undergraduate study of physics
Transcription
undergraduate study of physics
UNDERGRADUATE STUDY OF PHYSICS Osijek, May 2005 (last changes, September 2014) 1 2 1. INTRODUCTION 1.1. Reasons for launching the programme The rapid development of science and technology, especially information technology based on physics, has resulted in a more flexible education based on basic physical skills. Explaining and studying modern technologies and communication techniques by interpreting their physical basis, and teaching the use of modern information technology in physics results with the need of such a profile of expert who can deal with the technological development and the challenges and demands of the labor market. The suggested University Undergraduate Study of Physics enables students to acquire basic knowledge in the fields of Physics with basic mathematics and computer science courses as a necessary tool for solving physical problems, but also to support the development of logical thinking. This represents the first step in the education of professionals within the scientific field of Physics. Upon completion of the study, bachelors are qualified to carry out professional activities in educational and scientific institutions, laboratories, information technology and the financial sectors. The demand for bachelors on the labor market of the Republic of Croatia is still in its beginnings, and world wide experience shows that the process is moving on very slowly. Bachelors will, in addition to searching for a job, be able to continue their studies at the teaching Graduate Study of Physics and Computer Science at the Department of Physics, University of Osijek, or some other graduate programme in the Republic of Croatia 1.2. Previous experience of proposers in the implementation of similar programmes This study programme is based on teaching programmes of the Study of Physics and Technical Education with Computer Science, and Mathematics and Physics. The previous experience in organizing and carrying out the above mentioned study programmes showed that there is a steady and stable interest in this study. Throughout the study and according to the proposed study programme quality assurance measures will be implemented (mentors for students, quizzes during the academic year, individual and institutional questionnaires in order to obtain feedback on (dis) satisfaction of the conditions of study, ... ). 1.3. Mobility of students 3 The proposed Undergraduate Study programme of Physics is primarily aligned with related programmes of study in the Republic of Croatia (University of Rijeka (http://www.phy.uniri.hr), Split (http://fizika.pmfst.hr) and Zagreb (http://www.phy.hr) as well as in the European Union (University of Uppsala (www.physics.uu.se/en), Lille (http://physique.univ-lille1.fr), Maribor (http: / /www.fizika.uni-mb.si), Graz (http://physik.uni-graz.at/index_englisch.html). The study is organized through one semester courses which theoretically facilitates the mobility of students. 1.4. Other elements It should be noted, that the Department of Physics, University of Osijek, has adequate premises (labs and practicums) necessary for quality studies, and human resources needed for the implementation of the proposed programme of study. 4 2. GENERAL PART 2.1. Title of the study Undergraduate Study of Physics 2.2. Study holder Josip Juraj Strossmayer University of Osijek 2.3. Performer of the study programme The Department of Physics 2.4. Duration of the study Three years (6 semesters) 2.5. ECTS credits The proposed undergraduate study programme proposes a minimum of 180 ECTS credits. 2.5. Admission requirements Candidates, who have completed a four-year secondary school and passed the final state examination according to current conditions and procedures and in accordance with the Law, can enroll in the Undergraduate Study of Physics. 2.6. Learning outcomes Upon completion of the proposed study programe the candidate will develop following competencies: Professional competencies • The ability to formulate and to construct basic equations and their use in solving problems, explaining natural phenomena and principles of work of selected devices and instruments. • The performance of laboratory work in the context of applied physical laws and the evaluation of causal relationships with the given contents. • The practical application of concepts and mathematical formulation of physical laws in understanding of physical phenomena in nature, as well as solving simple tasks. • Handling of measuring instruments and devices (assembling electronic chart, compiling experiments to verify certain physical laws). • The application of acquired knowledge in the field of ICT in the process of researching and solving practical tasks. • The application of the principles and methods of programming in solving tasks by using specific programming languages. 5 General competencies • Development of written and oral communication skills and professional expression when writing reports and public appearances. • Applying of the acquired knowledge in the treated areas; the self-expanding of knowledge. • Working in teams and respecting other people's opinions addressing the terms of reference. • Behaving in accordance with the conducting rules in the laboratory and in accordance with the general rules of safety. • Understanding the impact of physics and computer science in the development of science and technology. • Gaining critical and self-critical reasoning in applying new technologies with regard to sustainable development. Learning outcomes Upon completion of the proposed study program the candidate will be able: • To apply the concepts and laws of mechanics, heat, electricity, magnetism and optics to solve various numerical and / or conceptual problems. • To perform accurate measurements and display the results in tables and graphs. • To process statistically and interpret the results within the context of applied physical laws and evaluate the causal relationships with the given contents. • To apply basic concepts of theoretical (classical mechanics, electrodynamics) and modern physics (statistical physics, condensed matter physics, quantum mechanics) in solving various numerical and / or conceptual problems. • To define, describe and evaluate the basic concepts of analysis and data processing, programming, architecture and organization of computers, databases, algorithms and data structures. • To apply the basic tools of web design and web programming in the area of personal work. • To highlight the impact of physics and computer science in the development of science and technology 2.7. Possibilities of continuing the study Bachelors can continue their studies at the teaching Graduate Study of Physics and Computer Science at the Department of Physics, University of Osijek, or some other graduate programme in the Republic of Croatia after passing necessary exams. 2.8. Professional or academic title awarded upon completion of studies Bachelor of Physics 6 3. PROGRAMME DESCRIPTION 3.1. List of compulsory and elective subjects with the number of teaching hours required for their implementation and ECTS credits 1st YEAR 1st Semester Course code Course title Course structure* L S E P EC TS F101 General Physics I 60 15 30 0 9 M101 Mathematics 1 (Differential calculus) 30 0 45 0 6 I101 Elementary Informatics 30 0 0 30 4 I102 E-Office 0 0 0 30 3 Z113 Physical education 1 0 0 30 0 1 30 0 15 0 5 30 0 30 0 5 0 30 0 0 2 Elective courses: student choose 7 credits Z105 General and Inorganic Chemistry 1 M106 Geometry of plane and space – Introduction in algebra Z101 English/ Germani 1 (optional) Total: 30 * L=Lectures, S=Seminars, E= exercises, , P=Practical (Laboratory) 2nd Semester Course code Course title Course structure* L S E P EC TS F102 General Physics II 60 15 30 0 9 M102 Mathematics 2 (Integral calculus ) 30 0 45 0 6 Z114 Physical education 2 0 0 30 0 1 Elective courses: student choose 14 credits M103 Linear Algebra 1 30 0 30 0 6 Z106 General and Inorganic Chemistry 2 30 0 15 0 6 I104 Algorithms and Data Structures 30 0 0 30 6 Z102 English/German 2 (optional) 0 30 0 0 2 Total: 30 * L=Lectures, S=Seminars, E= Exercises, , P=Practical (Laboratory) 7 2nd YEAR 3rd Semester Course code Course title F103 General Physics III M104 Matematics 3 (Functions of more variables) Course structure* L S E P EC TS 60 15 30 0 9 30 0 30 0 5 F107 Fundamentals of Measurement in Physics and Statistical Analysys 30 0 15 0 4 F111 General Physics Laboratory A 0 0 0 60 5 I106 Basics of Programming 1 15 0 0 30 4 Z103 English/German 3 (optional) 0 30 0 0 2 Z115 Physical education 3 0 0 30 0 1 Total: 30 * L=Lectures, S=Seminars, E= exercises, , P=Practical (Laboratory) 4th Semester Course code Course title Course structure* L S E P EC TS F104 General Physics IV 60 15 30 0 9 M105 Diferencial Equations 30 0 30 0 6 F114 General Physics Laboratory B 0 0 0 60 5 F105 Classical Mechanics 1 30 0 15 0 4 Z116 Tjelesna i zdravstvena kultura 4 0 0 30 0 1 Elective courses: students choose 6 credits I107 Basics of Programming 2 15 15 0 30 4 I105 Multimedia Systems 30 15 0 15 4 Z104 English/German 4 (optional) 0 30 0 0 2 S101 University elective course Total: 30 * L=Lectures, S=Seminars, E= Exercises, , P=Practical (Laboratory) 8 3rd YEAR 5th Semester Course code Course title Course structure* L S E P EC TS F108 Electrodynamics 1 30 0 30 0 5 F109 Introduction to Stastical Physics 30 0 15 0 5 F106 Classical Mechanics 2 30 0 15 0 5 Elective courses: students choose 15 credits T106 Science of Strength 30 0 15 0 3 F110 Mathematical Methods of Physics 45 0 30 0 5 I108 Data Base and Process Analysis 30 0 0 30 5 I109 Usage of Computers in Lectures 30 0 0 30 5 I116 Computer practicum 0 45 15 0 5 S102 University elective course Total: 30 * L=Lectures, S=Seminars, E= Exercises, , P=Practical (Laboratory) 6th Semester Course code F113 F115 F133 F134 I124 F131 F112 F123 S103 Course title Introduction to Quantum Mechanics Fundamentals of the Condensed Mater Physics Computational Physics Final thesis Elective courses: students choose 8 credits E-learning systems Electrodynamics 2 Special and General Relativity Introduction to Astronomy and Astrophysics University elective course Course structure* L 45 S 0 E 30 P 0 EC TS 7 30 0 15 0 5 15 0 30 15 15 0 0 0 5 5 15 30 30 15 0 0 0 15 15 30 0 0 4 4 4 30 0 15 0 4 Total: 30 * L=Lectures, S=Seminars, E= Exercises, , P=Practical (Laboratory) 9 3.2. Description of each course Prerequisites Learning outcomes: Teaching activity Class attendance 1 Learning outcome Course objective General Physics 1 F101 Lectures(60), Seminars (15), Numerical exercises (30) Basic subject 1. Semester 1. 9 ECTS credits Assistant professor Denis Stanić, PhD; Marina Poje, PhD; Maja Varga Pajtler, lecturer Adopt the basic knowledge and concepts in the field of kinematics and dynamics (mechanics), statics, relativistic mechanics, fluid mechanics and oscillations. Prepare for the courses that follow and which require knowledge of natural laws in specified fields. Obtained competences in physics and mathematics at the previous levels of education; enrolled the university undergraduate study. After successfully completed course, students will be able to: 1. Define the basic physical quantities and associated units of measure; be able to distinguish between primary and derived, as well as vector and scalar quantities. 2. Define basic concepts and describe the phenomena of the kinematics and dynamics. 3. Properly interpret graphical representation of physical quantities and their interdependence. 4. Define basic concepts and describe phenomena in the field of relativistic mechanics. 5. Correctly describe and interpret the laws of conservation. 6. Correctly describe and interpret the laws of statics. 7. Correctly describe and interpret the laws and phenomena of fluid mechanics and oscillations. 8. Properly evaluate the results obtained by solving the tasks. Apply knowledge gained from the treated areas. ECTS Course title Code Status Level Year ECTS Lecturer Students activity Methods of evaluation 1-8 Class attendance 1-8 Expressions of definitions and physical laws. Performs mathematical expressions for certain physical quantities. Describing demonstration experiments performed in class. Solving numerical Correlation of learning outcomes, teaching methods and evaluation Colloqium (midterm exams) 3 Points min max Evidence list (handwritten signature of the student) 0 10 Written midterms (3 exams per semester). 0 30 10 problems. Seminars Homework Final exam Consultations Gained competencies Content (Course curriculum) 1 1 3 1-8 1-8 1-8 The research on a given topic and writing text seminars. Drawing up a presentation and an oral presentation of the seminar. Solving numerical problems. Numerical exercises as written and oral assessment test understanding of physical laws. Rating of the written seminar (up to 5 points), and oral presentation score (up to 5 points). 0 10 Checking and discussions on the following exercises or consultation. 0 10 Written and oral examination. 0 40 Total 9 100 Denis Stanić: Wednesday, 12:00-14:00 Marina Poje: Tuesday, 12:00-14:00 Maja Varga Pajtler: Tuesday, 12:00-13:00 Understanding the basic physical concepts and relations related to mechanics, statics, relativistic mechanics and fluid mechanics. Spotting concepts that are common to different areas. Having the ability to formulate and perform basic equations and their use in solving problems, explaining natural phenomena and principles of selected devices and instruments. Developing analytical and quantitative approaches for solving problems. Showing the relationship of physical quantities using graphs and interpreting the graphs and the relationship between physical quantities. Developing the skills of scientific research. Developing of written and spoken communication skills and professional expression when writing seminars and during the public appearances. Introduction to physics. Physical units. Motion; speed, velocity, acceleration, free fall, slope, vertical projectile motion, slant projectile motion, circular motion. Dynamics; Newton’s laws. Conservation of linear momentum. Gravitation. Dynamics law for two systems in relative motion. The Galilean transformations, system in circular motion, Coriolis force. Elastic force. Friction. Work. Energy; law of conservation of mechanical energy. Power. Collision. Relativistic mechanics. Lorentz transformations, length contraction, time dilation, relativistic energy and momentum. Statics; center of gravity, handle, rotation of a rigid object about a fix axis, parallel-axis theorem, law of conservation of angular momentum, rotation of a rigid object about free axis. Fluid statics; hydraulic and atmospheric pressure, buoyant force, surface tension, capillarity. Fluid dynamics; the equation of continuity, Bernoulli’s equation, viscosity, flow of real fluid within tube, motion of a body in fluids. Viscosity measurement, errors of measurements. Oscillations; the pendulum, Lissajous figures, damped harmonic oscillations, forced harmonic oscillations, the physical pendulum. 11 Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up 1. 2. 3. 4. 1. 2. Planinić, J., Osnove fizike 1, Školska knjiga, Zagreb, 2005. Cindro, N., Fizika 1, Školska knjiga, Zagreb, 1988. Kulišić, P., Mehanika i toplina, Školska knjiga, Zagreb, 1990. http://kolegij.fizika.unios.hr/of1/nastavni-materijali/ Paić, M., Gibanje, Sile, Valovi, Liber, Zagreb, 1997. Kittel, C., Knight, W., Ruderman, M., Mehanika, Tehnička knjiga, Zagreb, 1986. 3. Young, H., Freedman, R., University Physics, Addison-Wesley Publ., New York, 1996. 4. E. Babić, R. Krsnik i M. Očko, Zbirka riješenih zadataka iz fizike, Školska knjiga, Zagreb 2004. 5. P. Kulišić, L.Bistričić, D. Horvat, Z. Narančić, T. Petrović i D. Pevec, Riješeni zadaci iz mehanike i topline, Školska knjiga, Zagreb, 2002. Lectures (60 hours) with the use of Power Point presentations, interactive simulation, the performance of demonstration experiments, addressing selected sample assignments, individual and group work, discussions and tests to check knowledge. Numerical exercises instructed by an assistant (30 hours) with the lead of the assistant. Within the auditory exercises students receive additional tasks for the exercise, which are solved alone for the homework. Checking solutions and discussion on the tutorials. Student presentations and discussions of specific topics at the seminar (15 hours). Students have the opportunity to take the numerical problems and theories through three exams (colloquium) per semester. If for each area in each colloquium achieve more than 60% of the points are exempt from the written and oral examination. Other students take a written and oral exam. Croatian. English (mentoring students). A questionnaire will be offered to students at the end of the semester with a goal of finding and improving weak spots in the conception and delivery of the course. 12 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: General Physics 2 F102 Lectures(60), Seminars (15), Numerical exercises (30) Basic subject 1. Semester 2. 9 ECTS credits Assistant professor Denis Stanić, PhD; Marina Poje, PhD; Maja Varga Pajtler, lecturer Adopt the basic knowledge and concepts in the field of electricity and magnetism. Prepare for courses that follow and which require knowledge of natural laws in specified fields. Obtained competences in physics and mathematics at the previous levels of education; entered university undergraduate study. After successfully completed course, student will be able to: 1. Define the basic concepts and describe phenomena in the field of electricity and magnetism. 2. Interprete properly graphical presentations of physical quantities and their interdependence. 3. Describe and interprete properly the demonstration of the above areas. Class attendance Correlation of learning outcomes, teaching methods and evaluation Colloqium (midterm exams) Seminars 1 3 1 Learning outcome Teaching activity ECTS 4. Evaluate correctly the results obtained by solving the tasks. Apply and improve the knowledge gained from the subject areas. Students activity Methods of evaluation 1-4 Class attendance 1-4 1-4 Expressions of definitions and physical laws. Performs mathematical expressions for certain physical quantities. Describing demonstration experiments performed in class. Solving numerical problems. The research on a given topic and writing of text seminars. Drawing up a presentation and an oral Points min max Evidence list (handwritten signature of the student) 0 10 Written midterms (3 exams per semester). 0 30 Rating of the written seminar (up to 5 points), and oral presentation score (up to 0 10 13 presentation of the seminar. Homework Final exam Consultations Gained competencies Content (Course curriculum) 1 3 4 1-4 Solving numerical problems. Numerical exercises as written and oral assessment test understanding of physical laws. 5 points). Checking and discussions on the following exercises or consultation. Written and oral examination. 0 10 0 40 Total 9 100 Denis Stanić:Wednesday, 12:00-14:00 Marina Poje: Tuesday, 12:00-14:00 Maja Varga Pajtler: Tuesday, 12:00-13:00 Understanding the basic physical concepts and relations related to electricity and magnetism. Spotting concepts that are common to different areas. Ability to formulate and derive the basic equations and their usage in solving problems, explaining natural phenomena and principles of selected devices and instruments. Developing analytical and quantitative approach to solving problems. Show the relationship of physical quantities using graphs and interpret the graph and the relationship between physical quantities. Developing the skills of scientific research. Developing written and spoken communication skills and professional expression when writing seminars and during the public appearances. Electricity. Coulomb's law. Electric field. Work in the electric field. Electric potential. Electric influence; induction. Gauss theorem. The distribution of charge on the conductor. Capacitors and capacitance. Dielectric polarization. Electrostatic field energy. Sources of electricity, electricity engines. Electromotive force. Electric current. Joule's law. Ohm's Law. Electric resistance. Connecting the resistors. Potentiometer. Kirchoff’s rules. Shunting conductors. Electric current in electrolytes. Current in vacuum and gases. Current in semiconductors. Magnetism. The magnetic field of electric current. The Biot-Savart law. Ampere's law. Magnetic force acting on a current-carrying conductor. Electrodynamics force. Lorentz force. The magnetic force between two parallel conductors; definition of ampere. Work due electrodynamics force. Magnetic flux. The current loop in a magnetic field. Galvanometer, ammeter, voltmeter. Electromagnetic induction; induced currents. Faraday's law of electromagnetic induction. Lenz's rule. Induced electromotive force; alternating current generator, dynamo generator. Mutual inductance. Self-inductance. Electric current in the RL, RC and LC circuits. Energy stored in a magnetic field. Energy on the capacitor; discharge of the capacitors in the LC circuit and the LRC circuits. Alternating electric current; resistor, Ohm's law, power. Transformer. Inductor. Three-phase alternating current. Electric motors. Magnetic properties of matter: permeability, diamagnetism, paramagnetism, ferromagnetism. Potential energy in a magnetic field. Magnetization. Hysteresis. Electromagnets. Electrodynamics microphone. Magnetic tape. Maxwell’s equations. Electromagnetic waves and their spectrum. 14 1. Cindro, N., Fizika 2, Školska knjiga, Zagreb, 1988. Recommended reading 2. Kulišić, P., Lopac, V., Elektromagnetske pojave i struktura tvari, Školska knjiga, Zagreb, 1991. 3. http://kolegij.fizika.unios.hr/of2/nastavni-materijali/ 1. Paić, M., Osnove fizike, III dio, Liber, Zagreb, 1989. Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up 2. Purcell, M., Berkeleyski tečaj fizike, II dio (Elektricitet i magnetizam), Tehnička knjiga, Zagreb 1988. 3. E. Babić, R. Krsnik i M. Očko, Zbirka riješenih zadataka iz fizike. Školska knjiga, Zagreb 2004. Lectures (60 hours) with the use of Power Point presentations, interactive simulation, the performance of demonstration experiments, addressing selected sample assignments, individual and group work, discussions and tests to check knowledge. Numerical exercises instructed by an assistant (30 hours) with the lead of the assistant. Within the auditory exercises students receive additional tasks for the exercise, which are solved alone for the homework. Checking solutions and discussion on the tutorials. Student presentations and discussions of specific topics at the seminar (15 hours). Students have the opportunity to take the numerical problems and theories through three exams (colloquium) per semester. If for each area in each colloquium achieve more than 60% of the points are exempt from the written and oral examination. Other students take a written and oral exam. Croatian. English (mentoring students). A questionnaire will be offered to students at the end of the semester with a goal of finding and improving weak spots in the conception and delivery of the course. 15 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: General Physics 3 F103 Lectures (60 hours), Seminars (15 hours), Exercises (30 hours) Fundamental course 2nd Semester 3rd 9 ECTS Dr Branko Vuković, PhD, Maja Varga Pajtler, teaching assistant, Ivana Krpan, teaching assistant Understanding of the basic physical concepts and relations connected with oscillations, waves, optics and atomic physics. Competences acquired in General Physics I, General Physics II, Mathematics 1, Mathematics 2 After successfully completed course, students will be able to: 1. Define fundamental terms and describe phenomena in the theory of waves 2. Define fundamental terms and describe phenomena in acoustics 3. Describe and interpret phenomena and laws in geometrical and physical optics 4. Explain line spectra and energy levels in atoms 5. Explain the concept of laser device 6. Interpret correctly results in solving numerical problems 7. Apply acquired knowledge in practical problems and continue independent broadening of views in presented fields Learning outcome Points ECTS Correlation of learning outcomes, teaching methods and evaluation Class attendance Knowledge test (preliminary exam) Seminar 0,9 1-7 Class attendance Evidence list 0 10 4,5 1-7 Preparation for written examination Written preliminary exam 0 50 0,9 7 Research on given topic, writing about it, prepare presentation and present results 0 10 Homework 1,35 6 Solving numerical problems 0 15 Final exam 1,35 1-7 Repetition of teaching materials Evaluation of written text (max 5 points) and evaluation of presentation (max 5 points) Short written exam every week during exercise class Oral exam (and written exam) 0 15 Total 9 0 100 Teaching activity Students activity Methods of evaluation min max 16 Consultations Gained competencies Content (Course curriculum) Recommended reading Additional reading Instructional methods Dr Branko Vuković, PhD: Wednesday, 10 – 12 Ivana Krpan, teacher assistant: Thursday, 12 – 13 Maja Varga Pajtler, teacher assistant: Thursday, 12 - 13 Understanding basic phenomena and relations in oscillations, waves, optics and atomic physics. Perceiving common concepts in different fields. Capability of deriving fundamental equations and using them in problem solving, as well as in explaining natural phenomena and concepts of several instruments. Developing analytical and quantitative approach in problem solving. Capability of interpreting laws of physics using graphs. Developing skills for scientific research. Developing writing and speaking communication skills. Using scientific terminology correctly and with self confidence Waves; longitudinal waves – equation, standing waves, transverse waves. Acoustics; standing waves in air, speed of sound, transmission of energy in progressive waves. Doppler effect. Sources of sound. Sensitivity of human ear. Shock waves. Optics; basic laws of geometrical optics. Plane mirror, spherical mirrors. Prism. Dispersion of light. Spherical dioptre. Optical systems: eye, magnifier, microscope, binoculars. Photometry. Physical optics; interference of light. Fresnel's mirrors. Lloyd's mirror, interference at planparallele plate. Newton's rings. Michelson interferometer. Diffraction of light; Fraunhoffer diffraction, diffraction grating, Fresnel's diffraction. Polarized light. Malus' law. Optical activity. Atomic line spectra and energy levels. Structure of atom. Lasers. - Planinić, J., Osnove fizike III., Valovi – akustika – optika - uvod u atomsku fiziku, Filozofski fakultet Osijek, 2005. - http://kolegij.fizika.unios.hr/of3 - http://moodle.fizika.unios.hr/ - Henč-Bartolić, V., Kulišić, P., Valovi i optika, Školska knjiga, Zagreb, 1991. - Cindro, N., Fizika 1, Školska knjiga, Zagreb, 1988. - Henč-Bartolić, V., Baće, M., Bistričić, L., Horvat, D., Kulišić, P., Rješeni zadaci iz valova i optike, Školska knjiga, Zagreb, 1992. - Paić, M., Gibanje, Sile, Valovi, Liber, Zagreb, 1997. - Paić, M., Osnove fizike, IV dio, Sveučilišna naklada Liber, Zagreb, 1983. - Halliday, D., Resnick, R., Walker, J., Fundamentals of physics, John Wiley & Sons, Hoboken, 2003. - Young, H., Freedman, R., University Physics, with modern physics AddisonWesley Publ., New York, 2008. - Giambattista, A i suradnici, College physics, McGraw Hill, 2007. - E. Babić, R. Krsnik i M. Očko. Zbirka riješenih zadataka iz fizike. Školska knjiga, Zagreb 2004. Lectures (60 hours) with Power Point presentations, interactive simulations, demonstration experiments, discussions, solving of sample problems individually and in group, regular tests. Problem solving in exercise classes (30 hours) independently and under the guidance of the teaching assistant. Exam formats Student seminars (15 hours) are designed to induce students in the direction of independent problem solving work when both the problem and solution methods are chosen by students after some example problems suitable for seminars are offered to students. Discussion and questions are encouraged. Short numerical exam every week, exams each month (the total of three during semester). Final exam immediately after the end of the course. Students that collect more than 60% credits during semester are considered to have passed the exam. 17 Language Quality control and successfulness follow up Students that collect less than 60% credits during whole semester are taking written and oral exam. Croatian, English (possible) A questionnaire will be offered to students at the end of the semester with a goal of finding weak spots in the conception and delivery of the course. 18 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: General Physics 4 F104 Lectures (60 hours), Seminars (15 hours), Exercises (30 hours) Fundamental course 2nd Semester 4th 9 ECTS Dr Branko Vuković, PhD, Maja Varga Pajtler, teaching assistant, Ivana Krpan, teaching assistant Understanding the basic physical concepts and relations connected with the structure of matter, kinetic theory of gases, thermodynamics, structure of atom, nuclear reactions, standard model of particles. Get prepared for advanced cources that require knowledge in named fields. Competences acquired in General Physics I, General Physics II, Mathematics 1, Mathematics 2 After successfully completed course, student will be able to: 1. Define fundamental terms and describe phenomena in structure of matter. 2. Define fundamental terms and describe phenomena in kinetic theory of gases. 3. Describe and interpret laws and phenomena regarding heat transfer, thermodynamics and heat engine. 4. Present historical development of the idea of atomic structure, describe structure of atomic nucleus. 5. Solve Schrödinger equation for simple cases. 6. Define basic terms and concepts in cosmology and particle physics. 7. Define basic terms and explain structure of periodic system of elements. 8. Interpret correctly results in solving numerical problems. 9. Apply acquired knowledge in practical problems and continue independent broadening of views in presented fields. Class attendance Knowledge test (preliminary exam) Seminar Points Learning outcome Teaching activity ECTS Correlation of learning outcomes, teaching methods and evaluation 0,9 1-9 Class attendance Evidence list 0 10 4,5 1-9 Preparation for written examination Written preliminary exam 0 50 0,9 9 Research on given topic, writing about it, prepare presentation and present results Evaluation of written text (max 5 points) and evaluation of presentation (max 5 points) 0 10 Students activity Methods of evaluation min max 19 Consultations Gained competencies Content (Course curriculum) Recommended reading Additional reading Homework 1,35 8 Solving numerical problems Final exam 1,35 1-9 Repetition of teaching materials Short written exam every week during exercise class Oral exam (and written exam) 0 15 0 15 Total 9 0 100 Dr Branko Vuković, PhD: Wednesday, 10 – 12 Ivana Krpan, teacher assistant: Thursday, 12 – 13 Maja Varga Pajtler, teacher assistant: Thursday, 12 - 13 Understanding of the postulates of statistical and thermodynamic description of many – particle systems. Associating law of entropy in isolated systems and phenomenological formulation of second law of thermodynamics. Explaining concept of heat engines using p – V diagram. Applying basic laws of thermodynamics on phase transitions. Present historical development of the idea of atomic structure. Solving Schrödinger equation for simple cases. Describing structure of atomic nucleus. Explaining concept of nuclear reactor. Developing skills for scientific research. Developing writing and speaking communication skills. Using scientific terminology correctly and with self confidence. Structure of matter; amount of substance, mol, Brown's motion. Diffusion. Molecular forces. States of matter. Kinetic theory of gases. Ideal gas law. Maxwell-Boltzmann distribution. Temperature. Thermometrics. Changes between states of matter. Humidity of air. Phase change graph, triple point of water. Calorimetrics; heat measurements, heat capacity. Calorimeters. Boling point, melting point, heat of transformation. Dalton's law. Real gases, Van der Waals equation. Thermodynamics; internal energy, work. First law of thermodynamics. Gay-Lussac-Joule experiment. Mayer's relation. Entalpy. Adiabatic process. Second law of thermodynamics, perpetuum mobile. Reversible and irreversible processes. Statistical theory of heat. Entropy. Carnot cycle. Efficiency of a Carnot engine. Clausius-Clapeyron equation. Engines. Thermodynamic temperature scale. Refrigerators. Heating pump. Heat transport. Spectrum of black body radiation. Kirchhoff's law of radiation. Planck law of black body radiation. Stefan law of radiation. Structure of atoms. Schrödinger wave equation. Heisenberg principle of uncertainty. Quantum numbers. The Pauli exclusion principle. Periodic table. Atomic nucleus. Radioactivity. Radioactive decay law. Nuclear reactions; nuclear fission, nuclear fusion. Accelerators, Roentgen's radiation. Interactions of radiation with matters. Radiation dosimetry. Radiation protection. Particle physics; quarks. The standard model of cosmology. - Cindro, N., Fizika 1, Školska knjiga, Zagreb, 1991. - http://kolegij.fizika.unios.hr/of4 - Kulišić, P., Mehanika i toplina, Školska knjiga, Zagreb, 2005. - Kulišić, P., Lopac, V., Elektromagnetske pojave i struktura tvari, Školska knjiga, Zagreb, 1991. - Kulišić, P., Bistričić, L., Horvat, D. et al., Riješeni zadaci iz mehanike i topline, Školska knjiga, Zagreb, 2007. - http://moodle.fizika.unios.hr/ - Paić, M., Toplina, Termodinamika, Energija, Liber, Zagreb, 1993. - Halliday, D., Resnick, R., Walker, J., Fundamentals of physics, John Wiley & Sons, Hoboken, 2003. - Young, H., Freedman, R., University Physics, with modern physics AddisonWesley Publ., New York, 2008. - Giambattista, A i suradnici, College physics, McGraw Hill, 2007. - E. Babić, R. Krsnik i M. Očko. Zbirka riješenih zadataka iz fizike. Školska 20 knjiga, Zagreb 2004. Instructional methods Lectures (60 hours) with Power Point presentations, interactive simulations, demonstration experiments, discussions, solving of sample problems individually and in group, regular tests. Problem solving in exercise classes (30 hours) independently and under the guidance of the teaching assistant. Exam formats Language Quality control and successfulness follow up Student seminars (15 hours) are designed to induce students in the direction of independent problem solving work when both the problem and solution methods are chosen by students after some example problems suitable for seminars are offered to students. Discussion and questions are encouraged. Short numerical exam every week, exams each month (the total of three during semester). Final exam immediately after the end of the course. Students that collect more than 60% credits during semester are considered to have passed the exam. Students that collect less than 60% credits during whole semester are taking written and oral exam. Croatian, English (possible) A questionnaire will be offered to students at the end of the semester with a goal of finding weak spots in the conception and delivery of the course. 21 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Classical Mechanics 1 F105 Undergraduate (obligated) Intermediate 2. Semester 4. 4 doc.dr.sc Zvonko Glumac; Matko Mužević, prof. 1. To demonstrate knowledge and understanding of the following fundamental concepts in: - Newtonian mechanics in one, two and three dimension, - oscillations, - particle motion under central forces, - Newton's law of motion in non-inertial frame of reference. 2. To develop students math skills as applied to physics. General Physics 1, F101 . After successfully completed course, students will be able to: 1 apply vector calculus to solve the basic problems of classical mechanics, 2 understand and apply Newton's axioms, 3 describe the properties of the free, damped and forced harmonic oscillator, 4 understand the law of gravity, 5 understand the connection between the inertial and non-inertial frame of reference. Consultations Gained competencies Content (Course curriculum) Class attendanc e Knowledg e test (prelimina ry exam) Final exam Points Learning outcome Teaching activity ECTS Correlation of learning outcomes, teaching methods and evaluation 0 - Class attendance Evidence list 0 0 2 1-5 Preparation for written examination Written preliminary exam 0 50 2 1-5 Repetition of teaching materials Oral exam (and written exam) 0 50 Students activity Methods of evaluation min max Total 4 1-5 0 100 Friday, 12.00 – 14.00. The students gain knowledge about the concepts and mathematicall formulation of the laws of mechanics, which enables them to understand the mechanical phenomena in nature, as well as solving simple tasks. Introduction; definition and basic properties of the vector; addition of vectors; vector multiplication; mirroring; derivative and integral of a vector field; gradient; divergence and Gauss's theorem; rotation and Stokes' theorem; Laplace operator; cylindrical coordinate system; spherical coordinate system; velocity and acceleration in rectangular, cylindrical and spherical coordinate systems; circular motion; Newton's axioms; inert and heavy mass; work, power, kinetic energy; 22 conservative forces and potential energy, conservation of mechanical energy, impulse, torque and angular momentum, equilibrium of a particle; motion in a uniform force field: falling bodies and projectiles: attenuation; motion of charged particles in the Lorentz force field; free, damped and forced harmonic oscillator; resonance; two-dimensional harmonic oscillator; the mathematical pendulum; gravitational force, field, potential energy and potential; equations of motion for a particle in central foce field, potential energy, energy conservation, energy graph; equivalence of Kepler's laws and the laws of gravity; virial theorem; time derivative of vectors in inertial and non-inertial systems, speed and acceleration in non-inertial systems; the equation of motion in non-inertial systems connected to the surface of the Earth; examples of motion in non-inertial systems connected to the surface of the Earth. Recommended reading 1. Klasična mehanika, uvod - Z. Glumac, http://www.fizika.unios.hr/~zglumac/utm.pdf; 2. Teorijska mehanika - Z. Janković; Additional reading 3. Theory and Problems in Theoretical Mechanics - M. Spiegel 4. Classical Mechanics - H. Goldstein; 5. Mehanika - L. D. Landau, E. M. Lifšic; 6. Teorijska fizika i struktura materije - I. Supek; 7. Mathematical Methods of Classical Mechanics - V. I. Arnold; 8. Teorijska mehanika - S. M. Targ; 9. A Guided Tour of Mathematical Physics - R. Snieder, http://samizdat.mines.edu/snieder/. Instructional methods Exam formats Language Quality control and successfulness follow up Lectures (30 hours) and auditory exercises (15 hours). Three preliminary exams (90 min.) during the semester (50% weighting) and oral exam (50% weighting), or one 2-hour written examination (50% weighting) and oral exam (50% weighting). Croatian or English (optional). Student survey. Permanent contact with students. 23 Course title Code Status Level Year ECTS Lecturer Course objective Classical Mechanics 2 F106 Undergraduate (obligated) Intermediate 3. Semester 5. 5 doc.dr.sc Zvonko Glumac; Matko Mužević, prof. 1 To demonstrate knowledge and understanding of the following fundamental concepts in: – the dynamics of system of particles, - motion of rigid body, - Lagrangian and Hamiltonian formulation of mechanics. 2 To represent the equations of motion for complicated mechanical systems using the Lagrangian and Hamiltonian formulation of classical mechanics. 3 To develop math skills as applied to physics. Prerequisites Learning outcomes: Classical Mechanics 1, F105 After successfully completed course, student will be able to 10. define and understand basic mechanical concepts related to discrete and continuous mechanical systems, 11. describe and understand the vibrations of discrete and continuous mechanical systems, 12. describe and understand planar and spatial motion of a rigid body, 13. describe and understand the motion of a mechanical system using Lagrange-Hamilton formalism. Consultations Gained competencies Class attendanc e Knowledg e test (prelimina ry exam) Final exam Points Learning outcome Teaching activity ECTS Correlation of learning outcomes, teaching methods and evaluation 0 - Class attendance Evidence list 0 0 2 1-4 Preparation for written examination Written preliminary exam 0 50 3 1-4 Repetition of teaching materials Oral exam (and written exam) 0 50 Students activity Methods of evaluation min max Total 5 1-4 0 100 Friday, 12.00 – 14.00 The students must acquire knowledge about the concepts and mathematically formulated laws of mechanics, which enables them to understand mechanical phenomena in nature as well as to solve simple problems. 24 Content (Course curriculum) Recommended reading Introduction; discrete and continuous systems of particles; mass density; center of mass; the momentum of system of particles; angular momentum of system of particles; energy of the particles; the work of internal forces and internal potential energy; work of external forces and external potential energy; motion relative to the center of mass (momentum, angular momentum, kinetic energy); Lagrange and D'Alembert's principle; motion missiles; collisions of particles; small longitudinal vibrations of a discrete one-dimensional system of particles; small transverse vibrations of continuous one-dimensional system of particles; standing wave; traveling wave; wave energy; planar motion of a rigid body; moment of inertia; theorems about moments of inertia; rotation kinetic energy; physical pendulum; statics of rigid bodies; tensor of inertia; principal moments of inertia; Euler equations of motion; motion of the Earth; precession; Euler angles; top: precession, nutation and spin; degrees of freedom; conditions on the motion; Lagrange equations for holonomic and nonholonomic systems; Lagrange function of charged particles in the electromagnetic field; Euler-Lagrange equations and Hamilton's principle; Hamilton's equations of motion; Poisson brackets; canonical transformation; Liouville's theorem; transition to quantum mechanics. 1. Klasična mehanika, uvod - Z. Glumac, http://www.fizika.unios.hr/~zglumac/utm.pdf; 2. Teorijska mehanika - Z. Janković; Additional reading 3. Theory and Problems in Theoretical Mechanics - M. Spiegel; 4. Classical Mechanics - H. Goldstein; 5. Mehanika - L. D. Landau, E. M. Lifšic; 6. Teorijska fizika i struktura materije - I. Supek; 7. Mathematical Methods of Classical Mechanics - V. I. Arnold; 8. Uvod u analitičku mehaniku - I. Aganović, K. Veselić; 9. Teorijska mehanika - S. M. Targ; 10. A Guided Tour of Mathematical Physics - R. Snieder, http://samizdat.mines.edu/snieder/ Instructional methods Exam formats Language Quality control and successfulness follow up Lectures (30 hours) and auditory exercises (15 hours) Three preliminary exams (90 min.) during the semester (50% weighting) and oral exam (50% weighting), or one 2-hour written examination (50% weighting) and oral exam (50% weighting). Croatian or English (optional) Student survey. Permanent contact with students. 25 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Fundamentals of Measurement in Physics and Statistical Analysys F107 Undergraduate (obligated) Basic 2. Semester 3. 4 doc.dr.sc. Zvonko Glumac; Matko Mužević, prof. To introduce the student to basic concepts of statistics and probability. To clarify the concept of random variables and probability distribution and introduce them as a mathematical model for actual physical problems. None After successfully completed course, student will be able to 1. use permutations, combinations and variations; 2. understand the basic concepts of probability; 3. describe the properties of binomial, Poisson, Gaussian and other distributions; 4. use the generating function of binomial, Poisson, Gaussian and other distribution; 5. use calculus of correlations in the statistical analysis; 6. use Markov chains and methods of finding the equilibrium probability distributions. Consultations Gained competencies Content (Course curriculum) Class attendanc e Knowledg e test (prelimina ry exam) Final exam Points Learning outcome Teaching activity ECTS Correlation of learning outcomes, teaching methods and evaluation 0 - Class attendance Evidence list 0 0 2 1-6 Preparation for written examination Written preliminary exam 0 50 2 1-6 Repetition of teaching materials Oral exam (and written exam) 0 50 Students activity Methods of evaluation min max Total 4 1-6 0 100 friday, 12.00 – 14.00 Students are prepared for scientific research, data processing and analysis of the results. Introduction; permutations with and without repetition; combinations with and without repetition; variations with and without repetition; binomial theorem; definition of the basic concepts of probability; addition of probability; multiplication of probability; conditional probability; addition and multiplication theorem; Bayes' theorem; mathematical expectation; Bernoulli probability events; Gaussian distribution; Gaussian integrals; average value; variance; Chebyshev's theorem; law of large numbers (Bernoulli's theorem); geometric 26 probability; discrete and continuous probability; theorems of random variables; transformation of variables; method of least squares; error function; law of propagation of errors; the standard deviation of the mean; equalization indirect observations; basic concepts of statistics; moments of the distribution; distributions: Binomial, Poisson, hypergeometric, Gaussian; gamma distribution; definition of generating functions; generating function of binomial, Poisson and Gaussian distribution; the addition theorem for the Gaussian distribution; generating function of gamma distribution; characteristic functions; inversion theorem; cumulative functions; central limit theorem; correlations; linear correlation; regression curve; regression lines; correlation coefficient; nonlinear correlation; index of correlation; ratio of correlation; random walk in one dimension; Markov chains; Poisson process. Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up 1. Vjerojatnost i statistika, uvod - Z. Glumac, http://www.fizika.unios.hr/~zglumac/uvs.pdf; 2. Vjerojatnost i statistika, V. Vranić; 3. Statistička teorija i primjena, I. Pavlić; 4. Introduction to Probability, C. M. Grinstead and J. M. Snell. Lectures (30 hours) and auditory exercises (15 hours). 1. Three preliminary exams (90 min.) during the semester (50% weighting) and oral exam (50% weighting). 2. Or, one 2-hour written examination (50% weighting) and oral exam (50% weighting). Croatian or English (optional) Student survey. Permanent contact with students. 27 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Electrodynamics I F108 Lectures (30), Exercises (30) Basic course 3dr Semester 5th 5 Ph.D. Josip Brana, Ivana Ivković, lecturer Theoretical understanding of basic laws of electrostatics, magnetostatics as well as electrodynamics in vacuum, and be possible to solve different problems in this field. Mathematics 1 - calculus, Math 2 - Integral Calculus, Math 3 - functions of higher variables, Fundamentals of Physics 1, 2, 3, Classical Mechanics I. After successfully completed course, student will be able to: 1. Understand and correctly express the fundamental laws of electrostatics 2. Describe and interpret the basic properties of the electric field 3. Understand and correctly express the fundamental laws of magnetostatics 4. Describe and interpret the basic properties of the magnetic field 5. Apply acquired knowledge in the field of electrostatic and magnetostatic in practice and self-solve mathematical problems 6. Describe the basic principles of electrodynamics in a vacuum 7. Understand, interpret and apply knowledge of Maxwell's equations to problems 8. Understand the concept of an electromagnetic wave, its structure and properties 9. Understand the energy-momentum concept of an electromagnetic field 10. Understand the way and reasons for introduction of electromagnetic potentials and consequently gauge freedom 11. Describe and understand the effects of radiation in electrodynamics Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 12. Apply learned knowledge to problem-solving tasks Students activity Attending lectures 1 1-11 The presence in the classroom Attending exercises 1 Homework 0,5 Seminars 0,5 Teaching activity 1-11 The presence in the classroom 1-11 Solving homework 1-11 Independent processing of Methods of evaluation Signing during the class Signing during the class Written submission of assignments Verbal presentation, Points min max 0 10 0 10 0 15 0 15 28 given topic, consultations Consultations Gained competencies Content (Course curriculum) Knowledge verification by tests 1 Final exam 1 Total: 5 1-11 1-11 Continuous work throughout the semester Repeating material written submission Written midterms (successfully passed tests replace the written examination) Written exam (if not satisfy the prague passing the colloquium), verbal exam 0 25 0 25 0 100 Tuesday, 11:00-12:00 1. Developing analytical and quantitative approach 2. Developing an abstract visualization of natural phenomena 3. Identify the problem, engage in problem solving and logical link key facts and elements 4. Teamwork 5. Developing accountability and ethics 1. Electrostatics o Coulomb's law o of the electric field o on the principle of linear superposition o of Gauss' law o of the scalar potential - Poisson equation o Work on the charge in an electrostatic field 2. Magnetostatic o magnetic induction and Biot-Savart law o the vector potential calibration freedom o Multipole on development o the magnetic moment o force and torque on the localized currents in a given magnetic field 3. Electrodynamics in a vacuum o charge motion in default electromagnetic fields § motion in a constant homogeneous fields § motion in periodic fields o electromagnetic field of the charge and current whose motion default § Maxwell's equations in vacuum § the continuity equation § Maxwell's equations away from the current and charge electromagnetic waves, polarization § energy and momentum of electromagnetic fields § electromagnetic potentials, their significance and gradient invariance § retarded and advanced solutions § Lienard-Wichert potentials o the effects of radiation § Larmors formula for dipole radiation § braking force on radiation and radiation damping 29 Recommended reading 1. J. D. Jackson: Classical Electrodynamics, 3rd edition, John Wiley, New York, 1998 2. I. Supek: Teorijska fizika I struktura materije, Školska knjiga, Zagreb, 1977 Additional reading 1. A.O. Barut: Electrodynamics and Classical Theory of Fields and Particles, MacMillan, New York, 1964 2. F. Rorlich: Classical charged particles. Addison-Wisley, Reading, Massachusetts, 1965 Instructional methods Exam formats Language Quality control and successfulness follow up Lectures on the theory and the problem-solving exercises and seminars. The exam is in writing and oral form Croatian/english Student's survey and statistical analysis of exam results 30 Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Learning outcome Prerequisites Electrodynamics II F131 Lectures (30), Exercises (15) Elective course 3dr Semester 6th 4 Ph.D. Josip Brana, Ivana Ivković, lecturer Theoretical understanding of basic laws of electrostatics, magnetostatics as well as electrodynamics in materials, and be possible to solve different problems in this field. Mathematics 1 - calculus, Mathematics 2 - Integral Calculus, Mathematics 3 functions of higher variables, Fundamentals of Physics 2, 3, Classical Mechanics I., Classical Mechanics II, Mathematical methods in physics, Electrodynamics 1 After successfully completed course, students will be able to: 1. Understand and express correctly the fundamental laws of electrostatics in materials 2. Describe and interpret the basic properties of the electric field in materials 3. Understand and correctly express the fundamental laws of magnetostatic in materials 4. Describe and interpret the basic properties of the magnetic field in materials 5. Apply acquired knowledge in the field of electrostatic and magnetostatic in materials in practice and self-solve mathematical problems 6. Describe the basic principles of electrodynamics in materials 7. Understand, interpret and apply knowledge of Maxwell's equations in materials to problems 8. Understand the concept of an electromagnetic wave, its structure and properties in materials 9. Understand the energy-momentum concept of an electromagnetic field in materials 10. Understand the way and reasons for introduction of electromagnetic potentials and consequently gauge freedom 11. Describe and understand the effects of radiation in electrodynamics 12. Apply learned knowledge to problem-solving tasks ECTS Course title Code Status Level Year ECTS Lecturer Course objective Students activity Attending lectures 0,5 1-11 The presence in the classroom Attending exercises 0,5 1-11 The presence in the classroom Homework 0,5 1-11 Solving homework Teaching activity Seminars 0,5 1-11 Independent processing of given topic, consultations Knowledge verification by tests 1 1-11 Continuous work throughout the semester Methods of evaluation Signing during the class Signing during the class Written submission of assignments Verbal presentation, written submission Written midterms (successfully passed tests Points min max 0 10 0 10 0 15 0 15 0 25 31 Final exam Consultations Gained competencies Content (Course curriculum) Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up 1 1-11 Repeating material replace the written examination) Written exam (if not satisfy the prague passing the colloquium), verbal exam 0 25 Total: 4 0 100 Tuesday, 11:00-12:00 1. Developing analytical and quantitative approach 2. Developing an abstract visualization of natural phenomena 3. Identifying the problem, engage in problem solving and logical link key facts and elements 4. Teamwork 5. Developing accountability and ethics 1. Electrostatic in macroscopic media and boundary conditions 2. Magnetostatic in macroscopic media and boundary conditions 3. The equations of electrodynamics in macroscopic 4. Boundary conditions at the boundaries of the substance 5. Emg waves in non-conductive areas • polarization of the waves • reflection of the waves • refraction on the border of two substances - wave optics 6. Emg. waves in dispersive environments 7. Emg waves in conductive materials 8. Waveguides, optical fibers and cavity 9. Multipole expansion of the electromagnetic fields 10. Quadrupole and magnetic dipole radiation 11. Radiation whip antenna 12. Scattering and diffraction EMG. waves 13. Relativistic generalization of the Larmor formula 14. Lorentz-Dirac's relativistic equation with the reaction of radiation 1. J. D. Jackson: Classical Electrodynamics, 3rd edition, John Wiley, New York, 1998 2. I. Supek: Teorijska fizika I struktura materije, Školska knjiga, Zagreb, 1977 3. A.O. Barut: Electrodynamics and Classical Theory of Fields and Particles, MacMillan, New York, 1964 4. F. Rorlich: Classical charged particles. Addison-Wisley, Reading, Massachusetts, 1965 Lectures on the theory and the problem-solving exercises and seminars. The exam is in writing and oral form Croatian/english Student's survey and statistical analysis of exam results 32 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Introduction to stastical physics F109 undergraduate (obligated) Intermediate 3rd Semester 5th 5 ECTS Lectures (30 hours) + Exercises ( 15 hours) Dr.sc. Ramir Ristić associate professor Microscopic explanation about fenomenological behaviour of many particle systems. General Physics 1,2,3,4 After successfully completed course, students will be able to: 1. explain the thermodynamic laws 2. explain the Boltzmann distribution 3. distinguish between Bose-Einstein and Fermi-Dirac distribution Consultations Gained competencies Content (Course curriculum) Recommended reading Additional reading Instructional methods Exam formats Teaching activity Class attendance Knowledge 2,5 test (preliminary exam) Final exam 2,5 Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 4. explain black body radiation 1-4 1-4 Points Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list Written preliminary exam 50 50 Repetition of teaching materials Oral exam (and written exam) 50 50 min max Total 5 100 100 Monday 12-14 Understanding the basic physical concepts and relations. Developing analytical and quantitative approach solving problems. Intermolecular scatering. Equation of state.Laws of thermodynamics. Thermodynamic potentials. Systems with changeable number of the particles. Maxwell-Boltzmann distribution. Phase space. Understanding of the second law of thermodynamics. Equipartition theorem. Barometric equation. Thermal properties of the ideal gas. Explanation of the third law of thermodynamics. Negative temperature. Black body radiation. Elastic vibrations in crystalline solids. Bose-Einstein and Fermi-Dirac functions of distribution. Limes of the classical statistical physics. Strongly degenerated fermi systems. Bose-Einstein condensation. 1. Šips, V. Uvod u statističku fiziku, Školska knjiga, Zagreb, 1990. 2. Lenac, Z., Šips, V. Zadaci iz statističke fizike I, Liber, Zagreb, 1980. 3. Lenac, Z., Šips, V. Zadaci iz statističke fizike II, Liber, Zagreb, 1981. 1. I.Supek, Teorijska fizika i struktura materije, Školska knjiga, Zagreb, 1974 2. Mandl, F. Statistical Physics, John Wiley & Sons, 1988. Lectures and excercises 33 Oral and written exam, and two exams during semester. Students who pass both exams during the semester are exempted from the written part of the exam in the winter examination period. To make the final score was positive, both,oral and written examination must be positive. To access the exam, students must be present in 50% of exercises and lectures. Language Quality control and successfulness follow up Croatian Student questionnaires 34 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Mathematical Methods of Physics F110 Undergraduate (obligated) Intermediate 3 Semester 5 7 doc.dr.sc. Zvonko Glumac; Matko Mužević, prof. The main objective of this course is to familiarize students with a range of mathematical methods that are essential for solving advanced problems in theoretical physics. None After successfully completed course, student will be able to: 7. use complex analysis in solving physical problems; 8. solve ordinary and partial differential equations of second order that are common in the physical sciences; 9. use Green functions; 10. use the orthogonal polynomials and other special functions; 11. use Fourier series and integral transformation; 12. use the calculus of variations. Consultations Gained competencies Content (Course curriculum) Class attendanc e Knowledg e test (prelimina ry exam) Final exam Points Learning outcome Teaching activity ECTS Correlation of learning outcomes, teaching methods and evaluation 0 - Class attendance Evidence list 0 0 3 1-6 Preparation for written examination Written preliminary exam 0 50 4 1-6 Repetition of teaching materials Oral exam (and written exam) 0 50 Students activity Methods of evaluation min max Total 7 1-6 0 100 Friday, 12.00 – 14.00. The laws of physics are often expressed through the relatively complex mathematical apparatus. This course is intended to give mathematical tools necessary for better understanding of the later courses in physics such as classical electrodynamics, quantum mechanics, solid state physics and statistical physics. Introduction; complex algebra; complex functions; De Moivre formula; CauchyRiemann conditions; line integral; Cauchy's integral theorem; Cauchy's integral formula; Cauchy's integral and derivative oh the functions; Taylor expansion; analytic extension; poles of the function; determination of residues; Laurent development; mapping; cut line, branch point and multi-valued functions; conformal mapping; singularities; Residue Theorem; Cauchy principal value; differential equations of the first order; homogeneous second-order differential 35 equations; singular points of differential equations; Frobenius method - series expansion; inhomogeneous differential equation of the second order; partial differential equations: separation of variables; Green's functions; self-adjoint differential equations; hermitian operators, Gram-Schmidt orthogonalization process; orthogonal polynomials; completeness of the eigenfunctions; Bessel's inequality; Schwarz inequality; expansion of Green's functions; Green's functions in one dimension; Dirac delta function; gamma function; Bessel functions of the first kind; Legendre polynomials; associated Legendre polynomials; Spherical function; Hermite polynomials; Laguerre polynomials; associated Laguerre polynomials; Fourier series; integral transformation: Fourier transformation; integral Transformation: Laplace transformation; calculus of variations; RayleighRitz variational technique. Recommended reading 1. Matematičke metode fizike, uvod - Z. Glumac, http://www.fizika.unios.hr/~zglumac/ummf.pdf; 2. Mathematical Physics - Eugene Butkov; Additional reading 1. Mathematical Methods for Physicists, G. B. Arfken and H. J. Weber; 2. Methods of Theoretical Physics- P. M. Morse and H. Feshbach; 3. A Guided Tour of Mathematical Physics - R. Snieder, http://samizdat.mines.edu/snieder/. Instructional methods Exam formats Language Quality control and successfulness follow up Lectures (45 hours) and auditory exercises (45 hours). Three preliminary exams (90 min.) during the semester (50% weighting) and oral exam (50% weighting), or one 2-hour written examination (50% weighting) and oral exam (50% weighting). Croatian or English (optional) Student survey. Permanent contact with students. 36 Course title Code Status Level Year ECTS Lecturers Course objective Prerequisites Learning outcomes: General Physics Laboratory A F111 Laboratory excersices Basic 2nd Semester 3rd 5 ECTS credits Professor Branko Vuković, PhD; Marina Poje, PhD; Ivana Ivković, lecturer Self conducting experiments in the field of general physics, processing and physical understanding of the results, and writting lavboratory reports on the experiment. The use of computers in data processing. Competences acquired by attending the courses "Basic Physics I and II" After successfully completed course, students will be able to: 1. Independently conducting experiments in the field of general physics (handling measuring devices and instruments). 2. Explain physical phenomena in the tests performed (a connection between physical laws and their application). 3. Statistical analysis of results obtained by experiment, interpretation of the results. 4. Using a computer to process the results. 5. Making the detailed, full report of the experiment. Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 6. Using scientific literature for the purpose of showing the measurement results Students activity Class attendance 0,5 1-6 Class attendance Performing the laboratory exercises 1 1-6 Measuring and data processing 2-6 Theoretical preparation for experiments, writing reports Teaching activity Independent work 2 Methods of evaluation Performing the exercises Precision measurement and analysis of results, written verification of measurement results Oral test of preparation for the conducting of the experiment, examination of the students written preparation, preparing Points min max 0 10 0 30 0 40 37 reports Consultations Final exam 1,5 Total 5 1-5 Performing certain exercises, data analysis and report writing Written report and oral exam 0 20 0 100 prof.dr.sc. Branko Vuković:Wednesday, 10:00-12:00 dr.sc. Marina Poje: Wednesday, 12:00-14:00 Ivana Ivković, prof.: Wednesday, 14:00-16:00 Gained competencies General competencies: 1. Developing analytical and quantitative approach 2. Identify the problem, engage in problem solving and logical link key facts and elements 3. Teamwork 4. Developing accountability and ethics 5. Behavior in accordance with the rules of behavior in the laboratory and in accordance with the general rules of safety. Specific competencies: 1. Usage of the correct units and their prefixes 2. Handling measuring instruments and appliances (electronic assembly diagram, assembly experiments to verify certain physical laws) 3. Spotting, analysis and eventual elimination of possible errors of measurement 4. Statistical analysis of the results and their correct record Content (Course curriculum) Introduction to laboratory work (physical size and corresponding units of measurement, the concept, accuracy and record measurements, types of errors and measured results, graphical and tabular display of measurement, safety guide for the laboratory work) List of experimental exercises (with possibility of choosing 10 of them): - Caliper, micrometer screw, spherometer, scales - The study of helical coils, determine the density of solid bodies using the dynamometer - Mathematical and physical pendulum - Static determination of torsion modules, dynamic torsion modules - Determination of density by pycnometer, Mohr- Westphal balance scale - Determination of surface tension of liquids, Hopplerov viscometer - Measurement of resistance using the Wheatstone bridge, measurement of resistance of electric light bulbs, depending on the current strength - Determination of the specific charge of the electron; magnetic field around a straight guide - Cathode oscillograph 38 Recommended reading - Calibration of the precision galvanometer, temperature measurement using thermocouples - Triode and transistor - M. Požek, A. Dulčić; Fizički praktikum I i II, Sunnypress, Zagreb, 1999. - Paić, M. Fizička mjerenja I, II i III, Liber, Zagreb, 1988. - http://kolegij.fizika.unios.hr/pof2 Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up - B. Marković, D. Miler, A. Rubčić, Račun pogrešaka i statistika, Liber, Zagreb, 1987. Students perform experiments on topics from Basic physics I and II during the four hours period During each term student verbally verify their knowledge of the experiment, which were currently performed. For any experiment performed the student is required to write a report that will be evaluated. The exam consists of performing one of the experiments. The rating is determined based on the knowledge shown during classes and examinations and secondary assessment of the conducted experiments. Croatian, English (possible). Monitoring the student progress in the execution of experiments, analysis and physical understanding of the measured data, and writing reports on the executed experiment. During the performance of the course, students will be surveyed on the experiments suitability and quality of the scripts, teachers and assistants. 39 Course title Code Status Level Year ECTS Lecturers Course objective Prerequisites Learning outcomes: General Physics Laboratory B F114 Laboratory excersices Basic 2nd Semester 4th 5 ECTS credits Professor Branko Vuković, PhD; Marina Poje, PhD; Ivana Ivković, lecturer Self conducting experiments in the field of general physics, processing and physical understanding of the results, and writting lavboratory reports on the experiment. The use of computers in data processing. Competences acquired by attending the courses "Basic Physics III and IV" After successfully completed course, students will be able to: 1. Independently conduct experiments in the field of general physics (handling measuring devices and instruments). 2. Explain physical phenomena in the tests performed (a connection between physical laws and their application). 3. Statistical analysis of results obtained by experiment, interpretation of the results. 4. Use a computer to process the results. 5. Make a detailed, full report of the experiment. Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 6. Usev scientific literature for the purpose of showing the measurement results Students activity Class attendance 0,5 1-6 Class attendance Performing the laboratory exercises 1 1-6 Measuring and data processing 2-6 Theoretical preparation for experiments, writing reports Teaching activity Independent work 2 Methods of evaluation Performing the exercises Precision measurement and analysis of results, written verification of measurement results Oral test of preparation for the conducting of the experiment, examination of the students written preparation, preparing Points min max 0 10 0 30 0 40 40 reports Consultations Final exam 1,5 Total 5 1-5 Performing certain exercises, data analysis and report writing Written report and oral exam 0 20 0 100 prof.dr.sc. Branko Vuković:Wednesday, 10:00-12:00 dr.sc. Marina Poje: Wednesday, 12:00-14:00 Ivana Ivković, prof.: Wednesday, 14:00-16:00 Gained competencies General competencies: 1. Developing analytical and quantitative approach 2. Identify the problem, engage in problem solving and logical link key facts and elements 3. Teamwork 4. Developing accountability and ethics 5. Behavior in accordance with the rules of behavior in the laboratory and in accordance with the general rules of safety. Specific competencies: 1. Usage of the correct units and their prefixes 2. Handling measuring instruments and appliances (electronic assembly diagram, assembly experiments to verify certain physical laws) 3. Spotting, analysis and eventual elimination of possible errors of measurement 4. Statistical analysis of the results and their correct record Content (Course curriculum) Introduction to laboratory work (physical size and corresponding units of measurement, the concept, accuracy and record measurements, types of errors and measured results, graphical and tabular display of measurement, safety guide for the laboratory work) List of experimental exercises: - Determination of the coil inductance - Determination of the capacity of the condenser - Geomagnetism, Balmer series - Electrolysis, conductivity of the electrolyte - Polarization, polarimetric measurement of the concentration of sugar solution, Photometry - Lenses - Electron diffraction, Determination of maximum energy beta radiation absorption in aluminum - Stefan-Boltzmann law - Latent heat of vaporization of water, Determination of the heat coefficient expansion of solids - Determination of the specific heat coefficient of petroleum, Determination of the adiabatic coefficient of air 41 Recommended reading - Sound waves - properties. Determination of velocity of sound waves by Kundt tube - Colorimetry - Checking the laws of Physics in the Electronics Workbench programme - Millikan experiment - M. Požek, A. Dulčić; Fizički praktikum I i II, Sunnypress, Zagreb, 1999. - Paić, M. Fizička mjerenja I, II i III, Liber, Zagreb, 1988. - http://kolegij.fizika.unios.hr/pof2 Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up - B. Marković, D. Miler, A. Rubčić, Račun pogrešaka i statistika, Liber, Zagreb, 1987. Students during the four hours period perform experiments on topics from Basic physics III and IV. During each term students verbally verify their tknowledge of the experiment, which was currently performed. For any experiment performed students are required to write a report that will be evaluated. The exam consists of performing one of the experiments. The rating is determined based on the knowledge shown during classes and examinations and secondary assessment of the conducted experiments. Croatian, English (possible) Monitoring the student progress in the execution of experiments, analysis and physical understanding of the measured data, and writing reports on the executed experiment. During the performance of the course, students will be surveyed on the experiments suitability and quality of the scripts, teachers and assistants. 42 Course title Special and general relativity Course code F112 Type of course Lectures (30), Exercises (15) Level of course Basic course/ Elective course Year of study 3. ECTS 4 ECTS: Semester 6. - 45 class units ~ 34 h ~ 1.1 ECTS - about 116 h of independent student work with consultations ~ 2.9 ECTS Name of lecturer Ph.D. Josip Brana, Assistant Professor, Matko Mužević Goal of course The goal of the course is to introduce students to one of the two most important modern theories. Prerequisites Three mathematics, three general physics and classical mechanics Learning outcomes After a successfully finished course student will be able to: 1. Differentiate wrong general public ideas about the theory and what the theory is really about. 2. Understand time – spacial relations at the local and global levels 3. Understand the basis of Standard model 4. Understand the gravity as bending of space-time 5. Calculate the angle light bends under the influence of gravity 6. Calculate the increase of wavelength of light leaving Earth 7. Calculate time dilation corrections used in GPS satellites due to special and general relativity 8. Understand the basic characteristics of black holes 9. Understand the basic characteristics of gravitational waves 10. Understand the accelerated expansion of the universe in relation to Einstein's cosmological constant Outcome Learning Points ECTS Correlation of learning outcomes, teaching methods and evaluation Students activity Attendin g class 0.74 1-10 Attending class Record keeping 0 100 Knowled ge test 0.36 1-10 Individual preparation Written exam 0 100 Teaching activity Methods of evaluation min max (prelimin 43 ary exam) Final exam 2.9 1-10 Total 4.0 1-10 Individual preparation Oral exam 0 100 Consultations Every Tuesday at 12 h Gained competencies Understanding basic concepts and principles of the special and general relativity. Learning about consequences to measuring length and time and well known three tests of OTR. Understanding black holes in Universe, evolution of Universe and gravitational waves. Course contents Special theory of relativity: Michelson-Morley's experiments. Postulates of STR, Lorentz transformations and its consequences. Minkowsky 4-space-time. Mechanics in STR. Mechanics and Electrodynamics in 4th dim form. General theory of relativity: Postulates of OTR and programme of gravitation field description in a curved space-time. Riemann 4 – space-time. Tensor algebra and analysis in a Riemann space, generalization of derivation. Geodesics. Einstein's equations of gravitation field. Schwartzschield solution, black holes.Three classical tests of OTR. Linearised equations, gravitation waves. Friedman cosmological models and Hubble law. Accelerated universe expansion. Recommended reading 14. Josip Brana, Opća teorija relativnosti – Einsteinova teorija gravitacije (prvi dio), Odjel za fiziku sveučilišta „J. J. Strossmayer“, Osijek 2011. 15. W. D. McGlinn: Introduction to Relativity, The John Hopkins University Press, Baltimore and London, 2003. 16. B. Schutz, Gravity from the ground up, Cambridge University Press, 2004. 11. Hobson, M. P., Efstathiou, G. and Lasenby, A. N., General Relativity, An introduction for Physicists, Cambridge University Press, Cambridge, 2006. 12. Adler, Bazin, Schiffer, Introduction to General Relativity, McGraw-Hill 1975. 13. Supek: Teorijska fizika I struktura materije, Školska knjiga, Zagreb, 1977 14. http://www2.slac.stanford.edu/vvc/theory/relativity.html 15. http://archive.ncsa.uiuc.edu/Cyberia/NumRel/GenRelativity.html 16. http://www-groups.dcs.stand.ac.uk/~history/HistTopics/General_relativity.htm Theory on lectures and trough exercises problems solving Supplementary reading Teaching methods Assessment methods Written and oral exam Language of instruction Croatian/english Quality assurance methods Student's survey 44 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Introduction to Quantum Mechanics F113 Lectures (45), Numerical exercises (30) Basic 3. Semester 2. 7 Doc. dr. sc. Igor Lukačević Connect the historical development of quantum mechanics with previous knowledge and learn the basic properties of quantum world. General Physics 1, Mathematics 1, Mathematics 2 After successfully completed course, student will be able to: 1. pinpoint the historical aspects of development of quantum mechanics 2. understand and explain the differences between classical and quantum mechanics 3. understand the idea of wave function 4. understand the uncertainty relations 5. solve Schroedinger equation for simple potentials 6. spot, identify and relate the eigenvalue problems for energy, momentum, angular momentum and central potentials Consultations Gained competencies Content (Course curriculum) Teaching activity Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 7. explain the idea of spin Students activity Methods of evaluation Points min max Knowledge 3.5 1-7 Preparation for Written 0% 50% test – examination (preparatory) numerical exam part Knowledge 3.5 1-7 Preparation for Written 0% 50% test – examination (preparatory) theoretical exam part Total 7 0% 100% Yes - understanding and relating the events which led toward the development of quantum mechanics - understanding the basic principles of wave mechanics - ability to solve simple problems exactly - relating the knowledge of mathematics to the formalism of quantum mechanics - adapting the gained knowledge to high school generations Physics by the end of 19th and the beginning of 20th century. Historical development of quantum mechanics. Principles of quantum mechanics. Schroedinger wave mechanics: history and philosophical implications. Basic properties of wave mechanics and applications (potential barriers). Eigenvalues and eigenfunctions of quantum mechanical operators (energy, momentum, orbital momentum). Quantum harmonical 45 oscillator. Hydrogen atom. Electron spin. Electron in magnetic field (electron magnetic moment and nuclear magnetic resonance). Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up - R. L. Liboff, Introductory Quantum Mechanics, Addison-Wesley, 2003. - D.J. Griffiths, Introduction to Quantum Mechanics, Pearson Education Inc, New York, 2005. - Y. Peleg, R. Pnini, E. Zaarur, Schaum's outline of theory and problems of quantum mechanics, McGraw-Hill, New York, 1998. - Supek, Teorijska fizika i struktura materije, Školska knjiga, Zagreb, 1989. - L. I. Schiff, Quantum Mechanics, Mc-Graw Hill, New York 1968. - R.P. Feynman, R.B. Leighton, M. Sands, The Feynman Lectures on Physics – Volume III, Addison-Wesley Publications, Reading, 1966. - E.H. Wichmann, Quantum Physics: Berkeley physicscourse – Volume IV, McGraw-Hill, New York, 1971. - R. Ročak, M. Vrtar, Zbirka zadataka iz kvantne mehanike, Zagreb 1969. - P.A.M. Dirac, Principles of Quantum Mechanics, Oxford University Press, Oxfrod, 1978. - P.A.M. Dirac, Lectures on Quantum Mechanics, Dover Publications, New York, 2001. - W. Heisenberg, The Physical Principles of the Quantum Theory, Dover Publications, New York, 1949. Lectures (theory). Numerical exercises (numerical part). Seminars. Written exams via preparatory exams during the semester (5/semester) from numerical and theoretical part. Croatian; English Quality of knowledge shown via exams. Estimation of enthusiasm towards the subject. 46 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Fundamentals of the condensed mater physics F115 undergraduate (obligated) Intermediate 3rd Semester 6th 5 ECTS Dr.sc. Ramir Ristić associate professor With lectures, disscusion and excersises to introduce the students with some properties of metals, isolators and semiconductors. General Physics 1,2,3,4, and passed exam in Introduction in Statistical Physics After successfully completed course, student will be able to: 1. define and identify the structure of the crystal lattice 2. define and explain the conductors, semiconductors and insulators 3. Explain the occurrence diamagnetism, paramagnetism and ferromagnetism Consultations Gained competencies Content (Course curriculum) Recommended reading Additional reading Teaching activity Class attendance Knowledge 2,5 test (preliminary exam) Final exam 2,5 Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 4. Describe the appearance of superconductivity 1-4 1-4 Points Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list Written preliminary exam 50 50 Repetition of teaching materials Oral exam (and written exam) 50 50 min max Total 5 100 100 Monday 12-14 With lectures, disscusion and excersises to introduce the students with some properties of metals, isolators and semiconductors. Crystal Structure. Defects in crystal structure. Cohesive energy. Chemical Bondings. Crystal dynamics. Infrared absorption. Neutron and X-ray diffraction. Thermal expansion. Free electron gas. Heat capacity of the free electron gas. Thermoelectronic emission. Electron in periodic potencial. Effective electron mass. Density of electron states. Conductors and isolators. Transport properties. Wiedemann-Franz law. Matthiessens rule. Resistivity of the ideal metal. Hall effect. Metal in oscilator field. Superconductivity. Extrinsic semiconductors. Mobility in semiconductors. Magnetic properties. Diamagnetism, paramagnetism and ferromagnetism. 1. Šips, V. Uvod u fiziku čvrstog stanja, Školska knjiga, Zagreb, 1991. 2. Knapp, V., Colić, P. Uvod u električna i magnetska svojstva materijala, Školska knjiga, Zagreb, 1990. 1. Kittel, C. Introduction to Solid State Physics, J.Wiley, New York 1996. 2. J.R.Hook, Hall, H.E. Solid State Physics, J.Wiley, New York 1994. 3. I.Supek, Teorijska fizika i struktura materije, Školska knjiga, Zagreb, 1974 47 4. I. Kupčić, Fizika čvrstog stanja : zbirka zadataka. Zagreb : Hinus, 1998. Instructional methods Exam formats lectures (30 hours) and excercises (15 hours) Language Croatian. Quality control and successfulness follow up Student questionnaires. Oral and written exam, and two exams during semester. Students who pass both exams during semester are exempted from the written part of the exam in the summer and autumn examination period. To make the final score was positive, both,oral and written examination must be positive. To access the exam, students must be present in 50% of exercises and lectures. 48 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Introduction to astronomy and astrophysics F123 Lectures (30), Exercises (15) Elective course 3rd Semester 6th 4 ECTS Full professor Vladis Vujnović; Assistant profesor Igor Lukačević, PhD; Marina Poje, PhD. Develop an interest in astronomy and astrophysics. Competences acquired in courses on the first two years of undergraduate study. After successfully completed course, student will be able to: 1. Define and analyze the basic concepts in astronomy. 2. Describe the working principle of the telescope. 3. Identify important constellations - orient in space. 4. Describe the planets of the solar system and their properties. 5. Physical perceive and interpret phenomena in the Universe. Teaching activity Class attendance Colloquiums Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 6. Describe and understand the physical processes in the Sun and other stars. Students activity 0,5 1-6 Class attendance 1 1-6 Individual work (preparation of the seminar) 1 1-6 Final exam 1,5 1-6 Answering theoretical questions and solving numerical problems (calculating the required value). Preparation of the seminar (selection and reading the literature). Making ppt presentation + written form of seminar. Oral presentation of work. Interpretation of the important physical phenomena in Methods of evaluation Points min max Listing of attending students. 0 10 The written form of the colloquium prepared for each student. 0 30 Rating of the written work and assessment of the ppt presentation during the presentation. 0 20 Oral examination. 0 40 49 the Universe. Total Consultations Gained competencies 4 0 100 Vladis Vujnović: Wednesday, 9:00-10:00 Igor Lukačević: Wednesday, 10:00-11:00 Marina Poje: Wednesday, 11:00-12:00 GENERAL COMPETENCIES: 1. Understanding of basic physical concepts important in astrophysics. 2. Identify the problem, engage in problem solving and logical link key facts and elements. 3. Ability to interpret graphs and relations of physical quantities. 4. Teamwork 5. Developing accountability and ethics SPECIFIC COMPETENCIES: 1. Use of the correct units and their prefixes. 2. Recognition of certain constellations and / or stars; determining the direction of the north by the stars (orientation in space). 3. Handling measuring instruments and devices (eg. telescope assembly, manipulation of the telescope). Content (Course curriculum) Recommended reading Additional reading Instructional methods Exam formats • Introduction, historical review of the development of astronomy • How to think of the stars and constellations • Basic methods of determining the distance • Motion of the Earth • The mechanics of gravity • Astronomy of planets • Astronomical Instruments • Spherical astronomy • The Sun and the space climate • Physics of the stars • Cosmology • Observation of the sky (practical classes in the evening) Vujnović, V. ; Astronomija 1 , Školska knjiga, Zagreb, 1994. Vujnović, V. ; Astronomija 2 , Školska knjiga, Zagreb, 1994. Teaching materials: http://kolegij.fizika.unios.hr/uaa/nastavni-materijali/ Vujnović, V. ; Zvjezdane vatre dalekog svemira: fizikalna astrognozija, Profil, Zagreb, 2009. Vujnović, V. ; Astronomija (za učenike osnovne škole), Element, Zagreb, 1997. Hester, J., Burstein, D., Blumenthal, G., Greeley, R., Smith, B., Voss., H.; 21st Century Astronomy, Norton&Company Inc. Fifth Avenue 500, New York, 2006. Classes are conducted in accordance with the form of two-hour lectures and 1 hour of exercise per week. During the semester at least one practical class is organized in the evening hours - watching the sky with telescopes. At the end of the semester students in short presentations processed astronomical and astrophysical topics from the leading scientific journals (Nature, Science) on the selected topic at the beginning of the semester. During the semester, students take two written tests with theoretical and numerical tasks (colloquim). At the end of the semester student is obligate to hold the seminar on 50 Language Quality control and successfulness follow up the subject obtained at the beginning of the semester, after which will be held a final exam (oral examination). Croatian During the performance of the course, students will be interviewed anonymously on the suitability of selected topics in the field, and their performance. 51 Course title Code Status Level Year ECTS Lecturer Course objective Mathematics 1 (Differential calculus) M101 Lectures (30), exercises (45) Basic course 1. Semester 1. 6 Prof.dr.sc. Antoaneta Klobučar, Ljiljana Primorac Gajčić To introduce students to the basic ideas and methods of mathematical analysis, which are the basis for many other courses and training students to apply knowledge for solving specific problems. Prerequisites Knowledge of high school Learning outcomes: After successfully completed course, student will be able to: 1. understand and replay the correct mathematical proof of the claims by applying the basic forms of reasoning and mathematical logic Consultations Gained competencies Content (Course curriculum) Teaching activity Class attendance Knowledge test (preliminary exam) Final exam Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 2. understand and solve the problem of computing the derivatives, and the problem of testing functions Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list Repetition of teaching materials Oral exam (and written exam) Written preliminary exam Points min 0 max 300 0 100 Total Wednesday from 13.30pm-15pm At the introductory level introduce students to the basic ideas and methods of mathematical analysis, which are the basis for many other courses. Lectures will be given in an informal manner, illustrating their utility and application. At exercises students learn the necessary techniques and apply them to solve real problems. 1. Introductory section. Real numbers, infimum and supremum of a set, absolute value, intervals. Complex numbers. 2. Functions. The concept of a function and basic properties. Elementary functions. Composition of functions. Bijection and inverse function. 3. Sequences.of real numbers. The concept of a sequence, properties and convergence. The number e. 4. Limits and continuity of functions. Limit of function. Properties of the limit. One-sided limits. Infinite limits and limits at infinity. Asymptote. Continuity and properties of continuous functions. 5. Differential calculus. Problems of tangents and speed. The derivative. The 52 derivative. Rules for finding the derivative. Derivatives of elementary functions. Derivatives of an implicit function. Derivatives of an parametric function. Lagrange’s mean value theorem. Higher derivatives. Taylor's theorem. 6. Recommended reading Additional reading Applications of the differential calculus. The differentia. Newton's tangent’s method. L'Hôpital's rule. Testing functions (monotonicity, extrema, convexity, the asymptote). - W.Rudin, Principles of Mathematical Analysis, Mc Graw-Hill, Book Company, 1964. -D. Jukić, R. Scitovski, Matematika I, Department of Mathematics, University of Osijek, Osijek, 2000 - S. Kurepa, Matematička analiza 1 (diferenciranje i integriranje), Tehnička knjiga, Zagreb, 1989. - S. Kurepa, Matematička analiza 2 (funkcije jedne varijable), Tehnička knjiga, Zagreb, 1990. Instructional methods -B.P. Demidovič, Zadaci i riješeni primjeri iz više matematike s primjenom na tehničke nauke, Tehnička knjiga, Zagreb, 1986 Lectures and exercises are mandatory. Exam formats The exam consists of a written and oral examination, which is taken after completion of lectures and exercises. During the semester, students can take three tests that replace the written examination. Language Quality control and successfulness follow up Croatian An anonymous questionnaire 53 Course title Code Status Level Year ECTS Lecturer Course objective Mathematics 2(Integration calculus) M102 Lectures (30), exercises (45) Basic course 1. Semester 2. 6 Prof.dr.sc. Antoaneta Klobučar, Ljiljana Primorac Gajčić To introduce students to the basic ideas and methods of mathematical analysis, which are the basis for many other courses and training students to apply knowledge for solving specific problems. Prerequisites Differential calculus Learning outcomes: After successfully completed course, student will be able to: 1. understand and replay the correct mathematical proof of the claims by applying the basic forms of reasoning and mathematical logic Consultations Gained competencies Content (Course curriculum) Teaching activity Class attendance Knowledge test (preliminary exam) Final exam Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 2. understand and solve the problem of computing the integral Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list Repetition of teaching materials Oral exam (and written exam) Written preliminary exam Points min 0 max 300 0 100 Total Wednesday from 13.30pm-15pm At the introductory level introduce students to the basic ideas and methods of mathematical analysis, which are the basis for many other courses. Lectures will be given in an informal manner, illustrating their utility and application. At exercises students learn the necessary techniques and apply them to solve real problems. 1. The Riemann integral. The problem of an area. Definition and properties of the Riemann integral. Integrability of monotone and continuous functions. The mean value theorem of integral calculus. Newton-Leibniz formula. Indefinite integral. Methods of integration. Basic techniques of integration. Application of integration: area between two curves, volumes of revolution, length of curve, work force, torque, center of mass. Improper integrals. Numerical integration (trapezoidal and Simpson's rule). 2. Series of real numbers. Infinite series and convergence. The convergence criteria. 54 3. Recommended reading Additional reading Series of functions. Rows function. Uniform convergence. Power series. Taylor series of elementary functions. Exponential and logarithmic functions. - W.Rudin, Principles of Mathematical Analysis, Mc Graw-Hill, Book Company, 1964. -D. Jukić, R. Scitovski, Matematika I, Department of Mathematics, University of Osijek, Osijek, 2000 - S. Kurepa, Matematička analiza 1 (diferenciranje i integriranje), Tehnička knjiga, Zagreb, 1989. - S. Kurepa, Matematička analiza 2 (funkcije jedne varijable), Tehnička knjiga, Zagreb, 1990. Instructional methods -B.P. Demidovič, Zadaci i riješeni primjeri iz više matematike s primjenom na tehničke nauke, Tehnička knjiga, Zagreb, 1986 Lectures and exercises are mandatory. Exam formats The exam consists of a written and oral examination, which is taken after completion of lectures and exercises. During the semester, students can take three tests that replace the written examination. Language Quality control and successfulness follow up Croatian An anonymous questionnaire 55 Course title Code Status Level Year ECTS Lecturer Course objective Mathematics 3 – Function of several variables M104 Lectures (30), Exercises (30) Basic course 2 Semester 3 5 ECTS prof.dr.sc. Ninoslav Truhar, assistant dr.sc. Ivana Kuzmanović The objective of the course is to provide insight into the fundamental parts of mathematics related to functions of several variables: the area of definition, continuity and limes, derivatives and integrals of functions of several variables. Students should be encouraged to think critically and to research. Prerequisites Learning outcomes: Mathematics 1, Mathematics 2 After successfully completed course, student will be able to: 1. recognize and explain the fundamental concepts of differential and integral calculus of real and vector functions of several variables, such as the continuity of functions, limits, partial derivatives and differential of function, as well as multiple, curve and surface integrals; 2. to calculate partial derivatives of complex functions, implicit and parametric functions; 3. to use calculus to compute the tangent plane and normal vector, and to determine the local extremes of functions of several variables 4. calculate areas and volumes using double and triple integrals; Consultations Gained competencies Content (Course curriculum) Teaching activity Class 1 attendance Knowledge 2 test (preliminary exam) Final exam 2 Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 5. calculate curve and surface integrals, and use them to calculate lengths, areas and volumes. 20 40 40 Points Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list 10 20 Written preliminary exam 40 100 Repetition of teaching materials Oral exam (and written exam) 40 100 min max Total 5 100 90 220 Consultations are held once a week In this course students are introduced to the differential and integral calculus of functions of several variables and vector functions. Primarily the focus is on situations in which the geometric view is possible, i.e. real functions of two or three variables, and functions from R to R2 and R3. During lectures, basic concept is introduced, analyzed, and illustrated by examples. During the exercises students train appropriate techniques to approach to specific problems and for solving them. Real functions of several variables. Space Rn. Level-curves and level surfaces. Limits and continuity. Partial derivatives and differentiability of functions of several variables. Partial 56 Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up derivatives of implicit functions and composite functions. Partial derivatives and differentials of higher orders. Vector functions. Vector functions of one variable - the derivation and integration. Differentiability of vector functions of several variables; Jacobi matrix. Applications of differential calculus of functions of several variables. Equation of tangent plane to the surface. Taylor's formula. Extremes and conditional extremes. Multiple integrals. Double integral - definition, properties, calculation, substitution variables (polar coordinates), applications. Triple integrals (cylindrical and spherical coordinates). Line integrals (first and second). Concept, properties, calculation, applications. Surface integrals (first and second). Concept, properties, calculation, applications. Scalar and vector fields. Directional derivative of a scalar field. Gradient of a scalar field. The divergence of a vector field. Rotation of a vector field. Theorem of GaussOstrogradsky. Stokes' theorem. - S. Suljagić, Matematika II, http://www.grad.unizg.hr/nastava/matematika/mat2/index.html - Slapničar, Matematika 2, - http://lavica.fesb.hr/mat2/ S. Kurepa, Matematička analiza 3: Funkcije više varijabli, Tehnička knjiga, Zagreb, 1984. B.P. Demidovič, Zadači i upražnjenja po matematičeskomu analizu, FM Moskva, 1963. - P. Javor, Matematička analiza 2, Element, Zagreb, 2000. - Š. Ungar, Matematička analiza u Rn, Golden marketing-Tehnička knjiga, Zagreb, 2005. - G.N. Berman, Zbornik zadač po kursu matematičesko analiza, Nauka, Moskva, 1972. - S. Lang, Calculus of Several Variables, Springer, New York, 1987. - M. Lovrić, Vector Calculus, Addison-Wesley Publ.\ Ltd., Don Mills, Ontario, 1997. Lectures and exercises are obligatory for all students. The exam consists of a written and oral part and it is taken after completion of lectures and exercises. During the semester, students can take two or more colloquiums that replace the written examination. Croatian An anonymous student survey 57 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Linear algebra 1 M103 Lectures (30), Seminar (0), Auditorium Exercises (30) Elective course 1 Semester 2 6 Dr. Darija Marković, Assistant Professor Introduction to basic concepts and problems of linear algebra. Geometry of plane and space After successfully completed course, studentswill be able to: 1. describe the structure and give examples of vector space; 2. explain the concepts of linear dependence and independence; 3. solve the task of determining the base and/or dimension of a vector space; 4. use the matrix operations; 5. examine the regularity of the square matrix; 6. describe the necessary and sufficient conditions for the solvability of the system of linear equations; 7. identify and apply different ways of solving linear systems; 8. check the linearity of the operator; 9. explain the concepts of rank and nullity of linear operators; 10. determine the matrix form of a linear operator; 11. express definition of eigenvalues and eigenvectors; 12. describe the finding of the characteristic and the minimal polynomial of a linear operator; 13. specify the definition and examples of inner product; Consultations Teaching activity Class attendance 0.4 Knowledge test (preliminary exam) Final exam 3.3 2.3 Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 14. implement the Gram-Schmidt orthogonalization process 1., 2., 6., 9., 11., 13. 3., 4., 5., 7., 8., 10., 12., 14. 1.-14. Students activity Methods of evaluation Class attendance Evidence list Preparation for written examination Written preliminary exam Repetition of teaching materials Oral exam (and written exam) Points min No points given 30 max 100 No points given Total 6 On official office hours and by appointment 58 Gained competencies Content (Course curriculum) Students are becoming familiar with basic knowledge of linear algebra and competence in their application, such as mastery of basic methods of matrix and vector operations, solving systems of linear equations, application of orthogonalization process 1. Matrices. Systems of linear equations. Concept of matrices and operation with them – Mm,n(F). space. Diagonal, identity, transpose hermite-conugate matrices. Trace and determinante of matrices. Product of matrices. Nonsingular matrices. Inverse matrices. 2. Vector spaces. Definition. Examples. Subspaces. Linear combinations. Summs of subspaces. Linear dependence and independence. Basis vectors. 3. Vector spaces of finite dimension. Linear dependence. Definition of finite dimensionality. Basis. Dimension. Direct sum and complement. Isomorphism. 4. Linear operators. Definition. Theorem about rank and nullity. Operations with operators. Correspondence matrices – operators. Characterisation of an isomorphism with a matrix regularity. Connection between matrices of same operator for different basis. 5. Polynoms of lin. operator. Minimal polynoms. Eigenvalues and eigenvectors (spectra of operators). Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up D. Bakić, Linearna algebre, Školska knjiga, Zagreb, 2008. D. Butković, Predavanja iz linearne algebre, Department of Mathematics, University of Osijek, 2010. S. Kurepa, Konačno dimenzionalni vektorski prostori i primjene, Liber, Zagreb, 1992. S. Kurepa, Uvod u linearnu algebru, Vektori - matrice - grupe, Školska knjiga, Zagreb, 1978. K. Horvatić, Linearna algebra, 9. izdanje, Tehnička knjiga, Zagreb, 2003. S. Lang, Introduction to Linear Algebra, Springer – Verlag, 1980. S. Lang, Linear Algebra, Springer – Verlag, 2004. G. Strang, Introduction to Linear Algebra, Cambridge Press, 1998. Lectures, Auditorium Exercises, Consultations The exam consists of oral and written parts of exam. The students can go in for an exam after attending all lectures and after doing all exercises. During one semester there is a possibility for the students to go in for 2 preliminary exams; these exams can replace the written part of the exam. Croatian An anonymous questionnaire 59 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Differential equations M105 2+0+2 Basic 2 Semester 4 6 doc.dr.sc. Krešimir Burazin, Ivana Vuksanović, prof. Introduce students with the concept and geometric meaning of ordinary differential equations, and with general theorems of existence and uniqueness of solutions. Demonstrate basic types and methods for finding solution with particular emphasis on the theory of linear equations. Mathematics 1. and 2. After successfully completed course, student will be able to: 1. identify some real world problems that can be modeled by differential equations; 2. identify and explain the fundamental concepts, such as solution of equation, Cauchy problem, slope field and sensitivity to initial conditions; 3. express in their own words conditions that ensure the existence (and uniqueness) of solution of Cauchy problem; 4. solve different types of equations of the first order as well as higher order equations that allow reduction of order; Consultations Gained competencies Content (Course curriculum) Teaching activity Class 2 attendance Knowledge 2 test (preliminary exam) Final exam 2 Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 5. solve linear equations and systems; all all all Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list Repetition of teaching materials Oral exam (and written exam) Points min max Written preliminary exam Total two times a week Capability of modelling real-world problems with differential equations, as well as solving them. 1. Introduction. Sources of ordinary differential equations. Notion of solutions: general and particular. Cauchy problem. The geometric meaning. Problem of sensibility on change of initial conditions. 2. Ordinary differential equations of the first order. Solution and slope field. Existence and uniqueness theorems. Some types of ordinary differential equations of the first order (exact, homogeneous, linear, Bernoulli, Lagrange, Clairaut, Riccati). Examples and applications. 3. Ordinary differential equations of second order. Some special types. Linear differential equation of second order. Lagrange's method of variation of constants. Linear differential equations of second order with constant coefficients. Laplace 60 transform. Examples and applications (harmonic oscillator). 4. Ordinary differential equations of higher order. 4. Systems of ordinary differential equations. System of linear equations with constant coefficients. Examples and applications (ballistic problem in vacuum and air). Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up 6. Appendix. Partial differential equation. Concept, examples and basic methods for solving them. M. Alić, Obične diferencijalne jednadžbe, PMF - Matematički odjel, Zagreb, 2001. I. Ivanšić, Fourierovi redovi. Diferencijalne jednadžbe, Department of Mathematics, University of Osijek, Osijek, 2000. W.E. Boyce, R.C. DiPrima, Elementary Differential Equations and Boundary Value Problems, 7th edition, John Wiley & Sons, 2000. L.E. Eljsgoljc, Differencialjnie uravnenija, Gosudarstvenoe izdateljstvo tehnikoteoretičeskoj literaturi, Moskva, 1957. G.F. Simmons, J.S. Robertson, Differential Equations with Applications and Historical Notes, $2^{nd$ Ed., McGraw-Hill, Inc., New York, 1991. Schaum's outline series, McGRAW-HILL, New York, 1991. S. Kurepa, Matematička analiza 2 (funkcije jedne varijable), Tehnička knjiga, Zagreb, 1990. Exercises are are auditory, with usage of computer and LCD projector. The exam consists of a written and oral part and can be is taken after the completion of lectures and exercises. Acceptable scores on 2-4 midterm examinations, which students write during the semester, replace the written examination. Students can also make a seminar paper which can affect the final grade. Croatian Anonymous survey testing of students . 61 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Geometry of plane and space – Introduction in algebra M106 Lectures and auditory exercises. Elective course. 1. Semester 1. 5 Assistant professor Tomislav Marošević, mag. math. Darija Brajković The objective of the course at the introductory level based on geometry of plane and space is to make students familiar with fundamentals of linear algebra. None. After successfully completed course, student will be able to: 1. know about term of vector and basic vector operations in plane and space with corresponding applications 2. understand concept of introduction of linear operator on vector space, as well as connection with the term of matrix, and know matrix calculation 3. generalize all the mentioned terms into several dimensions and at more abstract level Consultations Gained competencies Content (Course curriculum) Teaching activity Class 1 attendance Knowledge 2 test (preliminary exam) Final exam 2 Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 4. adopt basic principles of proving of mathematical assertion. 20% 40% 40% Points Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list 0 10 Written preliminary exam 0 40 Repetition of teaching materials Oral exam (and written exam) 0 50 min max Total 5 On Monday 11:00 – 12:00, on Thursday 13:30 -14:00, or as agreed upon. Knowledge on fundamentals of linear algebra based on geometry of plane and space (elementary vector operations in plane and space, symetric and orthogonal linear operators in plane and space, square matrices, curves of the second order). 1.Operations with vectors. Linear dependence and independence of vectors. Basis of vector spaces. Coordinate system. Norm of vectors. Distance between two points. Cauchy - Schwarz - Buniakowsky inequality. Vector dot/scalar product. Direction cosine. Projection of vector to the line and plane. Gramm - Schmidt orthonormalization process. 2. Square matrix of the second and third order and their determinants. Orientation − right and left basis and coordinate systems. Vector cross product. Algebraic properties. of the vector product. Geometrical properties of the cross product. Scalar triple product. Vector triple product. Jacobi identity. Straight line and plane in space. Hesse normal form of line and plane. 3. Linear operators in plane. Examples of operators: axial symmetry, central symmetry, 62 homothety, orthogonal projection, rotation. Basic properties of the linear operator. Operations with linear operators − vector space . Products and power of the linear operator. Matrix of the linear operator. Algebra of the matrix of the second order. Contraction and dilatation of the plane − eigenvectors and eigenvalues of the linear operator. Symmetric linear operator in the plane. Orthogonal linear operator in the plane. Diagonalization of the symmetric linear operator. Quadratic forms. Curves of the second order. 4. Linear operators in space . Examples. Transfer of all definitions from plane. Symmetric linear operator in the space. Surfaces of the second order. Recommended reading 1. R.Scitovski, Geometrija ravnine i prostora, reviewed course materials available on the course website, Department of Mathematics, University of Osijek, Sveučilište u Osijeku, 2011. 2. S. Kurepa, Uvod u linearnu algebru, Školska knjiga, Zagreb, 1978. Additional reading 1. D.Bakić, Linearna algebra, Školska knjiga, Zagreb, 2008. 2. N. Elezović, Linearna algebra, Element, Zagreb, 2001. 3. J.Hefferon, Linear Algebra, Saint Michael's College, Colchester, Vermont, USA, 2011 – freely available at: http://joshua.smcvt.edu/linearalgebra/book.pdf 4. D.Jukić, R.Scitovski, Matematika I, Department of Mathematics, University of Osijek, Sveučilište u Osijeku, Osijek, 2004. Instructional methods Exam formats Language Quality control and successfulness follow up Lectures and auditory exercises are obligatory to all students The exam is taken after completion of lectures and exercises, and it consists of a written and an oral part. There are 2 midterm exams during the semester that cover the entire course syllabus. Once a student has successfully passed all mid-term exams, he/she does not have to take the written part of the exam. Croatian University inquiry. 63 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Elementary Informatics I101 Obligatory course; Lecture (30), Laboratory Exercises (30) Elementary 1st Semester 1st 4 Branimir Dukić, Phd, Full Professor, Miroslav Katić, assistant Introduce students with basic knowledge in the field of information and computer science None After successfully completed course, student will be able to: 1. Applying theoretical knowledge to increase personal safety in achieving computer and information literacy 2. Define the basic concepts in the field of information technologies 3. Define the term information system Consultations Gained competencies Content (Course curriculum) Teaching activity Class 1 attendance Knowledge 1 test (preliminary exam) Final exam 2 Learnin g outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 4. Explain the role of information systems in the communication process 1-6 1-6 1-6 Points Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list Written preliminary exam 0 10 0 40 Repetition of teaching materials Oral exam (and written exam) 0 50 min max Total 4 according to the agreement Fundamental knowledge acquired in this course are the basis for further study of ICT and non ICT courses where is necessary usage of a computer. Basic concepts - definitions and classifications, codes and coding, number systems, writing numbers in arithmetic of fixed and floating point, parity checking with bits parity (parity bit), basic logic circuits, basic arithmetic circuits, memory, flip-flops, registers, transferring data between registers, decoders, counters, parts of a computer system, a microprocessor, a Turing machine, von Neumann's model, an overview of the Cisco and rISC computers, organizations of data processing, material carriers of data, input-output units, font , files, data display techniques, software subsystem, operating systems, user oriented software, computer networks, communication protocols, Intranet and Internet, the role of information systems in the communication process, data bases, data warehouse, knowledge base, multimedia and hypertext content, virtual environment, elements of the information system, the types of 64 information systems, methods of construction information system Recommended reading - Šimović, V.: Uvod u informacijske sustave, Golden marketing, Zagreb, 2009. - Tuđman, M.: Teorija informacijske znanosti, Hrvatska sveučilišna naklada, Zagreb 2014. - Ribarić S.: Arhitektura pete generacije računala, Školska knjiga, Zagreb, 1990. - Smiljanić G.: Mikroračunala, Školska knjiga Zagreb, 1986. - 1996. - Kvaternik R.: Uvod u operativne sisteme, Informator, Zagreb, 1991. Additional reading 1. Budin, L.: Informatika za 1. razred gimnazije, Element, Zagreb 1996. 2. Williama K.B.: Sawyer C.S., Hutchinson E.S., Using Information Technology, R.D. Irwin, Inc, USA, 1995. 3. Ribarić, S.: Arhitektura računala RISC i CISC, Školska knjiga, Zagreb 1996. Instructional methods Exam formats Language Quality control and successfulness follow up Lectures, laboratory exercises Written and oral examination with colloquia Croatian, English The quality and success of the course can be monitored through the systems of knowledge testing, through making their own practical works in accordance with the given tasks, and the ability of students to use accepted knowledge and skills that acquired in this course and other courses. 65 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: E-OFFICE I102 Mandatory course; Lecture (-), Seminar (-), Exercises (30) Elementary 1st Semester 1st 3 Darko Dukić, PhD, Associate Professor; Stojanka Dukić, PhD, Lecturer. The main goal of this course of lectures: to develop general and specific knowledge dealing with the usage of office tools, to become familiar with standards and norms of electronic business (education) and with the principles of the modern business communication. None After successfully completed course, student will be able to: 1. Recognize and use basic office computer hardware and software 2. Create basic documents and worksheets Correlation of learning outcomes, teaching methods and evaluation Consultations Gained competencies Content (Course curriculum) Recommended reading Teaching activity ECTS 3. Create presentation for educational purposes Class 1 attendance Knowledge 1 test (preliminary exam) Final exam 1 Points Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list 10 Written preliminary exam 40 Repetition of teaching materials Written exam 50 Total 3 Stojanka Dukić: Tuesday 10-12h min max 100 Student gain basic knowledge and skills to create basic types of office documents Business office structure. Automation business office. Office equipment. Printers. Plotters. Scanners. Software. Operating systems. Office tools. Design tools. Documentation tools. Databases. Organizers. Directories. Communication tools. Presentation tools. Other software. Intelligent assistance in work. Documentation. Electronic multi-purpose documents and standards. Intranet. Computer-supported cooperation. Internet. Remote presence and distance work. Object model of documents, hypertext and hypermedia. Processing, storing, access. Reproduction and storage of documents. Document storage. Electronic pollution. 1. Srića, Velimir; Kliment, Antun i Knežević, Blaženka: Uredsko poslovanje: Strategija i koncepti automatizacije ureda, Zagreb, Sinergija, 2003. 2. Mesarić, J., Zekić-Sušac, M., Dukić, B.: Alati za uredsko poslovanje, EFO, Osijek 2010. 3. Informatika i računalnstvo – udžbenik, V. Galešev, P.Brođanac, M. Korać, Lj. Miletić, S. Grabuzin, S. Babić, Z. Soldo, L. Kralj, G. Sokol, D. Kovač, SysPrint 4. Informatika i računalnstvo – zbirka zadataka, V. Galešev, P.Brođanac, M. Korać, Lj. Miletić, S. Grabuzin, S. Babić, Z. Soldo, L. Kralj, G. Sokol, SysPrint 66 Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up 1. D.Chaffey: Groupware, Workflow and Intranets. Reengineering the Enterprise with Collaborative Software, Digital Press, Boston, MA, 1998. 2. Kliment, Antun: Digitalne poslovne komunikacije, Ekonomski fakultet Zagreb, Mikrorad, 2000. Auditory presentations, problem solving, laboratory practice . Testing laboratory practice, written and oral examinations Croatian, English The quality and success of the course can be observed through the systems of assessment, through practical work in accordance with the given tasks, and through the level of students' ability to use the skills and knowledge acquired in this course in other courses as well. 67 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Algorithms and data structures I104 Elective course Elementary 1st Semester 2nd 6 Gordana Dukić, Ph.D., Associate Professor The aim of the course is to provide students with basic knowledge in data structures and to train them to develop and implement algorithms. Special emphasis is placed on the problems of linear programming, integer programming, and multicriteria linear programming. None After successfully completed course, students will be able to: 1. Use and implement simple and complex data structures and algorithms. 2. Explain the influence of data on the performance and speed of the algorithm. 3. Distinguish the types and data structures. 4. Identify and eliminate errors in algorithms. 5. Write algorithms for solving systems of linear and nonlinear equations. 6. Apply the method of least squares. 7. Algorithmically consider mathematical models. Consultations Gained competencies Teaching activity Class attendance Knowledge test: preliminary exams or written/oral exam Homework Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 8. Solve problems of linear programming, integer programming and multicriteria linear programming. 1,5 1-8 2,5 1-8 1,5 1-8 Points Students activity Methods of evaluation Class attendance Preparation for preliminary exams or written/oral exam Evidence list 0 0 Preliminary exams grade or written/oral exam grade 0 90 Doing homework Evaluation of homework Evaluation of presentation 0 0 min max Presentation 0,5 1-8 Preparation 0 10 of a topic and related to presentation of the course a topic Total 6 0 100 In a previous agreement with students After successfully completing the course the student will be able to develop, use and implement simple and complex data structures and algorithms. The participant will also understand the influence of data on the performance and speed of the algorithm. 68 Content (Course curriculum) Recommended reading Types and data structures. Operations on data. Errors. Interpolation. Solving systems of linear equations. Solving systems of nonlinear equations. The method of least squares. Nonlinear least squares problem - Gauss-Newton method. Mathematical models. Mathematical programming. Linear programming. Integer programming. 0-1 programming. Multicriteria linear programming. Nonlinear programming. 1. Barković, D.: Operacijska istraživanja, Ekonomski fakultet, Osijek, 2001. 2. Björck, A.: Numerical Methods for Least Squares Problems, SIAM, Philadelphia, 1996. 3. Predavanja: http://moodle.fizika.unios.hr/course/view.php?id=16 Additional reading 1. Scitovski, R.: Numerička matematika, Elektrotehnički fakultet, Osijek, 2000. 2. Scitovski, R.: Problemi najmanjih kvadrata. Financijska matematika, Ekonomski fakultet, Elektrotehnički fakultet, Osijek, 1993. 3. Wolfram, S.: The Mathematica Book, Wolfram Media, Champaign, 1999. Instructional methods Exam formats Language Quality control and successfulness follow up Lectures (30), laboratory exercises (30). Two exams during the semester or written/oral examination. Students who regularly attend classes and achieve more than 55% marks in their preliminary exams are exempt from the written/oral examination. Croatian/English. Students' survey. 69 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Multimedia systems I105 30+15+0+15 Elementary 3nd 3nd 3nd 5 Prof.dr.sc. Branimir Dukić; Slavko Petrinšak, MA, Lecturer Adoption of factual knowledge and development of skills needed for independent development of multimedia systems and applications using available hardware and software tools. None After successfully completed course, studentd will be able to: 1. Describe the types of media and define multimedia system. 2. Describe the process of digitizing (quantization) of different analog signals (text, graphics, sound and video). 3. Use and apply tools for image processing, video, sound and animation. 4. Apply methodology to develop a multimedia system. Consultations Gained competencies Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 5. Apply acquired knowledge in the field of multimedia in practice and independently continue to expand knowledge in this field. Class attendance Laboratory exercises 0,2 1-6 Homework 1 1-6 Seminar presentation, discussion. Knowledge 1, test (preliminary exam) Final exam 1 1-6 Preparation for written examination 1-6 Repetition of teaching materials Teaching activity 0,8 Students activity Class attendance The research on a given topic and creation of work materials. Methods of evaluation Evidence list The relevance of the data collected and the accompanying media. Rating writing seminars (up 5 points) and verbal rating exposure (up to 5 points) Evaluation (professor, students) and self-evaluation Oral exam and written exam Points min max 0 5 20 25 0 25 0 25 Total 4 0 100 Darko Dukić, PhD, Associate Professor ; Wednesday 11-13h Slavko Petrinšak, MA, Lecturer ; Monday 10-12h Information and communication competencies. Solving the given problem. Collaborative work and respect of other people's opinions addressing the terms of 70 reference. Application of ICT in the development of educational materials. Communication skills (written and spoken). Content (Course curriculum) Media types (text, graphics, images, audio, speech, video, animation). The components of the multimedia system. Hypermedia and the Web. Review of multimedia software tools and authorization. VRML. Graphics and images: display types and file formats. Review of color images and video clips: basic models of color. Video: Component and composite video, S-video, analog and digital video. Digital Audio: Sampling, quantization, coding and transmission of sound. Compressing multimedia data with and without losses. Standards of compressing still images. Basic techniques of compressing video and audio. Requirements to computer and system software in multimedia applications. Apparatus for collecting and storing multimedia data. The requirements of the human-computer interface in multimedia. Multimedia networks and transmission of images. Visualization. Legal aspects of multimedia. Recommended reading • N. Chapman, J. Chapman. Digital Multimedia, John Wiley & Sons, New York, 2004. • Yun Qing Shi, Huifang Shu, Image and Video Compression for Multimedia Engineering, CRC Press, New York, 2008. • Z-N Li, M.S. Drew. Fundamentals of Multimedia • R.W. Sebesta, Programming the World Wide Web (2nd Ed.), Addison Wesley, Boston, 2003. • Manuals for working with the selected software tools for creating multimedia elements and systems ( Adobe Photoshop, Adobe Premiere , Adobe Flash, Gif animation, Windows Movie Maker, ... Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up Lectures, seminars and laboratory exercises. In the exercises, students should accomplish independent creation and treatment of preexisting media files with the help of a support program for producing images, hypertext, sound, animation and video. Written and oral exam with the preliminary exam through exercises and assignments. Croatian/English An anonymous survey held after each teaching theme (teacher reflection on amendments to certain segments continue to improve the quality of direct work with students). Unique University student survey where students assess their satisfaction with the quality of teachers and teaching assistants in each course, and course performance in general (the survey is a good starting point for self- evaluation of teachers and teaching assistants throughout the academic year). 71 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Basics of Programming 1 I106 Lectures (15), Laboratory exercises (30) Basic 2 Semester 3 4 doc.dr.sc. Alfonzo Baumgartner, Miroslav Katić, prof. Acquire basic knowledge of software development, and especially application software. The given target is reached by teaching and learning: basic terms of programming, software development, algorithms and data structures and their application in a high level programming language, methods of programming. none After successfully completed course, student will be able to: 1. To define the basic terms in the field of programming 2. To use simple algorithms and to know how to implement them in a structured programming language 3. To write and to test programs which solve simple arithmetic problems Correlation of learning outcomes, teaching methods and evaluation Gained competencies Content (Course curriculum) 1 Le ar ni ng ou tco me 1,2 1 1-3 2 1,2 Teaching activity Class attendanc e Knowled ge test (prelimin ary exam) Final exam Consultations E C T S Points Students activity Methods of evaluation min max Class attendance Evidence list 4 10 Preparation for written examination Written preliminary exam 16 40 Repetition of Oral exam 20 50 teaching (and written materials exam) Total 4 40 100 A. Baumgartner: Tuesdays 10-12h, ETF building at campus, C. Hadrijana 10B, office K0-5 (ground floor ) Understanding the basic concepts of programming. The ability to use simple algorithms in a structured programming language to solve simple arithmetic problems. Understanding and use of elementary data types and simple data structures. Programming, software (system and application). Programming languages (machine, assembler, high level programming languages). Compiler, Interpreter. Basics of software development. (analysis and problem specification, algorithm. Flowchart, pseudocode, coding programs, writing and insertion of instruction in the computer, test programs and debugging, maintenance, documentation). Algorithmic structures (linear, branched, cyclic structure). Guide trough structurally oriented programming 72 language (input-output instructions, decision instruction, programming loops, functions, files and file types). Programming approach (monolithic, structured, object-oriented). Recommended reading S. Stankov: /Programiranje I./, Fakultet prirodoslovno-matematičkih znanosti i odgojnih područja Sveučilišta u Splitu, listopad, 2003. Additional reading R. Simon, M. Schmidt. Teach Yourself Visual C++.NET in 24 Hours, Sams, Indianapolis, 2002. Instructional methods Exam formats Language Quality control and successfulness follow up Lectures and laboratory exercises Written and oral exam with the preliminary exam Croatian / English The quality and success of the course can be seen through the system assessment, through the creation of their own practical works in accordance to given assignments, and the ability of students to use the knowledge and skills acquired in this course on the other courses 73 Course title Code Status Level Year ECTS Lecturer Course objective Basics of Programming 2 I107 Lectures (15), Seminars (15), Laboratory exercises (30) Optional course 2 Semester 4 4 doc.dr.sc. Alfonzo Baumgartner, Miroslav Katić, prof. The goal of this course is to train students for programming in modern development environments and work in programming teams. Furthermore, students should acquire knowledge about the software evaluation and testing methods. These goals are achieved through the introduction to basic methods and programming paradigms through lectures as well as appropriate exercises where students develop software independently and as a part of the team. Prerequisites Learning outcomes: Basics of Programming 1 After successfully completed course, student will be able to: 1. To define the basic terms of software development 2. To use integrated environment for software development 3. To make simple programming tasks in a team using an object-oriented approach to software development 4. To understand and practicaly implement the different phases of software development (requirements, design of models, design architecture, design of individual parts, testing, documentation) Correlation of learning outcomes, teaching methods and evaluation Consultations Gained E C T S Pohađanj e predavan ja i vježbi Seminar work 1 Le ar ni ng ou tco me 1-4 1 3,4 Knowled ge test (prelimin ary exam) Final exam 1 1-4 1 1-4 Teaching activity Points Students activity Methods of evaluation min max Class attendance Evidence list 4 10 Preparation and presentation of seminars Preparation for written examination Presentation and paper rating 8 20 Written preliminary exam 12 30 Repetition of Oral exam 16 40 teaching (and written materials exam) Total 4 40 100 A. Baumgartner: Tuesdays 10-12h, ETF building at campus, C. Hadrijana 10B, office K0-5 (ground floor ) Understanding the basic concepts of software development. Ability to use modern 74 competencies Content (Course curriculum) Recommended reading development environments for development and testing of software. Understanding of individual roles and different phases in the software development process. Comparative overview and classification of programming languages, examples of programming languages, methodologies of software development, an overview of programming paradigms, structured programming, modular programming, object oriented programming, presentation and comparison of different development environments of software development, development of applications with a graphical user interface using appropriate development environment, the basics of programming network applications, web programming, methods of storing data, testing software. -Robert W. Sebesta: Concepts of Programming Languages, Addison Wesley, 6 edition, 2003. -Paul Kimmel: Advanced C# Programming (McGraw-Hill/Osborne), ISBN: 953-7063-07-0 -Luke Welling, Laura Thomson: razvoj aplikacija za Web, ISBN 86-7555-237-8 -Blake Schwendiman: PHP4 Vodic( za programere, ISBN: 86-7555-173-8 -Greg Buczek:ASP Developer's Guide (The McGraw-Hill Companies, Inc., 2000), ISBN: 86-7555-171-1 Additional reading -Hugh E. Williams, David Lane: Web Database Applications with PHP & MySQL (O'Reilly), ISBN 86-7555-225-4 -Eric A. Smith: Active Server Pages 3 Weekend Crash Course, ISBN: 86-7555176-Charles Wright: C# Tips & Techniques (McGraw-Hill/Osborne, 2002.) Instructional methods Exam formats Language Quality control and successfulness follow up Lectures and laboratory exercises Written and oral exam with the preliminary exam Croatian / English The quality and success of the course can be seen through the system assessment, through the creation of their own practical works in accordance to given assignments, and the ability of students to use the knowledge and skills acquired in this course on the other courses 75 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Databases and Process Analysis I102 Mandatory course; Lecture (30), Laboratory Exercises (30) Elementary 3th Semester 5th 5 Branimir Dukić, Phd, Full Professor, Miroslav Katić, assistant Enable students to create a database and use the database management system None After successfully completed course, student will be able to: 1. Analyze business structure, events and processes in the function of database modeling 2. Define the relational data model 3. Create a relational database and queries to the database (SQL) Teaching activity Class 1 attendance Knowledge 2 test (preliminary exam) Final exam 2 Learnin g outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 4. Explain the role and benefits of new technology in the database application 1-6 1-6 1-6 Points Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list Written preliminary exam 0 10 0 40 Repetition of teaching materials Oral exam (and written exam) 0 50 min max Total 5 according to the agreement Specific knowledge for the systemic analysis of business structure, events and processes in the function of database modeling. In addition to the theory related to the database, the student should be familiar with methods of conceptual logical and physical modeling principles. Within the course, the student should acquire skills required for practical use of the database management system. Content (Course Abstraction in programming, design and data modeling, models and process curriculum) modeling, business processes, relational data model, relational language SQL, hierarchical and network model, the physical implementation of the data model, implementation of relational operations, integrity and security of the database, database use: multimedia database, mobile database, data warehouse, data marts. Trends in the development of databases. Consultations Gained competencies 76 Recommended reading 1. Tkalac, S.: Relacijski model podataka, DRIP, Zagreb 1993. 2. Dukić, B.: Baze podataka i poslovni procesi – nastavni materijali, Ekonomski fakultet u Osijeku, Osijek 2010. 3. Dukić, B.: Baze podataka i poslovni procesi – praktikum uz nastavne materijele, Ekonomski fakultet u Oisjkeu, Osijek 2013. 4. Varga, M.: Upravljanje podacima, Element, Zagreb 2012. 5. Manger, R.: Baze podataka, Element, Zagreb 2012. Additional reading 1. Mesarić, J., Zekić-Sušac, M., Dukić, B.: Alati uredskog poslovanja, Ekonomski fakultet u Osijeku, Osijek 2010. 2. Varga M.: Baze podataka – konceptualno, logičko i fizičko modeliranje podataka, DRIP, Zagreb 1994 3. Strahonja, V., Varga, M., Pavlić, M.: Projektiranje informacijskih sustava, Zavod za informatičku djelatnost Hrvatske i INA-INFO, Zagreb 1992. 4. 5. Instructional methods Exam formats Language Quality control and successfulness follow up Shepherd, C.J.: Database Management: Theory and Application, Boston: IRWIN, 1990. http://www.mysql.com Lectures, laboratory exercises Written and oral examination with colloquia Croatian, English The quality and success of the course can be monitored through the systems of knowledge testing, through making their own practical works in accordance with the given tasks, and the ability of students to use accepted knowledge and skills that acquired in this course and other courses. 77 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Usage of computers in lectures I109 30+0+0+30 Elementary 3. 5. Semester 5 doc.dr.sc. Denis Stanić; mr. sc. Slavko Petrinšak Develop students' skills and competencies for the application of information and communication technologies in the educational process. None After successfully completed course, student will be able to: Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS • Properly use the Internet as a source of information in the preparation of the teaching process • Describe the duties and tasks of teachers of informatics in teaching and administration aspects (E-nut, VETIS, E-book) • Develop appropriate multimedia elements for classes (drawing, photography, sound, video animation, interactive animation) • Plan educational materials using the hybrid or mixed classes (combination of classical teaching in the classroom and teaching with the help of technology, LMS) • Define the objective type tasks for e-assessment Class attendance Laboratory exercises 0,5 1-6 1,5 1-6 Homework 1 1-6 Seminar presentation, discussion. 1-6 Preparation for written examination 1-6 Repetition of teaching materials Teaching activity Knowledge 0,5 test (preliminary exam) Final exam 1,5 Consultations Gained competencies Students activity Class attendance The research on a given topic and creation of work materials. Methods of evaluation Evidence list The relevance of the data collected and the accompanying media. Rating writing seminars (up 5 points) and verbal rating exposure (up to 5 points) Evaluation (professor, students) and self-evaluation Oral exam and written exam Points min max 0 10 30 20 0 10 0 30 Total 5 0 100 Ph.D. Denis Stanic: Wednesday, 10-12 h mr. Sc. Slavko Petrinšak: Monday, 10-12 h Information and communication competence. Independently solving given problems. Collaborative work and respect of other people's opinions addressing the terms of 78 Content (Course curriculum) Recommended reading reference. The application of ICT in the development of educational materials. Communication skills (written and spoken) - Introduction to the course - Educational technology and areas of application of computers in the classroom - New sources of information - the Internet - The application of multimedia elements in educational facilities - The concept of educational software - Methodology of designing educational software - Assessment on the Internet - Interactive Learning - The definition of e-learning and system for e-learning - Standards for systems architecture design for e-learning - Web-oriented intelligent tutoring systems - E-assessment • • • Additional reading • • Textbooks for primary schools, secondary vocational and secondary school (2014) S. Stankov: Suvremena informacijska tehnologija u nastavi, Fakultet prirodoslovno matematičkih znanosti i odgojnih područja Sveučilišta u Splitu, (Materijal priređen za: Poslijediplomski znanstveni studij iz Didaktike prirodnih znanosti usmjerenja: kemija, biologija, fizika), Split, siječanj, 2005. Thomas A. Powell Web dizajn: kompletan priručnik, Mikro knjiga, 2001. Grundler, Gvozdanović, Ikica, Kos, Milijaš, Srnec, Širanović, Zvonarek., ECDL 5.0 (Windows 7, MS Office 2010) The curricula for primary and secondary schools Internet sources • • • http://pak.hr/cke/ostalo%204/Loomen%20upute%20v3.pdf http://www.carnet.hr/referalni/obrazovni.html http://www.carnet.hr/ictedu/edukativni_sadrzaji Instructional methods Planned classes that are achieved through lectures and exercises. Each lecture is followed by performing exercises where students develop the necessary skills and competencies. Each exercise is completed independently or within a team as part of the homework. Homework covers the entire course material. Display and evaluation of achievement of students’ tasks is performed through a variety of activities: oral presentation, discussion and presentation. Exam formats Each student is assigned a final seminar that must be completed by the specified date and presented in a 10-minute lecture. Completing the final seminar and 80% of practicum tasks is a condition for the course signature. An element of the course grade is students’ activity during class. As part of the course, each student will create their own personal web page of the course. The website will publish resolved tasks. This will be a way to monitor and evaluate activity during the semester. Final seminar that is assessed with grade 3 or higher is automatically transferred to adequate course grade, no additional exam needed. If the student is not satisfied with the grade, he or she may take the written and oral exam. If the student has not met the established criteria he or she must take the written 79 and oral exam together with submitted assignments. Language Croatian/English Quality control and successfulness follow up An anonymous survey held after each teaching theme (teacher reflection on amendments to certain segments continue to improve the quality of direct work with students). Unique University student survey where students assess their satisfaction with the quality of teachers and teaching assistants in each course, and course performance in general (the survey is a good starting point for self- evaluation of teachers and teaching assistants throughout the academic year). 80 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: E-learning systems I124 Elective course Elementary 3rd Semester 6th 4 Darko Dukić, Ph.D., Associate Professor, D. Matotek, dipl. Oec. The aim of the course is to provide students with in-depth insight into the field of elearning and e-learning systems. The practical part of the course (exercise) is based on the Moodle software platform, one of the leading learning management systems. None After successfully completed course, student will be able to: 1. Explain the basic concepts in the field of e-learning and to understand its development. 2. Classify e-learning. 3. Identify advantages and disadvantages of e-learning in the context of distance education. 4. Consider the various services provided by the e-learning system. 5. Evaluate e-learning systems with respect to the needs of potential users. 6. Participate in the e-learning design process. 7. Take an active role in the e-learning management. Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS 8. Administer and use the learning management system Moodle. Class attendance Knowledge test: preliminary exams or written/oral exam Seminar paper 1,5 1-8 1,8 1-8 0,4 1-5 Homework 0,3 6-8 Teaching activity Points Students activity Methods of evaluation Class attendance Preparation for preliminary exams or written/oral exam Evidence list 0 5 Preliminary exams grade or written/oral exam grade 0 50 Preparation and presentation of a seminar paper Doing homework related to the use of the learning management system Seminar paper grade 0 25 Evaluation of homework 0 20 min max 81 Total Consultations Gained competencies Content (Course curriculum) Recommended reading 4 0 100 Darko Dukić, Ph.D., Associate Professor: Monday, 17-19. After successfully completing the course the student will be able to evaluate various elearning systems and to use information and communication technologies in all stages of the educational process. Specific competencies are related to the use, design and administration of the learning management system Moodle. Introductory considerations. Defining the basic concepts. Historical overview of teaching technologies and e-learning development. Classification of e-learning. Advantages and disadvantages of e-learning in the context of distance education. Elearning environment. Services provided by the e-learning system. E-learning and Web 2.0. A conceptual model of e-learning system. E-learning system configuration and elearning facilities. Evaluation of e-learning system. Learning management system Moodle. Installation and system administration. Management course. Editing course. Working with resources. Communication and collaboration tools. Tasks, assessment and examination. 1. Bosnić, I.: Moodle - Priručnik za seminar, Hrvatska udruga za otvorene sustave i Internet, 2006. 2. Naidu, S.: E-Learning - A Guidebook of Principles, Procedures and Practices, Second Revised Edition, CEMCA, New Delhi, 2006. 3. Stankov, S.: E-učenje, PMF, Split, 2009. 4. Predavanja: http://moodle.fizika.unios.hr/course/view.php?id=35 Additional reading 1. Cole, J., Foster, H.: Using Moodle (Teaching with the Popular Open Source Management System), Second Edition, O’Reilly Media, Inc., Cambridge, 2008. 2. Carliner, S., Shank, P. (eds.): The E-Learning Handbook: Past Promises, Present Challenges, Pfeiffer, San Francisco, 2008. 3. Horton, W., Horton, K.: E-Learning Tools and Technologies: A Consumer's Guide for Trainers, Teachers, Educators, and Instructional Designers, Wiley Publishing, Inc., Indianapolis, 2003. 4. Morrison, D.: E-learning Strategies: How to Get Implementation and Delivery Right First Time, John Wiley & Sons Ltd., Chichester, 2003. 5. Instructional methods Exam formats Language Quality control and successfulness follow up Stankov, S.: Inteligentni tutorski sustavi: teorija i primjena, PMF, Split, 2010. Lectures (15), seminars (15), laboratory exercises (30). Two exams during the semester or written/oral examination. Students who regularly attend classes and achieve more than 50% marks in their preliminary exams, seminar paper, and homework are exempt from the written/oral examination. Croatian/English. Students' survey. 82 Lecturer Course objective Karmen Knežević A.M.E.S. Students will learn the vocabulary in the field of teaching units and grammatical concepts that will actively and passively be used in mastering the literature and communication No After completing the course, students will be able to: 1. to use language skills (comprehension, listening, speaking and writing) 2. to use thinking skills, showings conclusions and presenting personal opinions in English as a foreign language 3. to use vocational termnology in speaking and writing (communication skills) 4. to understand verbal exposure and professional dialogue in English 5. to use the basis of English grammar and syntax in profession 6.to use dictionaries, glossaries and online tools 7. to monitor scientific literature in English Prerequisites Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Consultations Gained competencies Content (Course curriculum) Teaching activity Class attendance Knowledge test: preliminary exams or final writeten exam Final exam Learning outcome English 1 Z101 Seminars Advancesd course of lectures 1st Semester 1st 2 ECTS60 hours = 22.5 hours (lectures) + 22.5 hours (preparation of seminars) + 15hours (preparation for exams) ECTS Course title Code Status Level Year ECTS 0,5 1-7 1,5 1-5 0 0 Points Students activity Methods of evaluation Class attendance Preparation for preliminary exams or final written examination (repeating by ) Evidence list 0 30 Homeworki vocabulary and grammar excersizes, group work 0 70 Repetition of teaching materials Oral exam (and written exam) 0 0 min max Total 2 0 100 2hours a week Expanding vocabulary with an emphasis on specialized areas of physics, developing of passive skills and understanding of the translations (written texts), and presentation skills as well as potentially the most important skill in the field. The Course English I is devided into 7 Unists: 1.Physics in general, 2.Scope and aims,3.Brief history of phyisics,4.Galileo Galilei,5.Isaac Newton,6.The Birth of modern physics,7.Nikola Tesla),. Using grammatical structures which characterize the language of profession correctly. Enabling students for reading specialized books and for having conversation about general subjects connected with the profession. Grammar: Parts of speech. Word order. Tenses. Modals. Participles. Relative clauses. Passive voice. Conditional clauses. Irregular plural. Word building – prefixes, suffixes. Comparison of adjectives. Acronyms. Connectors and modifiers. Antonyms and synonyms 83 Recommended reading 1. 2. 3. 4. 5. 6. Lidija Kraljević, Karmen Knežević: English in physics (internal script) 2. R.Murphy, English Grammar in Use, CUP, Cambridge, 1995. Bujas,Ž: English-Croatian Dictionary,Nakladni Zavod Globus,Zagreb 2011. Bujas,Ž: Croatian –English Dictionary,Nakladni Zavod Globus,2011. Oxford Dictionary of Physics,Oxford,2009. Penguin Dictionary in Physics, Penguin Books,2009 Additional reading 1.Krauskopf K.B;Beiser,A.:The Physical Universe, McGraw Hill Higher Education,2006 Instructional methods Classes for this course are intended as seminars which are compulsory for all students. In teaching audio-visual teaching aids (computer programs are done with the use of LCD projector) and numerous professional journals and books are used. Students occasionally receive homework assignments, which may affect the final grade. For the assessment of vocabulary, grammar, translation skills and written expression 2 preliminary exams are planned. Students who have access to both exams and achieve a minimum 35 of 70 points are released from the obligation to take the final exam. Homework assignments (translations, grammatical tasks ...) are an essentialpart of the course and one of the prerequisites for obtaining signatures Exam formats he written final exam -All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination -The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) The written final exam -All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Language Quality control and successfulness follow up Oral examination -The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) English Conducting an anonymous survey among students 84 Lecturer Course objective Karmen Knežević A.M.E.S. Students will learn the vocabulary in the field of teaching units and grammatical concepts that will actively and passively be used in mastering the literature and communication No. After completing the course, students will be able to: 1. to use language skills (comprehension, listening, speaking and writing) 2. to use thinking skills, showings conclusions and presenting personal opinions in English as a foreign language 3. to use koristiti vocational termnology in speaking and writing (communication skills) 4. to understand verbal exposure and professional dialogue in English 5. to use the basis of English grammar and syntax in profession 6.to use dictionaries, glossaries and online tools 7. to monitor scientific literature in English Prerequisites Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Consultations Gained competencies Content (Course curriculum) Teaching activity Class attendance Knowledge test preliminary exams or final written exam Final exam Learning outcome English 2 Z101 Seminars Advancesd course of lectures 1st Semester 2nd 2 ECTS60 hours = 22.5 hours (lectures) + 22.5 hours (preparation of seminars) + 15hours (preparation for exams) ECTS Course title Code Status Level Year ECTS 0,5 1-7 1,5 1-5 0 - Points Students activity Methods of evaluation Class attendance Preparation for preliminary exams or written examination Evidence list 0 30 Homework, vocabulary and grammar excersizes, group work 0 70 Repetition of teaching materials Oral exam (and written exam) 0 0 min max Total 2 100 2hours a week Expanding vocabulary with an emphasis on specialized areas of physics, developing of passive skills and understanding of the translations (written texts), and presentation skills as well as potentially the most important skill in the field. The Course English II is devided into (Albert Einstein, Stephan Hawking, Terms you should know, The five most important concepts in physics, The History of antimatter, The history of antimatter (1928-1959),The history of antimatter (19651995),The most interesting physical theories), using grammatical structures which characterize the language of profession correctly. Enabling students for reading specialized books and for having conversation about general subjects connected with the profession. Grammar: Parts of speech. Word order. Tenses. Modals. Participles. Relative clauses. Passive voice. Conditional clauses. Irregular plural. Word building – prefixes, suffixes. Comparison of adjectives. Acronyms. Connectors and modifiers. Antonyms and 85 synonyms Recommended reading 1. 2. 3. 4. 5. 6. Lidija Kraljević: English in physics (internal script) 2. R.Murphy, English Grammar in Use, CUP, Cambridge, 1995. Bujas,Ž: English-Croatian Dictionary,Nakladni Zavod Globus,Zagreb 2011. Bujas,Ž: Croatian –English Dictionary,Nakladni Zavod Globus,2011. Oxford Dictionary of Physics,Oxford,2009. Penguin Dictionary in Physics, Penguin Books,2009 Additional reading 1.Krauskopf K.B;Beiser,A.:The Physical Universe, McGraw Hill Higher Education,2006 Instructional methods Classes for this course are intended as seminars which are compulsory for all students. In teaching audio-visual teaching aids (computer programs are done with the use of LCD projector) and numerous professional journals and books are used. Students occasionally receive homework assignments, which may affect the final grade. For the assessment of vocabulary, grammar, translation skills and written expression 2 preliminary exams are planned. Students who have access to both exams and achieve a minimum 35 of 70 points are released from the obligation to take the final exam. Homework assignments (translations, grammatical tasks ...) are an essentialpart of the course and one of the prerequisites for obtaining signatures Exam formats The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Language Quality control and successfulness follow up Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) English Conducting an anonymous survey among students 86 Lecturer Course objective Karmen Knežević A.M.E.S. Students will learn the vocabulary in the field of teaching units and grammatical concepts that will actively and passively be used in mastering the literature and communication No After completing the course, students will be able to: 1. to use language skills (comprehension, listening, speaking and writing) 2. to use thinking skills, showings conclusions and presenting personal opinions in English as a foreign language 3. to use koristiti vocational termnology in speaking and writing (communication skills) 4. to understand verbal exposure and professional dialogue in English 5. to use the basis of English grammar and syntax in profession 6.to use dictionaries, glossaries and online tools 7. to monitor scientific literature in English Prerequisites Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Teaching activity Class attendance Knowledge test preliminary exams or final exam Final exam Consultations Gained competencies Content (Course curriculum) Learning outcome English 3 Z101 Seminars Advancesd course of lectures 2nd Semester 3rd 2 ECTS60 hours = 22.5 hours (lectures) + 22.5 hours (preparation of seminars) + 15hours (preparation for exams) ECTS Course title Code Status Level Year ECTS 0,5 1-7 1,5 1-5 Points Students activity Methods of evaluation Class attendance Preparation for written examination by repeating Evidence list 0 30 Homework, vocabulary and grammar excersizes, group work Oral exam (and written exam) 0 70 0 0 Repetition of teaching materials min max Total 2 100 2hours a week Expanding vocabulary with an emphasis on specialized areas of physics, developing of passive skills and understanding of the translations (written texts), and presentation skills as well as potentially the most important skill in the field. The Course English III is devided into (,Atomic theory of matter,Temperature and thermometers,Vibrations and waves,Four dimesnional space-time,Big Bang Theory, How does a satellite stay in orbit, How do things float?,Time travel ) using grammatical structures which characterize the language of profession correctly. Enabling students for reading specialized books and for having conversation about general subjects connected with the profession. Grammar: Parts of speech. Word order. Tenses. Modals. Participles. Relative clauses. Passive voice. Conditional clauses. Irregular plural. Word building – prefixes, suffixes. Comparison of adjectives. Acronyms. Connectors and modifiers. Antonyms and synonyms 87 Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up 1. 2. 3. 4. 5. Lidija Kraljević: English in physics (internal script) R.Murphy, English Grammar in Use, CUP, Cambridge, 1995. Bujas,Ž: English-Croatian Dictionary,Nakladni Zavod Globus,Zagreb 2011. Bujas,Ž: Croatian –English Dictionary,Nakladni Zavod Globus,2011. Oxford Dictionary of Physics,Oxford,2009. 6.Penguin Dictionary in Physics, Penguin Books,2009 1.Krauskopf K.B;Beiser,A.:The Physical Universe, McGraw Hill Higher Education,2006 Classes for this course are intended as seminars which are compulsory for all students. In teaching audio-visual teaching aids (computer programs are done with the use of LCD projector) and numerous professional journals and books are used. Students occasionally receive homework assignments, which may affect the final grade. For the assessment of vocabulary, grammar, translation skills and written expression 2 preliminary exams are planned. Students who have access to both exams and achieve a minimum 35 of 70 points are released from the obligation to take the final exam. Homework assignments (translations, grammatical tasks ...) are an essentialpart of the course and one of the prerequisites for obtaining signatures The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) English Conducting an anonymous survey among students 88 Lecturer Course objective Karmen Knežević A.M.E.S. Students will learn the vocabulary in the field of teaching units and grammatical concepts that will actively and passively be used in mastering the literature and communication No. After completing the course, students will be able to: 1. to use language skills (comprehension, listening, speaking and writing) 2. to use thinking skills, showings conclusions and presenting personal opinions in English as a foreign language 3. to use koristiti vocational termnology in speaking and writing (communication skills) 4. to understand verbal exposure and professional dialogue in English 5. to use the basis of English grammar and syntax in profession 6.to use dictionaries, glossaries and online tools 7. to monitor scientific literature in English Prerequisites Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Consultations Gained competencies Content (Course curriculum) Teaching activity Learning outcome English 4 Z101 Seminars Advancesd course of lectures 2nd Semester 4th 2 ECTS 60 hours = 22.5 hours (lectures) + 22.5 hours (preparation of seminars) + 15hours (preparation for exams) ECTS Course title Code Status Level Year ECTS Class 0,5 attendance Knowledge 1,5 test (preliminary exam or final written exam 1-7 Final exam 0 0 1-5 Points Students activity Methods of evaluation Class attendance Preparation for preliminary exams or final Evidence list 0 30 Homeworki, vocabulary and grammar excersizes, group work, seminar paper Oral exam (and written exam) 0 70 0 0 Repetition of teaching materials min max Total 2 100 2hours a week Expanding vocabulary with an emphasis on specialized areas of physics, developing of passive skills and understanding of the translations (written texts), and presentation skills as well as potentially the most important skill in the field. The Course EnglishIV is devided into 9 Unists (Teleportation, Quantum mechanics of atom, The beginning of time I, The beginning of time II, The beginning of time III,A brief history of string theory, How old is universe?, Gravitational collapse, Looking for extra dimensions), ,using grammatical structures which characterize the language of profession correctly. Enabling students for reading specialized books and for having conversation about general subjects connected with the profession. Grammar: Parts of speech. Word order. Tenses. Modals. Participles. Relative clauses. Passive voice. Conditional clauses. Irregular plural. Word building – prefixes, suffixes. Comparison of adjectives. Acronyms. Connectors and modifiers. Antonyms and 89 synonyms Recommended reading Additional reading Instructional methods Exam formats 1. 2. 3. 4. 5. Lidija Kraljević: English in physics (internal script) 2. R.Murphy, English Grammar in Use, CUP, Cambridge, 1995. Bujas,Ž: English-Croatian Dictionary,Nakladni Zavod Globus,Zagreb 2011. Bujas,Ž: Croatian –English Dictionary,Nakladni Zavod Globus,2011. Oxford Dictionary of Physics,Oxford,2009. 6.Penguin Dictionary in Physics, Penguin Books,2009 1.Krauskopf K.B;Beiser,A.:The Physical Universe, McGraw Hill Higher Education,2006 Classes for this course are intended as seminars which are compulsory for all students. In teaching audio-visual teaching aids (computer programs are done with the use of LCD projector) and numerous professional journals and books are used. Students occasionally receive homework assignments, which may affect the final grade. For the assessment of vocabulary, grammar, translation skills and written expression 2 preliminary exams are planned. Students who have access to both exams and achieve a minimum 35 of 70 points are released from the obligation to take the final exam. Homework assignments (translations, grammatical tasks ...) are an essentialpart of the course and one of the prerequisites for obtaining signatures.Students have to make a presentation according to their own chosen theme (physicsc) The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Language Quality control and successfulness follow up Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) English Conducting an anonymous survey among students 90 Lecturer Course objective Karmen Knežević A.M.E.S. Students will learn the vocabulary in the field of teaching units and grammatical concepts that will actively and passively be used in mastering the literature and communication No After completing the course, students will be able to: 1. to use language skills (comprehension, listening, speaking and writing) 2. to use thinking skills, showings conclusions and presenting personal opinions in English as a foreign language 3. to use koristiti vocational termnology in speaking and writing (communication skills) 4. to understand verbal exposure and professional dialogue in English 5. to use the basis of English grammar and syntax in profession 6.to use dictionaries, glossaries and online tools 7. to monitor scientific literature in English Prerequisites Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Consultations Gained competencies Content (Course curriculum) Learning outcome German 1 Z101 Seminars Advancesd course of lectures 1st Semester 1st 2 ECTS60 hours = 22.5 hours (lectures) + 22.5 hours (preparation of seminars) + 15hours (preparation for exams) ECTS Course title Code Status Level Year ECTS Class attendance Knowledge test: preliminary exams or final written exasm 0,5 1-7 1,5 1-5 Final exam 0 0 Teaching activity Students activity Methods of evaluation Class attendance Preparation for prelininary exams or final written examination by repetition of reaching materials Repetition of teaching materials Evidence list Points min max 0 30 0 Homework, vocabulary and grammar excersizes, group work 70 Oral exam (and written exam) 0 0 Total 100 2hours a week Expanding vocabulary with an emphasis on specialized areas of physics, developing of passive skills and understanding of the translations (written texts), and presentation skills as well as potentially the most important skill in the field. The Course German I is devided into 5 Unists: (Zahlen, Klammern,Brueche, Potenzieren, Radizieren), using grammatical structures which characterize the language of profession correctly. Enabling students for reading specialized books and for having conversation about general subjects connected with the profession. Grammar: Parts of speech. Word order. Tenses. Modals. Participles. Relative clauses. Passive voice. Conditional clauses. Irregular plural. Word building – prefixes, suffixes. Comparison of adjectives. Acronyms. Connectors and modifiers. Antonyms and synonyms 91 Recommended reading Knežević, K.,Kraljević,L.:Deutsch in der Physik (interna skripta) Additional reading Hoche, D., Küblbeck, J., Meyer, L., Reichwald, R., Schmidt, G., Schwarz, O.,Spitz, Ch. (2011). Duden:Bassiswissen Schule, Physik,Berlin,Duden Schulbuchverlag. Bronstein, I., Semendjajev, K., Musoil, G., Mühlig, H., (2010).Taschenbuch der Mathematik, Berlin,Harri Deutsch. http://www.leifiphysik.de/ Instructional methods Classes for this course are intended as seminars which are compulsory for all students. In teaching audio-visual teaching aids (computer programs are done with the use of LCD projector) and numerous professional journals and books are used. Students occasionally receive homework assignments, which may affect the final grade. For the assessment of vocabulary, grammar, translation skills and written expression 2 preliminary exams are planned. Students who have access to both exams and achieve a minimum 35 of 70 points are released from the obligation to take the final exam. Homework assignments (translations, grammatical tasks ...) are an essentialpart of the course and one of the prerequisites for obtaining signatures The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam). The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) German Conducting an anonymous survey among students Exam formats Language Quality control and successfulness follow up 92 Lecturer Course objective Karmen Knežević A.M.E.S. Students will learn the vocabulary in the field of teaching units and grammatical concepts that will actively and passively be used in mastering the literature and communication No After completing the course, students will be able to: 1. to use language skills (comprehension, listening, speaking and writing) 2. to use thinking skills, showings conclusions and presenting personal opinions in English as a foreign language 3. to use koristiti vocational termnology in speaking and writing (communication skills) 4. to understand verbal exposure and professional dialogue in English 5. to use the basis of English grammar and syntax in profession 6.to use dictionaries, glossaries and online tools 7. to monitor scientific literature in English Prerequisites Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Consultations Gained competencies Content (Course curriculum) Learning outcome German 2 Z102 Seminars Advancesd course of lectures 1st Semester 2nd 2 ECTS60 hours = 22.5 hours (lectures) + 22.5 hours (preparation of seminars) + 15hours (preparation for exams) ECTS Course title Code Status Level Year ECTS Class attendance Knowledge test:preliminary exam or final written exam 0,5 1-7 1,5 1-5 Final exam 0 0 Teaching activity Students activity Methods of evaluation Class attendance Preparation for preliminary exams or written examination by repetition of teaching materials Repetition of teaching materials Points min max Evidence list 0 30 Homework, vocabulary and grammar excersizes, group work 0 70 Oral exam (and written exam) 0 0 Total 2 100 2hours a week Expanding vocabulary with an emphasis on specialized areas of physics, developing of passive skills and understanding of the translations (written texts), and presentation skills as well as potentially the most important skill in the field. The Course German I is devided into 4 Units (Physik generell, Ziele und Methoden in der Physik, Klassische Physik, Moderne Physik),using grammatical structures which characterize the language of profession correctly. Enabling students for reading specialized books and for having conversation about general subjects connected with the profession. Grammar: Parts of speech. Word order. Tenses. Modals. Participles. Relative clauses. Passive voice. Conditional clauses. Irregular plural. Word building – prefixes, suffixes. Comparison of adjectives. Acronyms. Connectors and modifiers. Antonyms and synonyms 93 Recommended reading Knežević, K.,Kraljević,L:Deutsch in der Physik (interna skripta) Additional reading Hoche, D., Küblbeck, J., Meyer, L., Reichwald, R., Schmidt, G., Schwarz, O.,Spitz, Ch. (2011). Duden:Bassiswissen Schule, Physik,Berlin,Duden Schulbuchverlag. Bronstein, I., Semendjajev, K., Musoil, G., Mühlig, H., (2010).Taschenbuch der Mathematik, Berlin,Harri Deutsch. http://www.leifiphysik.de/ Instructional methods Classes for this course are intended as seminars which are compulsory for all students. In teaching audio-visual teaching aids (computer programs are done with the use of LCD projector) and numerous professional journals and books are used. Students occasionally receive homework assignments, which may affect the final grade. For the assessment of vocabulary, grammar, translation skills and written expression 2 preliminary exams are planned. Students who have access to both exams and achieve a minimum 35 of 70 points are released from the obligation to take the final exam. Homework assignments (translations, grammatical tasks ...) are an essentialpart of the course and one of the prerequisites for obtaining signatures. The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) German Conducting an anonymous survey among students Exam formats Language Quality control and successfulness follow up 94 Lecturer Course objective Karmen Knežević A.M.E.S. Students will learn the vocabulary in the field of teaching units and grammatical concepts that will actively and passively be used in mastering the literature and communication No After completing the course, students will be able to: 1. to use language skills (comprehension, listening, speaking and writing) 2. to use thinking skills, showings conclusions and presenting personal opinions in English as a foreign language 3. to use koristiti vocational termnology in speaking and writing (communication skills) 4. to understand verbal exposure and professional dialogue in English 5. to use the basis of English grammar and syntax in profession 6.to use dictionaries, glossaries and online tools 7. to monitor scientific literature in English Prerequisites Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Consultations Gained competencies Content (Course curriculum) Learning outcome German 3 Z103 Seminars Advancesd course of lectures 2nd Semester 3rd 2 ECTS60 hours = 22.5 hours (lectures) + 22.5 hours (preparation of seminars) + 15hours (preparation for exams) ECTS Course title Code Status Level Year ECTS Class attendance Knowledge test preliminary exam or final written exam 0,5 1-7 1,5 1-5 Final exam 0 0 Teaching activity Points Students activity Methods of evaluation Class attendance Preparation for preliminary exams or written examination by repetition of reaching materials Repetition of teaching materials Evidence list 0 30 Homework, vocabulary and grammar excersizes, group work 0 70 Oral exam (and written exam) 0 0 min max Total 2 100 2hours a week Expanding vocabulary with an emphasis on specialized areas of physics, developing of passive skills and understanding of the translations (written texts), and presentation skills as well as potentially the most important skill in the field. The Course German III is devided into 4 Units (Weltferaenderer :Galileo Galilei, Sir Isaac Newton, Nikola Tesla_Ein vergessenes Genie, Albert Einstein), using grammatical structures which characterize the language of profession correctly. Enabling students for reading specialized books and for having conversation about general subjects connected with the profession. Grammar: Parts of speech. Word order. Tenses. Modals. Participles. Relative clauses. Passive voice. Conditional clauses. Irregular plural. Word building – prefixes, suffixes. Comparison of adjectives. Acronyms. Connectors and modifiers. Antonyms and synonyms 95 Recommended reading Knežević, K.,Kraljević,L.:Deutsch in der Physik (interna skripta) Additional reading Hoche, D., Küblbeck, J., Meyer, L., Reichwald, R., Schmidt, G., Schwarz, O.,Spitz, Ch. (2011). Duden:Bassiswissen Schule, Physik,Berlin,Duden Schulbuchverlag. Bronstein, I., Semendjajev, K., Musoil, G., Mühlig, H., (2010).Taschenbuch der Mathematik, Berlin,Harri Deutsch. http://www.leifiphysik.de/ Instructional methods Classes for this course are intended as seminars which are compulsory for all students. In teaching audio-visual teaching aids (computer programs are done with the use of LCD projector) and numerous professional journals and books are used. Students occasionally receive homework assignments, which may affect the final grade. For the assessment of vocabulary, grammar, translation skills and written expression 2 preliminary exams are planned. Students who have access to both exams and achieve a minimum 35 of 70 points are released from the obligation to take the final exam. Homework assignments (translations, grammatical tasks ...) are an essentialpart of the course and one of the prerequisites for obtaining signatures Exam formats The written final exam -All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination -The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) The written final exam -All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Language Quality control and successfulness follow up Oral examination -The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) German Conducting an anonymous survey among students 96 Course title Code Status Level Year ECTS German 4 Z104 Seminars Advancesd course of lectures 2nd Semester 4th 2 ECTS60 hours = 22.5 hours (lectures) + 22.5 hours (preparation of seminars) + 15hours (preparation for exams) Lecturer Course objective Karmen Knežević A.M.E.S. Students will learn the vocabulary in the field of teaching units and grammatical concepts that will actively and passively be used in mastering the literature and communication No After completing the course, students will be able to: 1. to use language skills (comprehension, listening, speaking and writing) 2. to use thinking skills, showings conclusions and presenting personal opinions in English as a foreign language 3. to use koristiti vocational termnology in speaking and writing (communication skills) 4. to understand verbal exposure and professional dialogue in English 5. to use the basis of English grammar and syntax in profession 6.to use dictionaries, glossaries and online tools 7. to monitor scientific literature in English Consultations Gained competencies Content (Course curriculum) Recommended reading Additional reading Points Learning outcome Correlation of learning outcomes, teaching methods and evaluation ECTS Prerequisites Learning outcomes: Students activity Class attendance Knowledge test preliminary exams or final written exam 0,5 1-7 Class attendance Evidence list 0 30 1,5 1-5 Written preliminary exam 0 70 Final exam 0 0 Preparation for preliminary exams or final written examination by repetition fo teaching materials Repetition of teaching materials Oral exam (and written exam) o o Teaching activity Methods of evaluation min max Total 2 100 2hours a week Expanding vocabulary with an emphasis on specialized areas of physics, developing of passive skills and understanding of the translations (written texts), and presentation skills as well as potentially the most important skill in the field. The Course German 4 is devided into 4 Units ( Physik der Atomhuelle, Physik des Atomkerns, Wie alt ist das Universum, Garavitations – Kollaps) which characterize the language of profession correctly.,emabling students for reading specialized books and for having conversation about general subjects connected with the profession. Grammar: Parts of speech. Word order. Tenses. Modals. Participles. Relative clauses. Passive voice. Conditional clauses. Irregular plural. Word building – prefixes, suffixes. Comparison of adjectives. Acronyms. Connectors and modifiers. Antonyms and synonyms Knežević, K.,Kraljević,L.:Deutsch in der Physik (interna skripta) Hoche, D., Küblbeck, J., Meyer, L., Reichwald, R., Schmidt, G., Schwarz, O.,Spitz, Ch. (2011). Duden:Bassiswissen Schule, Physik,Berlin,Duden Schulbuchverlag. Bronstein, I., Semendjajev, K., Musoil, G., Mühlig, H., (2010).Taschenbuch der Mathematik, Berlin,Harri Deutsch. http://www.leifiphysik.de/ 97 Instructional methods Exam formats Classes for this course are intended as seminars which are compulsory for all students. In teaching audio-visual teaching aids (computer programs are done with the use of LCD projector) and numerous professional journals and books are used. Students occasionally receive homework assignments, which may affect the final grade. For the assessment of vocabulary, grammar, translation skills and written expression 2 preliminary exams are planned. Students who have access to both exams and achieve a minimum 35 of 70 points are released from the obligation to take the final exam. Homework assignments (translations, grammatical tasks ...) are an essentialpart of the course and one of the prerequisites for obtaining signatures Students have to make a seminar (presentation) according to their own chosen theme in physics. The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) The written final exam All students who have not realized enough points in the preliminary exams or those who want to gain a higher rating than what they realized in preliminary exams have to take the final exam. The student has passed successfully the written examination if it is resolved with at least 50% of tasks. Language Quality control and successfulness follow up Oral examination The oral exam is required only to students who want to achieve an excellent score (5) or very good (4). At the oral exam the active knowledge of general and technical vocabulary, pronunciation and grammar is being verified, and the final score depends on the points awarded for the preliminary exam (or final written exam) German Conducting an anonymous survey among students 98 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: General and inorganic chemistry 1 Z105 Elective Middle advantage First Semester First 5 Goran Šmit Ph.D., Assistant Professor Preparation of students for studies of natural and technical sciences which are based on knowledge given by general and inorganic chemistry. None After successfully completed course, students will be able to: 1. Connect unit for amount of substance (mole) with other quantity values which describe its state (mass, volume, pressure), 2. Define chemical formula of chemical compound on basis of results provided by chemical analysis, 3. Understand the meaning of chemical equation and its application in different calculations, 4. Apply gas laws in chemical reactions, 5. Calculate needed values for preparation of solutions by solving of solids and dilution of solutions, 6. Use physical properties of solutions in calculations associated with colligative properties (osmosis, elevation of boiling point, depression of freezing point). Consultations Gained competencies Content (Course curriculum) Recommended reading Learning outcome Points ECTS Correlation of learning outcomes, teaching methods and evaluation Knowledge test (preliminar y exam) Final exam 3 1.–6. Preparation for written examination Written preliminary exam 40 70 2 1.–6. Repetition of teaching materials Oral exam (and written exam) 21 30 Total 5 61 100 Teaching activity Students activity Methods of evaluation min max Understanding of connection between physical properties of substances and their chemical changes. Theoretical basis needed for work in chemical laboratory. Introduction in chemistry. Substances (chemical elements, chemical compounds and mixtures). Relative atomic and molecular mass. Structure of atoms. Chemical bond and structure of molecules. Solutions. Osmosis and osmotic pressure. Solutions of electrolytes. Degree of dissociation. Acids and bases. 1. I. Filipović, S. Lipanović, Opća i anorganska kemija, Školska knjiga, Zagreb, 1991., 2. M. Sikirica, Stehiometrija, Školska knjiga, Zagreb, 1991. 99 Additional reading Instructional methods Exam formats 1. M. Silberberg, Chemistry: The Molecular Nature of Matter and Change, WCB/Mcgraw-Hill, Boston, 1996. Lectures with actively participation of students and auditory exercises with independently solving of numerical problems. First written preliminary exam at the middle of semester (learning outcomes 1.-3.): 5 numerical problems which are 35% of final grade, Second written preliminary exam at the end of semester (learning outcomes 4.-6.): 5 numerical problems which are 35% of final grade, Additional written preliminary exam at the end of semester (learning outcomes 1.-6.): 5 numerical problems which are 10% of final grade, Final oral exam (learning outcomes 1.-6.): 10 theoretical questions which are 30% of final grade and threshold is 70%. Final grade: D (2) for realized 61-70% of final grade, C (3) for realized 71-80% of final grade, B (4) for realized 81-90% of final grade, A (5) for realized 91-100% of final grade. Language Quality control and successfulness follow up Croatian (English) Anonymous student opinion poll and discussions with students after passing of exam. 100 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: General and inorganic chemistry 2 Z106 Elective Middle advantage First Semester First 6 Goran Šmit Ph.D., Assistant Professor Preparation of students for studies of natural and technical sciences which are based on knowledge given by general and inorganic chemistry. None After successfully completed course, students will be able to: 1. Solve equations of oxidation and reduction, 2. Use constant of chemical equilibrium for conducting chemical reactions in wanted direction (increasing or diminishing yield of products), 3. Apply solubility product constant and dissociation constant in calculation for preparing of solutions, 4. Use ionic product of water for preparation of solutions with defined pH, 5. Determine basic values in operation of galvanic and electrolytic cell, 6. Calculate theoretical values of energetic changes during chemical reactions. Consultations Gained competencies Content (Course curriculum) Recommended reading Learning outcome Points ECTS Correlation of learning outcomes, teaching methods and evaluation Knowledge test (preliminar y exam) Final exam 4 1.–6. Preparation for written examination Written preliminary exam 40 70 2 1.–6. Repetition of teaching materials Oral exam (and written exam) 21 30 Total 6 61 100 Teaching activity Students activity Methods of evaluation min max Understanding of chemical reactions of some chemical elements and their compounds. Theoretical basis needed for conducting chemical experiments. Chemical reactions. Oxidation and reduction. Hydrolysis. Chemical equilibrium. Solubility product constant and dissociation constant. Ionic product of water (pH). Galvanic cell. Electrolysis. Energetic changes in chemical reactions. Colloidal systems. Chemical elements and their compounds. 3. I. Filipović, S. Lipanović, Opća i anorganska kemija, Školska knjiga, Zagreb, 1991., 4. M. Sikirica, Stehiometrija, Školska knjiga, Zagreb, 1991. Additional reading Instructional methods 2. M. Silberberg, Chemistry: The Molecular Nature of Matter and Change, WCB/Mcgraw-Hill, Boston, 1996. Lectures with actively participation of students and auditory exercises with independently solving of numerical problems. 101 Exam formats First written preliminary exam at the middle of semester (learning outcomes 1.-3.): 5 numerical problems which are 35% of final grade, Second written preliminary exam at the end of semester (learning outcomes 4.-6.): 5 numerical problems which are 35% of final grade, Additional written preliminary exam at the end of semester (learning outcomes 1.-6.): 5 numerical problems which are 10% of final grade, Final oral exam (learning outcomes 1.-6.): 10 theoretical questions which are 30% of final grade and threshold is 70%. Final grade: D (2) for realized 61-70% of final grade, C (3) for realized 71-80% of final grade, B (4) for realized 81-90% of final grade, A (5) for realized 91-100% of final grade. Language Quality control and successfulness follow up Croatian (English) Anonymous student opinion poll and discussions with students after passing of exam. 102 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Physical education 1-4 Iy-Z113, 2y-Z114, 3y-Z115 and 4y-Z116 Exercises (two hours on week) Basic I. and II. Semester I. – IV. 1 ECTS in semester Josip Cvenić, higher lecturer Maintence of motor and functional abilities, and acquiring new motor and theoretical knowledge in the physical education field No prerequisites After successfully completed course, student will be able to: 1. know the difference between anaerobic and aerobic training 2. recognize the impact of each exercises on the muscle group 3. to prepare training and training load according to their possibilities 4. demonstrate the complex of warm-up exercises 5. apply the knowledge and principles of regular exercise in their leisure time; Consultations Gained competencies Content (Course curriculum) 7. arrange your own exercise program; 8. compare own results with the PE standards and other students Teaching activity Class 1 attendance Knowledge test (preliminary exam) Final exam Learning outcome calculate body mass index; ECTS Correlation of learning outcomes, teaching methods and evaluation 6. 1-8 Students activity Methods of evaluation Class attendance Preparation for written examination Evidence list Repetition of teaching materials Oral exam (and written exam) Points min 15 max 30 Written preliminary exam Total 1 15 30 Every Thursday 12.00 – 13.00 in office nr.27, Department of mathematics Understanding basic forms of physical exercise and application in daily life. Based on the initial condition to create a program with the adjusted kinesiology facilities. Adopt theoretical information about healthy lifestyles, proper nutrition, and the bad influence sedentary behavior. Acquire the habit of daily and regular physical exercise. Curriculum consists of a set of various kinesiology activities can be divided into basic and specialized curriculum. Students opting with regard to interest, the level of motor skills, level of ability, health status and material conditions on the university and the department. The basic program consists of kinesiology activities (fitness, aerobics, athletics, basketball, football, volleyball, dance structures, swimming, handball, table tennis, ..) while special programs consist of activities that have been less common in the curricula of primary and secondary schools (ice skating, beach volleyball, mountain hiking tours, tennis, karate, taekwondo, squash, bowling ...). 103 Recommended reading 1. Pearl, B., Moran G. T. (2009). Trening s utezima, Gopal d.o.o, Zagreb Additional reading 1. Caput – Jogunica, R., Bagarić I., Babić D., Ćurković S., Špehar N., Alikalfić V. Nastavni plan i program tjelesne i zdravstvene kulture u visokom obrazovanju (skripta). Zagreb, 2007. 2. Delija K., K. Pleša (2004). Vrednovanje u području edukacije. U V. Findak (ur.), 13. ljetna škola kineziologa Republike Hrvatske, Rovinj, 2004. (str. 22-28). Hrvatski kineziološki savez 3. Findak, V. (1999). Metodika tjelesne i zdravstvene kulture. Zagreb: Školska knjiga 4. Findak, V. (2004). Vrednovanje u području edukacije, sporta i sportske rekreacije. U V. Findak (ur.), 13. ljetna škola kineziologa Republike Hrvatske, Rovinj, 2004. (str. 12-20). Hrvatski kineziološki savez 5. Janković, V., N . Marelić (1995). Odbojka. Zagreb:Fakultet za fizičku kulturu Sveučilišta u Zagrebu. Milanović, D. (ur.)(1996). Fitnes. Zbornik radova međunarodnog znanstveno-stručnog savjetovanja of fitnesu, 5. zagrebački sajam sporta, Fakultet za fizičku kulturu, Zagreb 6. Jukić I., G. Marković (2005). Kondicijske vježbe s utezima. Zagreb: Kineziološki fakultet Sveučilišta u Zagrebu. 7. Mišigoj-Duraković, M. (2008). Kinantropologija. Zagreb: Kineziološki fakultet Sveučilišta u Zagrebu. 8. Volčanšek, B. (1996). Sportsko plivanje. (Udžbenik)Fakultet za fizičku kulturu, Zagreb. 9. Vukić, Ž., Jančić S., Vukić Ž. (1997). Model ustroja nastave tjelesne i zdravstvene kulture i športa na visokim učilištima (skripta). Osijek, Ekonomski fakultet Osijek. Instructional methods Exam formats Language Quality control and successfulness follow up Practical exercises on different sport indoor and outdoor areas. Regular attendance of classes (80%) Croatian (language of teaching). English and German (can be taught) Anonymous student survey 104 Course title Science of Strength Course code T106 Type of course Theoretical with exercises Level of course Intermediate level (for graduate study) Year of study 3rd Semester 5th 3 ECTS ECTS (Number of Teaching ≈ 1 ECTS credits allocated) Student studying ≈ 2 ECTS Name of lecturer Dr. Tomislav Mrčela, Professor Goal of course The goal of this course is that the student acquire general knowledge of the theory of strength of solids. Dealing special knowledge the student becomes acquainted with concepts which are the foundation for understanding the basic background in the specification of a technical product. Prerequisites No prerequisites Learning outcomes and competences After successfully completed course, student will be able to: 1. use a complex system of stress control of imaginary constructions and apply basic physical postulates of the theory of strength science, 2. use the tools that are available to solve complex structures, define their load and make the criteria for stability and reliability. 3. succeeding to solve the most complex tasks related to the life and exploitation of complex construction solutions. Outcom e Learnin g Teaching activity Students activity Points ECTS Correlation of learning outcomes, teaching methods and evaluation Methods of evaluation Attendin g class 1 1-3 Attending class Record keeping 0 100 Knowled ge test 1 1-3 Individual preparation Written exam 0 100 1 1-3 Individual Oral exam 0 100 min max (prelimin ary exam) Final 105 exam Total preparation 3. 0 1-3 Consultations By appointment Course contents Strain and deformations: Basic theory of interior forces and deformations, relations between Strain and deformations, Hooks act, Strain force, Strain in the leaning cutest( normal and tangential strain), Morhs circuits. Two axle and tree axle strain, security coefficient, Strain working range, Product Geometrical characteristic of diagonally cutest: surfaces moment of inertia and resistance, Normal strain: tension and pressure strain, bending, wrapping (Euler’s force, Tetmajer’s method and “W” procedures) Tangential strain: cut, twisting. Complex strain: tension and bending, bending and wrapping (hypotheses of maximum normal strain, hypotheses of maximum tangential strain and hypotheses of maximum deformation ); Recommended reading Alfirević, I. Nauka o čvrstoći, Tehnička knjiga, Zagreb Supplementary reading Tehnička enciklopedija Bazijanac, D. Nauka o čvrstoći Tehnička knjiga Zagreb Kraut, B. Strojarski priručnik, Tehnička knjiga, Zagreb Kruz. Tehnička mehanika, Školska knjiga, Zagreb Kruz. Nauka o čvrstoći, Školska knjiga, Zagreb Teaching methods Lectures (30), exercises (15) Assessment methods Course is successfully resolved trough two preliminary exams during presentations or in the end of presentation by written and oral exam. Language of instruction Croatian. Quality assurance methods At the beginning and at the end of the teaching process: questionnaires about learning outcomes and competences, and about the course. 106 Course title Code Status Level Year ECTS Lecturer Course objective Prerequisites Learning outcomes: Computational Physics F133 Undergraduate (obligated) Intermediate 3. Semester 6. 5 prof.dr.sc. Branko Vuković doc.dr.sc. Zvonko Glumac doc.dr.sc. Igor Lukačević Igor Miklavčić, lecturer Matko Mužević, assistant Students should be able to tackle with problems in the physical science using computer and different software as a numerical tool. Computer Laboratory, I116 After successfully completed course, student will be able to: 1. Apply Monte Carlo simulations. 2. Numerically solve systems of nonlinear equations. 3. Numerically calculate eigenvalues and eigenvectors of a matrix. 4. Numerically calculate multiple integrals. 5. Solve physical problems using modern computational software. 6. Visualize physical problems and their solutions on a computer. 7. Use PHYTON programming language. Consultations Gained competencies Content (Course curriculum) Class attendanc e Frontal lectures about problem Points Learning outcome Teaching activity ECTS Correlation of learning outcomes, teaching methods and evaluation 4 1-6 Class attendance Evidence list 0 100 1 5-7 - investigation about problem - writing code - making presentation on computer -oral presentation in front of peers Oral, after the presentation 0 20 Students activity Methods of evaluation min max Total 5 0 120 Z. Glumac; I. Lukačević; I. Miklavčić; M. Mužević: Friday, 12.00 – 14.00 Students will be able to use the computer and different software for simulation, numerical processing and graphical representation of solutions of simple physical problems. They will be able to handle large databases using a scripting language. 1. Stochastic Systems • Random walk in one dimension • Random walk in two dimensions 2. Monte Carlo simulation 107 Recommended reading Additional reading Instructional methods Exam formats Language Quality control and successfulness follow up • Metropolis algorithm • Ising model 3. Approximate solution of systems of nonlinear equations • One equation with one unknown - the real zeros • One equation with one unknown - the complex zeros • Two equations with two unknowns - the real zeros • Two equations with two unknowns - the complex zeros 4. Eigenvalues of the matrix • The largest eigenvalue and associated eigenvector • The smallest eigenvalue and associated eigenvector • The complex conjugate eigenvalues • The roots of the polynomial 5. Numerical Integration • Single integrals • Double integrals 6. Visualization of physical problems • 2D models • 3D models 8. Solving the physical problem • Basic mathematical operations • Using the calculus • Using the linear algebra 9. Visualization of problem solutions • Drawing graphs 10. AWK/shell scripting 11. Introduction in PHYTON programming language • Installation • IDLE, Python shell, basics of python programming, "loops" • Solving simple physical problem • Presentation Računalne metode fizike, uvod – Z. Glumac http://www.fizika.unios.hr/~zglumac/urmf.pdf http://www.sysprint.hr/infosapl/ 1. B. P. Demidovich and I. A. Maron:Computational Mathematics 2. Nicholas J. Giordano and Hisao Nakanishi: Computational Physics 3. J. Stoer and R. Bulirsch:Introduction to Numerical Analysis 4. http://reference.wolfram.com/mathematica/guide/Mathematica.html 5. http://www.gnuplot.info 6. http://www.gnu.org/software/gawk/manual/gawk.html 7. https://www.python.org/ 8. http://www-personal.umich.edu/~mejn/computationalphysics/ Lectures (15 hours) Seminars (45 hours) Each week a student receives a task that needs to be solved and that is evaluated. The final grade is the arithmetic average of the weekly ratings. Croatian or English (optional) Student survey. Permanent contact with students. 108 Prerequisites Learning outcomes: Correlation of learning outcomes, teaching methods and evaluation Learning outcome Course objective Computer practicum I116 Elective 3 Semester 5 5 Lectures (0), Seminars (45), Laboratory (15) Darko Dukić, PhD, Associate Professor; Slavko Petrinšak, MA, Lecturer; Miroslav Katić, BA, Lecturer. Students will acquire basic knowledge and competences for independently managing computer laboratories in schoosl using latest ICT solutions and modern programing languages. I101, I106, I107 After successfully completed course, student will be able to: • carry out an analysis of the current situation of equipment and functionality of computer labs • maintain the accuracy of the equipment and software support in the IT classroom • install and configure the parameters of the applications that are used in teaching • properly use and maintain the available information and communication technologies • solve tasks in given programming languages •prepare independently programming exercises for teaching in primary and secondary schools ECTS Course title Code Level Year ECTS Teaching model Lecturer Class attendance Laboratory exercises 0.5 1-6 1 1-6 Homework 1 1-6 Teaching activity Knowledge 1.5 test (preliminary exam) Final exam 1 Consultations Gained competencies Content (Course curriculum) 1-6 1-6 Points Students activity Methods of evaluation Class attendance Research, preparation Evidence list 10 Evaluation 20 Presentation, discussion, workshop presentation Presentation Written 20 Evaluation 30 Repetition of teaching materials Oral exam and written exam 20 min max Total 5 100 Darko Dukić, Wednesday 11-13h Slavko Petrinšak, Monday 10-12h Miroslav Katić.: Tuesday 10-12h Students gain basic knowledge and skills to perform educational process in ICT classroom at school using latest ICT solutions and modern programing languages. 1. How to prepare the work environment for teaching in primary and secondary schools 2. Basic maintenance of hardware and software in the ICT classroom 3. Computer hardware 4. Installation of operating systems (MS Windows, Linux) 5. ICT in education 6. Computer network 7. Pseudo code as meta language 109 Recommended reading Additional reading 8. Logo 9. Basic, C/C++, Pascal 10. Pyton, PHP 11. Visual Studio (VB, C#), Java 12. Small basic 13. Javascript • Recent books and workbooks for primary and secondary school • e- Library http://e-knjiznica.carnet.hr/e-knjige • Computer networks http://sistemac.carnet.hr/node/343 • CARNet: Referalni centri za e-obrazovanje http://www.carnet.hr/referalni/obrazovni/ • Bosnić, I.: Moodle - Priručnik za seminar, Hrvatska udruga za otvorene sustave i Internet, 2006. • Informatika i računalnstvo – udžbenik, V. Galešev, P.Brođanac, M. Korać, Lj. Miletić, S. Grabuzin, S. Babić, Z. Soldo, L. Kralj, G. Sokol, D. Kovač, SysPrint • Informatika i računalnstvo – zbirka zadataka, V. Galešev, P.Brođanac, M. Korać, Lj. Miletić, S. Grabuzin, S. Babić, Z. Soldo, L. Kralj, G. Sokol, SysPrint • L. Budin, Informatika za 1. razred gimnazije, Element, Zagreb 1996. • S. Stankov: Programiranje I., Fakultet prirodoslovno-matematičkih znanosti i odgojnih područja Sveučilišta u Splitu, listopad, 2003. • Programiranje Visual Studio, Jesse Liberty, O’ Reilly / Dobar Plan Zagreb • CARNet: Referalni centri za e-obrazovanje Instructional methods Exam formats Language Quality control and successfulness follow up Classes are held in a computer workshop. Teaching practicum will take place in two forms, seminars and laboratory exercises. In the exercises, students will independently solve the tasks assigned and predent them in form of seminars. At the beginning of the exercise, every student's knowledge necessary to perform the exercises will be verbally verified. Student is required to write a report on every completed exercise before a given deadline. Student is required to perform all the exercises in order to take the exam. Testing laboratory practice, written and oral examinations. Croatian/ English An anonymous survey held after each teaching theme (teacher reflection on amendments to certain segments continue to improve the quality of direct work with students). Unique University student survey in which students assess their satisfaction with the quality of teachers and teaching assistants in each course, and course performance in general (the survey is a good starting point for self- evaluation of teachers and teaching assistants throughout the academic year). 110 3.3. Terms and method of study The mode of study and student obligations are determined by the Regulation Book on the Study and Studying at the University of Osijek (http://www.unios.hr/uploads/50pravilnik-o- studiranju_2013-09-27.pdf).The proposed undergraduate programme is structured in semesters and lasts six semesters. All courses last one semester. Conditions for enrolling in the next academic year are in line with the mentioned Regulation Book. Conditions that relate to the enrollment of a subject (if any) are listed in the subject programme. 3.4. The list of courses and modules that students can enroll in other study programmes With the compulsory and elective courses of the proposed University Undergraduate Study of Physics (Table 3.1.), students can also enroll in a university elective course (list of university elective courses is published at the beginning of the academic year) with the consent and approval of the Lecturer and the Head Deputy for Education and Students, which has to be approved by the Council of the Department of Physics. 3.5. Courses and / or modules that can be taught in a foreign language We do not expect a large number of foreign students interested in attending classes. For a small number of possibly interested students we anticipate teaching through consultations for all courses, and in the case of greater interest classes in English for all courses will be organized 3.6. Criteria and transfer of CTS credits The assignment of credits for courses that students can choose from other university studies or other higher education institutions shall be determined according to the principles of programme integration or by the Decission of the Senate of the J. J.Strossmayer University of Osijek. 3.7. Completion of the study Students are required to take and pass all subjects (compulsory and elective selected), make all scheduled commitments (to write and hold seminars, regularly attend practicums, take quizzes, homework,...), pass all exams and thereby collect at least 175 ECTS credits. The student gets the final 5 ECTS credits (to a final sum of 180 ECTS credits) if his/her final paper is successfully evaluated (according to the procedure prescribed in the Regulation Book of the Final Paper at the Undergraduate Study of the Department of Physics) 111 3.8. Conditions under which students, who interrupted or lost the right to study, can continue studying Students who interrupted the study or lost the right to study in a program of study must submit an application which will be individually addressed by the Committee for Education and Students and has to be confirmed by the Council of the Department of Physics, in accordance with applicable legislation and regulations (the Regulation Book on Study and Learning at the University of Osijek, the Regulation Book of the Department of Physics, the University Statute). 4. CONDITIONS OF THE STUDY 4.1. Locations of the study programme Classes are held at the Higher Education Institution (Department of Physics, University of Osijek, Trg Ljudevita Gaja 6) 4.2. Space and equipment Currently there are 6 classrooms, 3 of which are also used as practicums and 2 as IT classrooms (spread over 577 m2). All are adequately equipped with computer equipment, being suitable for giving lectures. The classroom for methodology teaching (No 68) is equipped with the „whiteboard“ and the classroom/practicum for teaching electronics (No 67) has adequately equipped desks for safe teaching. Classes in practicums are carried out individually or in groups of two, and each student has enough space to perform all the necessary exercises. Each year, the Department of Physics invests significant resources in its own procurement of laboratory equipment for scientific research and teaching activities. At the Department of Physics there are 2 IT classrooms (No. 46 and 51) and one lecture / practicum with computers (No. 57) with a total of 59 computers and projectors. Students are provided with two classrooms (No. 46 and 57) in which there is a total of 33 computers that are permanently available, except during school hours. The computers are in good condition, functional and prepared to work with licensed applications. The maximum speed cable Internet connection is up to 1Gbit / s, and there is an available wireless network (password protected) with five access points (distributed to cover the entire area of the Department). There are 11 teacher's offices in the Department, with the average surface of 20 m2. Teachers have good working conditions (14 m2 of space per one full-time teacher ). Each cabinet is air conditioned and there is a central heating system (radiators). 112 4.3. Names of carriers and contractors who will participate in the courses at the beginning of the study TEACHERS and ASSOCIATES in academic 2014./2015. year 1st Semester Course title General Physics I Mathematics 1 (Differential calculus) Elementary Informatics E-Office Physical education 1 L S E 60 15 30 9 45 6 30 30 P 30 30 30 ECTS Teachers Associates doc.dr.sc. D. Stanić dr.sc. M. Poje, viši asistent M.V. Pajtler, prof. I. Krpan, prof. Lj.P. Gajčić,prof. 4 3 izv. prof. dr. sc. A. Klobučar prof.dr.sc. B. Dukić izv.prof.dr.sc. D. Dukić 1 J. Cvenić, v. pred. M. Katić, prof. M. Katić, prof. Elective courses: student choose 7 credits General and Inorganic Chemistry 1 Geometry of Plane and Space 30 15 5 doc.dr.sc. G. Šmit 30 30 5 doc.dr.sc. T. Marošević English/German 1 (optional) 30 2 D. Brajković, prof. K. Knežević, v. pred. * L=Lectures, S=Seminars, E= exercises, P=Practical (Laboratory) 2nd Semester Course title General Physics II Mathematics 2 (Integral calculus ) Physical education 2 L S E 60 15 30 9 45 30 30 P ECTS Teachers Associates doc.dr.sc. D. Stanić dr.sc. M. Poje, viši asistent M. V. Pajtler, prof. I. Krpan, prof. 6 izv.prof.dr.sc. A. Klobučar Lj.P. Gajčić, prof. 1 J. Cvenić, v. pred. Elective courses: student choose 14 credits General and Inorganic Chemistry 2 Linear Algebra 1 Algorithms and Data 30 15 6 doc.dr.sc. G. Šmit 30 30 6 doc.dr.sc. D. Marković 6 izv.prof.dr.sc. G. Dukić 30 30 dr. sc. I. Soldo Structures English/German 2 30 2 K. Knežević, v. pred. (optional) 113 3rd Semester Course title General Physics III L S E P 60 15 30 9 izv.prof. dr. sc. B. Vuković M.V. Pajtler, prof. Matematics 3 (Functions 30 30 5 prof.dr.sc. N. Truhar dr.sc. I. Kuzmanović, viši asistent 30 15 4 doc.dr.sc. Z. Glumac M. Mužević, prof. 60 5 izv.prof.dr.sc. B. Vuković 30 1 4 J. Cvenić, v. pred. doc.dr.sc. A. Baumgartner Karmen Knežević, v. pred. ECTS Teachers of more variables) Fundamentals of Measurement in Physics and Statistical Analysys General Physics Laboratory A Physical education 3 Basics of Programming 1 30 15 English/German 3 30 2 (optional) Associates dr.sc. M. Poje, viši asistent I. Ivković, pred. M. Mužević, prof. M. Katić, prof. 4th Semester Course title L General Physics IV 60 Classical Mechanics 1 General Physics Laboratory B 30 Diferencial Equations Physical education 4 30 S 15 E P ECTS 30 9 15 4 60 Teachers izv.prof. dr. sc. B.Vuković doc.dr.sc. Z. Glumac 5 izv.prof.dr.sc. B. Vuković 30 5 doc.dr.sc. K. Burazin 30 1 J. Cvenić, v. pred. Associates M.V. Pajtler, prof. M. Mužević, prof. dr.sc. M. Poje, viši asistent I. Ivković, pred. M. Mužević, prof. I.Vuksanović, prof. Elective courses: student choose 6 credits Basics of Programming 2 15 15 30 4 Multimedia Systems 30 15 15 4 English/German 4 (optional) University elective course 30 2 doc.dr.sc. A. Baumgartner prof.dr.sc. B. Dukić M. Katić, prof. mr.sc. S. Petrinšak, pred. K. Knežević, v. pred. 114 5th Semester Course title Classical Mechanics 2 Electrodynamics 1 Introduction to Stastical Physics L S 30 30 30 E P 15 30 15 ECTS 5 5 5 Teachers doc.dr.sc. Z. Glumac doc.dr.sc. J. Brana izv.prof.dr.sc. R. Ristić Associates M. Mužević, prof. I. Ivković, pred. Elective courses: student choose 15 credits Science of Strength 30 15 3 prof.dr.sc. T. Mrčela Mathematical Methods of Physics 45 30 5 doc.dr.sc. Z. Glumac Data Base and Process Analysis 30 30 5 prof.dr.sc. B. Dukić M. Katić, prof. Usage of Computers in Lectures 30 30 5 doc.dr.sc. D. Stanić mr.sc. S. Petrinšak, pred. 5 izv.prof.dr.sc. D. Dukić mr. sc. S.Petrinšak, pred. M. Katić, prof. ECTS Teachers Computer practicum 45 15 S E M. Mužević, prof. University elective course 6th Semester Course title Introduction to Quantum Mechanics Fundamentals of the Condensed Mater Physics Computational Physics L P 45 30 7 doc.dr.sc. I. Lukačević 30 15 5 izv.prof.dr.sc. R. Ristić 15 5 izv.prof.dr.sc. B. Vuković doc.dr.sc. Z. Glumac doc.dr.sc. I. Lukačević izv.prof.dr.sc. V. Radolić 15 Final thesis 30 15 5 Associates I. Miklavčić, pred. M. Mužević, asistent Elective courses: student choose 8 credits E-learning systems 15 Electrodynamics 2 30 Introduction to Astronomy and Astrophysics Special and General Relativity University elective course 15 30 4 izv.prof.dr.sc. D. Dukić D. Matotek, dipl.oec. 15 4 izv.prof.dr.sc. R.Ristić 30 15 4 prof.dr.sc. V. Vujnović doc.dr.sc. I. Lukačević izv.prof.dr.sc. R. Ristić dr.sc. M. Poje, viši asistent 30 15 4 doc.dr.sc. J. Brana M. Mužević, prof. 115 Data on teachers: 1. Name and Surname: prof.dr.sc. Branko Vuković 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: branko@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/~branko/ 5. Biography : Branko Vuković was born on 10 March 1960 in Tiborjanci. He finished primary school in Belišće and secondary school in Osijek. In 1984 he was granted a BSc degree in mathematics and physics from the Faculty of Education, University of Osijek. In 1994 he obtained his MSc degree and in 2002 his PhD degree in the field of nuclear physics, both at the Department of Physics, University of Zagreb. From February 1984 to September 1987 Dr. Vuković worked as a secondary school mathematics and physics teacher. Then he started to work at the Faculty of Education, University of Osijek, as as assistant. In April 2005 he was appointed assistant professor at the Department of Physics, University of Osijek. In October 2010 he was appointed asociate professor at the Department of Physics, University of Osijek. In 2005 he was appointed head of the Department of Physics, University of Osijek. Dr. Vuković's major research field of interest is low energy nuclear physics (project: Radioactivity and aerosols in the environment: radon). Dr. Vuković has published 23+4 scientific papers in journals cited in the Current Contents and Science Citation Index (Nucl. Instr. and Meth. B., J. Radioanal. Nucl. Chemistry, Inverse J. Radioanal. Nucl. Chem. Letters, Applied radiation and isotopes, …), 10 scientific papers in international conference proceedings, 20 scientific papers in Croatian conference proceedings. Dr. Vuković is a member of the Croatian Physical Society and the Croatian Radiation Protection Association. 6. List of papers (do 5 izabranih radova): 1. Radolić, Vanja; Miklavčić, Igor; Stanić, Denis; Poje, Marina; Krpan, Ivana; Mužević, Matko; Petrinec, Branko; Vuković, Branko. Identification and mapping radon-prone areas in Croatia - preliminary results for Lika-Senj and southern part of Karlovac county //Radiation Protection Dosimetry (2014), doi: 10.1093/rpd/ncu212, prihvaćeno za tisak 2. Poje, Marina; Vuković, Branko; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Varga Pajtler, Maja; Planinić, Josip.Mapping of cosmic radiation dose in Croatia. // Journal of environmental radioactivity. 103 (2012) ; 30-33. 3. Vuković, Branko; Poje, Marina; Varga, Maja; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Stanić, Denis; Planinić, Josip. Measurements of neutron radiation in aircraft. // Applied Radiation and Isotopes. 68 (2010) ; 2398-2402. 4. Vuković, Branko; Faj, Dario; Poje, Marina; Varga, Maja; Radolić, Vanja; Miklavčić, Igor; Ivković, Ana; Planinić, Josip.A neutron track etch detector for electron linear accelerators in radiotherapy. // Radiology and oncology. 44 (2010) , 1; 62-66. 5. Vuković, Branko; Radolić, Vanja; Lisjak, Ivan; Vekić, Branko; Poje, Marina; Planinić, Josip.Some cosmic radiation dose measurements aboard flights connecting Zagreb Airport. // Applied and Isotopes. 66 (2008) , 2; 247-251 7. List of other papers: http://bib.irb.hr/lista-radova?autor=149733&lang=EN 8. Last year of election in scientific-educational. scientific, educational or associate title:2010. 9. Scientific-educational, scientific, educational or associate title: Associate Professor. 10. Work status: Full time 116 1. Name and Surname: doc.dr.sc. Zvonko Glumac 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: zglumac@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/~zglumac 5. Biography : Zvonko Glumac was born on 13 August 1961 in Vukovar, where he also finished primary and secondary school. In 1987 he was granted a BSc degree in physics from the Faculty of Science, University of Zagreb. In 1996 he obtained his PhD degree in the field of statistical physics, at the Department of Physics, University of Zagreb. From October 1987 to February 1999, he worked at the Institute of Physics in Zagreb as assistant researcher. Then he started to work at the Faculty of Electrical Engineering in Osijek as a lecturer. He became assistant professor in 2002. Since April 2005 he works at the Department of Physics, University of Osijek. Dr. Glumac's major research field of interest is statistical physics, in particular phase transition and critical phenomena (project: 2008 Critical phenomena and system out of equilibrium 035-0000000-3187). Dr. Glumac has published 13+1 scientific papers in journals cited in the Current Contents and Science Citation Index (Phys. Rev. E, Eur. Phys. J. B, Phys. A, Phys. Rev. Lett., J. Phys. A, …), 9 scientific papers in international conference proceedings, 5 scientific papers in Croatian conference proceedings. Dr. Glumac is a member of the Croatian Physical Society. 6. List of papers: 1. Glumac, Zvonko; Uzelac, Katarina. Yang-Lee zeros and the critical behavior of the infinite-range two- and three-state Potts models. Physical Review E - Statistical, Nonlinear, and Soft Matter Physics. 87 (2013) , 2; 022140-1-022140-10 2. Uzelac, Katarina; Glumac, Zvonko; Barišić, Osor-Slaven. Short-time dynamics in the 1D long-range Potts model. European Physical Journal B. 63 (2008) , 1; 101-108 3. Glumac, Zvonko; Uzelac, Katarina. Complex-q zeros of the partition function of the Potts model with long-range interactions. Physica A: Statistical Mechanics and its Applications. 310 (2002) , 1-2; 91-108 4. Uzelac, Katarina; Glumac, Zvonko. The critical behaviour of the long-range Potts chain from the largest cluster probability distribution. Physica A: Statistical Mechanics and its Applications. 314 (2002) , 1-4; 448-453 5. Uzelac, Katarina; Glumac, Zvonko; Aničić, Ante. Critical behavior of the long-range Ising chain from the largest-cluster probability distribution. // Physical review E. 63 (2001) , 2; 0271 7.List of other papers: https://bib.irb.hr/lista-radova?autor=122211 8Last year of election in scientific-educational. scientific, educational or associate title:2012. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10. Work status: Full time. 117 1. Name and Surname: izv.prof. dr. sc. Ramir Ristić 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: ramir.ristic@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/~rristic/ 5. Biography : Ramir Ristić was born on 20.03. 1953 in Zagreb. He finished primary and secondary (Gimnazija “Braća Ribar”) school in Osijek. In 1975 he was granted a BSc degree from the Faculty of Science, University of Zagreb. In 1988 he obtained his MSc degree and in 1992 his PhD degree in the field of solid state physics, both at the Department of Physics, University of Zagreb. From1975 to 1977 he worked at grammar school „Božidar Maslarić“ as physics teacher. Then he started to work at the Education Academy which soon upgrade to Faculty of Education. In 1998 he was appointed assistant professor and 2010 he was appointed asociate professor at the Department of Physics, University of Osijek. Dr. Ristić's major research field of interest is solid state physics-amorphous metal physics. Dr. Ristić has published 16+1 scientific papers in journals cited in the Current Contents and Science Citation , 10 scientific papers in international conference proceedings and journal Fizika, He is a member of the Croatian Physical Society (HFD). 6. List of papers: 1. Remenyi, Gyorgy; Biljaković, Katica; Stare_šinić, Damir; Dominko, Damir; Ristić, Ramir; Babić, Emil; Figueroa, Ignacio A.; Davies, H. A.: Looking for footprint of bulk metallic glass in electronic and phonon heat capacities of Cu55Hf45-xTix alloys. // Applied physics letters 104 (2014) ; 171906-1-171906-4 . 2. Pajić, Damir; Marohnić, Željko; Drobac, Đuro; Zadro, Krešo; Ristić, Ramir; Babić, Emil. Evolution of Magnetism in Hf-Fe Metallic Glasses. // Journal of alloys and compounds 536S (2012) , (S1); S370-S373. 3. Ristić, Ramir; Babić, Emil; Pajić, Damir; Zadro, Krešo; Figueroa, Ignacio; Davies, Hywel; Todd, Ian; Kuršumović, Ahmed; Stubičar, Mirko: Mechanical and magnetic properties of Cu55Hf45-xTix metallic glasses. // Solid state communications 151 (2011) ; 1014-1017 . 4. Ristić, Ramir; Babić, Emil; Stubičar, Mirko; Kuršumović, Ahmed; Cooper, John Robert; Figueroa, Ignacio; Davies, Hywel; Todd, Ian; Varga, L.K.; Bakonyi, Imre: Simple correlation between mechanical and thermal properties in TE-TL (TE=Ti, Zr, Hf ; TL=Ni, Cu) amorphous alloys. // Journal of non-crystalline solids 357 (2011) ; 2949-2953. 5. Ristić, Ramir; Babić, Emil; Pajić, Damir; Zadro, Krešo; Kuršumović, Ahmed; Figueroa, I. A.; Davies, H. A.; Todd, I.; Varga, L. K.; Bakonyi, Imre:Properties and Atomic Structure of Amorphous Early Transition Metals. // Journal of alloys and compaunds 504S (2010) ; S194-S197. 7. List of other papers: http://bib.irb.hr/lista-radova?autor=86961&lang=EN 8. Last year of election in scientific-educational. scientific, educational or associate title:2010. 9. Scientific-educational, scientific, educational or associate title: Associate Professor 10. Work status: Full time 118 1. Name and Surname: doc. dr. sc. Denis Stanić 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: dstanic@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/~dstanic/ 5. Biography : Denis Stanić was born in Osijek, 1972. He finished primary and secondary school in Ivanovci and Valpovo. In 1999 he was granted a BSc degree in physics from the Faculty of Science, University of Zagreb. In 2009 he obtained his PhD degree in the field of solid state physics at the Department of Physics, Faculty of Science, University of Zagreb. In October 2000 he started to work at the Faculty of Education, University of Osijek, as as assistant. Since 2005 he is employed at the Department of Physics, University of Osijek. In December 2010 he was appointed assistant professor at the Department of Physics, University of Osijek, where still works as the head of chair of experimental physics. Dr. Stanić's major research field of interest is solid state physics (transport properties of complex metallic alloys; magnetic properties of amorphous ferromagnets) low energy nuclear physics (radioactivity in the environment; radon). He has published 21 scientific papers in journals cited in the Current Contents and attended many international and domestic conferences. Dr. Stanić is a member of the Croatian Physical Society, Croatian Radiation Protection Association and the Croatian Vacuum Society. 6. List of papers (do 5 izabranih radova): 1. Bobnar, M.; Jeglič, P.; Klanjšek, M.; Jagličić, Z.; Wencka, M.; Popčević, Petar; Ivkov, Jovica; Stanić, Denis; Smontara, Ana; Gille, P.; Dolinšek, J. Intrinsic anisotropic magnetic, electrical and thermal transport properties of d-Al-Co-Ni decagonal quasicrystal. // Physical Review B - Condensed Matter and Materials Physics. 85 (2012) ; 024205-1-024205-11 2. Jazbec, S.; Koželj, P.; Vrtnik, S.; Jagličić, Z.; Popčević, Petar; Ivkov, Jovica; Stanić, Denis; Smontara, Ana; Feuerbacher, M.; Dolinšek, J. Electrical, magnetic and thermal properties of the δ-FeZn10 complex intermetallic phase. // Physical Review B - Condensed Matter and Materials Physics. 86 (2012) ; 064205-1-064205-8 3. Ivkov, Jovica; Popčević, Petar; Stanić, Denis; Bauer, B.; Gille, P.; Dolinšek, J.; Smontara, Ana. Anisotropic Hall effect in Al13TM4 approximants. // Philosophical magazine 91 (2011) , 19/21; 2739-2745 4. Popčević, Petar; Stanić, Denis; Bihar Željko; Bilušić, Ante; Smontara, Ana. Heat transport in aluminum based quasicrystals i-AlPdMn, i-AlCuFe, and d-AlCoNi. // Israel journal of chemistry. 51 (2011) , 11/12; 1340-1348 5. Vuković, Branko; Poje, Marina; Varga, Maja; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Stanić, Denis; Planinić, Josip. Measurements of neutron radiation in aircraft. // Applied radiation and isotopes. 68 (2010), 12; 2398-2402 7. List of other papers: http://bib.irb.hr/lista-radova?autor=255790 8. Last year of election in scientific-educational. scientific, educational or associate title: 2010. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10. Work status: Radni odnos na neodređeno vrijeme - puno radno vrijeme 119 1. Name and Surname: doc.dr.sc. Josip Brana 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: jbrana@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/~jbrana 5. Biography : Josip Brana was born in Derventa on 22 April 1949 (father Henrik,, mother Olga) where he finished primary scholl and teachers'college. In 1973 he was granted a BSc degree in physics from the Faculty of Science in Sarajevo. He obtained his MSc degree at the Faculty of Science in Zagreb, branch Theorietical physics, and his PhD in 1977, branch Physical scienses menthored by Prof. Krunoslava Ljolje at the Faculty of Science in Sarajevo (Theme: Dirac's and Maxwell's field their relationship and interconnection.) From 1973-1979 he works as an assistant at the Faculty of Science in Sarajevo, Department of Physics, teaching Excersizes in theoretical physics (Quantum mechanics, Quantum field theory, Theory of gravitational fields, Physics of elementary particles). As an assistant professor he teaches Quantum theory from 1979 – 1987. From 1987-1997 he works on researches in physical oceanography at the Institute «Ruđer Bošković» in Rovinj. From 1997-2000 he works ast the Faculty of Economics and Tourism «Dr. M. Mirković» in Pula, University of Rijeka, teaching Statistics and Aconometrics. From 1993 – 2000 he teaches as external associate Quantum theory and the Structure of matter as well as Electrodinamics at the Faculty of Education, University "J.J. Strossmayera" in Osijek He also teaches Quantum theory and Stucture of matter from 1997-1999 at the Faculty of Science in Split. From 2000 – 2004 he works at the Faculty of Education, University in Osijek, teaching Quantum theory and the Structure of matter, Electrodynamics. He was the Head of physics seminars and teaches Statistics at the Department of Biology and Chemistry. He initiated the formation of the Department of Physics at the University "J. J. Strossmayer" in Osijek and becames its Head in 2004 (till 2005). From 2005 -2012 he works at the Department of Physics. He is the Head of the Desk for Theoretical and Computational Physics, as well. From 2012 till tody he works at the Faculty of Electrical Engeneering in Osijek. As external assosiate he works at the Universities in Pula and Mostar. He mentored about fourty thesis works and one master's thesis. He is the autor of one book – university textbook: The general theory of relativity - Einstein's theory of gravity (First part), University in Osijek, 2011. He translated the book A. Salam: The unification of the fundamental forces of nature, Školska knjiga Zagreb, 1996. He has published more than twenty scientific papers in the field of quantum theory, electrodynamics and quantum field theory, physical oceanography and environmental physics. He managed and participated in several scientific projects in Bosnia and Herzegovina, and Croatia. He also participated in several national and international scientific meetings. He was an active participant (President of the Commission for Nature) in the development of the Croatian National Educational Standards and Curricula for Nature, autor of dozen of popular works of modern physics, the physics of the sea and the history of physics, as well as popularizer of physics 120 through public lectures. He was the secretary of mathematicians, physicists and astronomers of BiH (1981-1985) as well as pedagogical manager of the former Yugoslavia during the physical Olympics in Stockholm. He is a member of the German Physical Society and one of the initiators of founding a subsidiary in Osijek, as well as its president for two terms (2002 -2010). He is a member of the American Physical Society. 6. List of papers: 1. Brana, J.H. (2001). Quantum generalization of electrodynamics without the divergent Coulomb self-interaction. Il Nuovo Cimento 116 B (2001) 687-695. 2. Brana, J.H.; S. Kilić; L. Vranješ(2002). Helium 4 Dimer in Two Coaxial Adjacent Nanotubes. Journal of Low Temperature Physics, 126 (2002) 265-270. 3. Buljan, A.V.; Delikatny, E.V.; Brana, J.H.; Garvey, C., and Hambley, B.D.(2003). Does microtubules architecture obey fullerenic principles? Proceedings of the 27th Annual Conference of the Australian Society for Biophysics (ASB P9), 19-20 September 2003, Adelaide, South Australia. 4. Brana,H. J.(2001). Na razmeđu tisućljeća - Stota obljetnica Planckove hipoteze kvanata. Nova Istra. 5. Brana, H. J.(2002). Stogodišnjica rođenja P. A. M. Diraca. Bosna Franciscana, 17 (2002) 301. 6. Brana, J.(2003). Sjećanje na profesora Krunoslava Ljolje. Bosna Franciscana, 18 (2003) 289. 7. List of other papers: http://bib.irb.hr/mzos/lista-radova?autor=138323 8Last year of election in scientific-educational. scientific, educational or associate title: 2011. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10. Work status: Part time (25% of full time) 121 1. Name and Surname: Izv.prof.dr.sc. Darko Dukić 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: darko.dukic@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/~ddukic 5. Biography : Darko Dukić is an associate professor in the field of information and communication sciences in the Department of Physics at the Josip Juraj Strossmayer University of Osijek. He was born on December 1, 1970, in Osijek, where he finished elementary school and high school (mathematics and informatics), passing all his classes with the highest marks. After military service, he enrolled as a full-time student at the Faculty of Economics in Osijek. He graduated in 1995 from the program in Economic Cybernetics, with an average grade of 4.92/5.00. In 1998, he received his MSc from the same faculty, also with an average grade of 4.92/5.00. In 2006, he defended his doctoral thesis and received his PhD degree from the Faculty of Economics in Osijek. From 1995 to 1998 he was employed as a teacher and IT manager at the Primary School 'Mladost' in Osijek. In 2002, he established the enterprise specialized in tuition, statistical research and IT consulting. He joined the Department of Physics as a senior assistant in 2008. He became an assistant professor in 2009 and an associate professor in 2013. Darko Dukić is the author and co-author of more than 50 scientific papers published in international journals and presented at international academic conferences. Over the past few years, he has worked on several scientific research projects. His research and teaching interests include information technology implementation and adoption, online databases and e-resources, management information systems, e-learning, simulation models, statistics, and data mining. He is married and the father of two children. He became a member of MENSA in 1995. 6. List of papers (do 5 izabranih radova): 1. Dukić, Darko: Use and perceptions of online academic databases among Croatian university teachers and researchers. // LIBRI: International Journal of Libraries and Information Services, 64 (2014), 173-184. 2. Dukić, Darko: Online databases as research support and the role of librarians in their promotion: The case of Croatia. // Library Collections, Acquisitions, and Technical Services, 37 (2013), 56-65. 3. Dukić, Darko; Kozina, Goran: ICT knowledge and skills of Croatian polytechnic students. // Technics Technologies Education Management, 7 (2012), 758-764. 4. Penny, Kay, Dukić, Darko: E-learning participation in higher education: A study of Scottish and Croatian students. // CIT – Journal of Computing and Information Technology, 20 (2012), 183188. 5. Dukić, Darko; Dukić, Gordana; Kozina, Goran: Analysis of students’ ICT usage in the function of Croatian higher education development management. // Technical Gazette, 19 (2012), 273-280. 7. List of other papers: http://bib.irb.hr/lista-radova?autor=260093 8. Last year of election in scientific-educational. scientific, educational or associate title:2013. 9.Scientific-educational, scientific, educational or associate title: Associate Professor 10.Work status: Full time. 122 1. Name and Surname: doc.dr.sc. Igor Lukačević 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: igor.lukacevic@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/~ilukacevic/ 5. Biography : Igor Lukačević, assistant professor from the Department of Physics, University J. J. Strossmayer in Osijek, was born on March 10th 1978. in Osijek, Croatia. In Osijek he finishes his elementary and high school (3rd Gymnasium). He graduated in 2001. at University J. J. Strossmayer in Osijek (Mathematics and Physics teacher). He obtained his PhD degree in 2009. at Physics Department, Faculty of Natural Sciences and Mathematics in Zagreb in the field of molecular and atomic physics (mentor was D. Kirin). After graduation he starts to work at Physics Section, Faculty of Philosophy in Osijek, as a research associate. Together with the Physics Section he transfers to the Department of Physics, University J. J. Strossmayer in Osijek, in 2004. After completing his PhD study in 2009., he remains at the Department of Physics as senior assistant. Four years later he obtains a position of assistant professor, which is his current position. Fields of research include theoretical solid state physics (applications of density functional theroy) and applied spectroscopy. He published 11+2 scientific articles in journals with international review and cited in Current Contents and Science Citation Index (Physical Review B, Journal of Alloys and Compounds, Solid State Sciences, Materials Chemistry and Physics, Computational Materials Science,…). He also has more than 10 scientific papers in international Conference Proceedings. He is a memeber of Croatian Physical Society (HFD) and American Optical Society (OSA). 6. List of papers (do 5 izabranih radova): 1. Lukačević, Igor; Gupta, Sanjeev K. Nature of low compressibility and anisotropic elasticity in YbB2. // Journal of alloys and compounds. 597 (2014) ; 148-154. 2. Jha, Prafulla K.; Gupta, Sanjeev K.; Lukačević, Igor. Electronic structure, photocatalytic properties and phonon dispersions of X-doped (X = N, B and Pt) rutile TiO2 from density functional theory. // Solid state sciences. 22 (2013) ; 8-15. 3. Lukačević, Igor; Gupta, Sanjeev K.; Jha, Prafulla K.; Kirin, Davor. Lattice dynamics and Raman spectrum of rutile TiO2: the role of soft phonon modes in pressure induced phase transition. // Materials chemistry and physics. 137 (2012) , 1; 282-289. 4. Mankad, Venu; Gupta, Sanjeev K.; Lukačević, Igor; Jha, Prafulla K. Thermodynamical and Phonon Properties of Rare-Earth REBi (RE=Ce and La) Bismuthidies. // Computational materials science. 65 (2012) ; 536-541. 5. Kirin, Davor; Lukačević, Igor. Stability of high-pressure phases in II-VI semiconductors by a density functional lattice dynamics approach. // Physical Review B - Condensed Matter and Materials Physics. 75 (2007) , 17; 172103-1172103-4. 7. List of other papers: http://bib.irb.hr/lista-radova?autor=254726 8. Last year of election in scientific-educational. scientific, educational or associate title:2013. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10. Work status: Full time 123 1. Name and Surname: dr.sc. Marina Poje, viša asistentica 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: marina.poje@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/cms/fizos/hr/opcipodaci/ured/web_imenik/marina_poje.html 5. Biography : Marina Poje was born on 2nd of June 1983 in Osijek, where she finished her primary and secondary education. In the academic year 2001/02 she started the study of physics and polytechnics in the Faculty of Education (now the Faculty of Philosophy) at the Josip Juraj Strossmayer University. In the year 2004 the Department of Physics was established at the same University, which she successfully completed in April 2006. In the same year she has been employed in the position of an assistant to the scientific field of natural sciences in the field of Physics, the scientific branch of Atomic and Molecular Physics. In 2007 she started post-graduate study in Physics, scientific branch of Atomic and Molecular Physics and Astrophysics at the Physics Department, Faculty of Science in Zagreb. She acquired her PhD in 2012. (Supervisors: Prof. Josip Planinić, professor emeritus, PhD., and professor Branko Vukovic, PhD). She is an active researcher on the project, "Radioactivity in the environment - low radiation doses" as this is her primary scientific interest. Results of this research was published in a series of scientific papers. Dr. Poje is an active member of the Croatian Physical Society and the Croatian Radiation Protection Association on whose scientific meetings regularly and actively participate. 6. List of papers (do 5 izabranih radova): 1. Poje, Marina; Vuković, Branko; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Varga Pajtler, Maja; Planinić, Josip. Mapping of cosmic radiation dose in Croatia. // Journal of environmental radioactivity. 103 (2012), 1; 30-33 (članak, znanstveni). 2. Vuković, Branko; Poje, Marina; Varga, Maja; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Stanić, Denis; Planinić, Josip. Measurements of neutron radiation in aircraft. // Applied radiation and isotopes. 68 (2010) , 12; 2398-2402 (članak, znanstveni). 3. Miklavčić, Igor; Radolić, Vanja; Vuković, Branko; Poje, Marina; Varga, Maja; Stanić, Denis; Planinić, Josip. Radon anomaly in soil gas as an earthquake precursor. // Applied radiation and isotopes. 66 (2008) , 10; 1459-1466 (članak, znanstveni). 4. Poje, Marina; Vuković, Branko; Varga, Maja; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Planinić, Josip. Relation between galactic and solar cosmic radiation at aviation altitude. //Advances in Space Research. 42 (2008) , 12; 1913-1916 (članak, znanstveni). 5. Vuković, Branko; Radolić, Vanja; Lisjak, Ivan; Vekić, Branko; Poje, Marina; Planinić, Josip. Some cosmic radiation dose measurements aboard flights connecting Zagreb Airport. //Applied Radiation and Isotopes. 66 (2008) , 2; 247-251 (članak, znanstveni). 7.List of other papers: : https://bib.irb.hr/lista-radova?autor=288651 8. Last year of election in scientific-educational. scientific, educational or associate title: 2012. 9. Scientific-educational, scientific, educational or associate title: senior instructor 10. Work status: Full time 124 1. 2. 3. 4. Name and Surname: dr.sc. Maja Varga Pajtler, asistentica Name of basic organisation: Odjel za fiziku E-mail adress: mvarga@fizika.unioshr Adress of private web page: http://www.fizika.unios.hr/cms/fizos/hr/opcipodaci/ured/web_imenik/maja_varga.html 5. Biography : Maja Varga Pajtler is an assistant proffesor at the Department of Physics, University J. J. Strossmayer in Osijek. She is born on 19th of April 1984 in Osijek. She finished primary and secondary school in Osijek. In 2007 she was granted a BSc degree in mathematics and physics from the Department of Mathematics, University J. J. Strossmayer in Osijek. In 2008 she started her postgraduate study in the field of nuclear physics at the Department of Physics, Faculty of Science, University of Zagreb. Her major research field of interest is low energy nuclear physics (project: Radioactivity and aerosols in the environment: radon). As a part of her PhD study, she studies multinucleon transfer reaction, under supervision of dr. Suzana Szilner from the Ruđer Bošković institute, Zagreb. She has published 5 scientific papers in journals cited in the Current Contents and Science Citation Index, 1 scientific paper in international conference proceedings, 6 scientific papers in Croatian conference proceedings. Maja Varga Pajtler is a member of the Croatian Physical Society and the Croatian Radiation Protection Association. 6. List of papers (do 5 izabranih radova): 1. Poje, Marina; Vuković, Branko; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Varga Pajtler, Maja; Planinić, Josip. Mapping of cosmic radiation dose in Croatia. // JOURNAL OF ENVIRONMENTAL RADIOACTIVITY. 103 (2012) , 1; 30-33 2. Vuković, Branko; Poje, Marina; Varga, Maja; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Stanić, Denis; Planinić, Josip. Measurements of neutron radiation in aircraft. // Applied radiation and isotopes. 68 (2010) , 12; 2398-2402 3. Miklavčić, Igor; Radolić, Vanja; Vuković, Branko; Poje, Marina; Varga, Maja; Stanić, Denis; Planinić, Josip. Radon anomaly in soil gas as an earthquake precursor. // Applied radiation and isotopes. 66 (2008) , 10; 1459-1466 4. Poje, Marina; Vuković, Branko; Varga, Maja; Radolić, Vanja; Miklavčić, Igor; Faj, Dario; Planinić, Josip. Relation between galactic and solar cosmic radiation at aviation altitude. // Advances in Space Research. 42 (2008) , 12; 19135. Vuković, Branko; Radolić, Vanja; Miklavčić, Igor; Poje, Marina; Varga, Maja; Planinić, Josip. Cosmic radiation dose in aircraft - a neutron track etch detector. // Journal of Environmental Radioactivity. 98 (2007) , 3; 264-273 7.List of other papers: https://bib.irb.hr/lista-radova?autor=295226&lang=HR 8. Last year of election in scientific-educational. scientific, educational or associate title: 2014. 9. Scientific-educational, scientific, educational or associate title: senior instructor 10. Work status: Radni odnos na određeno vrijeme - puno radno vrijeme. 125 1. Name and Surname: Karmen Knežević, v.pred. 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: karmen.knezevic@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/~kknezevic 5. Biography : Karmen Knežević, senior lecturer, was born on 20 February 1966 in Osijek. She finished primary school in Pforzheim (Germany) and Osijek and secondary school in Osijek. In 1989 she was granted a BSc degree in English language and literature and German language and literaturee from the Faculty of Education, University of Osijek. In 2010 she obtained the Academic title Specialist of European Studies at the University J.Jurja Strossmayera of Osijek. From September 1989 till May 1991 she worked as a teacher of English and German language at a foreign language school in Osijek. In 1991 she became Head of the Protocol and Mayor 's Cabinet. During war period she worked in her hometown and in 1993 she moved for family reasons to Pula, where she worked as high school teacher. In February 1996 returned to Osijek and started to work in the City of Osijek as the Head of Department for International Cooperation. In 2007 she started to work as subcontractor of English language at the Faculty of Economy in Osijek. In 2010 she became advisor for International Affairs at Mayor 's Office, where she remained until 2011. Then she started to work at at the Department of Physics, University of Osijek as a lecturer of English and German language. In 2014 she was appointed senior lecturer in English and German language. 6. List of papers (do 5 izabranih radova): Stručni radovi 1. Knežević, K., (2013.) "Regional competitiveness through innovative teaching: team teaching at the university“, zbornik radova , 33rd Scientific Symposium Osijek Pforzheim 2. Knežević, K., Poje, M., (2012.) „Timska nastava kao inovativan pristup u obrazovanju na visokoškolskim ustanovama“, Ekonomski vjesnik, Osijek 3. Knežević,K., Kraljević, L. (2012.) „Višejezičnost kao čimbenik jačanja konkurentnosti na gospodarskom tržištu“, Ekonomski vjesnik, Osijek 4. Knežević,K., (2008.) „Perspektiva nove jezične politike- Nova višejezičnost i učenje Engleskih jezika“, Ekonomski vjesnik, Osijek Udžbenik: 1. Knežević, Karmen, Sedlan-Koenig, Ljerka, Vujčić, Jasna (2011.), College Writing Skills, University J. J. Strossmayera in Osijek, Osijek Skripte : 1. Knežević K.;Kraljević ,L. (2008.) Physics I, Odjel za fiziku 2. Knežević K.;Kraljević ,L. (2008.) Physics II, Odjel za fiziku 3. Knežević K.;Kraljević ,L. (2014.) Deutsch in der Physik, Odjel za fiziku 7. List of other papers: nije evidentirano 8. Last year of election in scientific-educational. scientific, educational or associate title:2014. 9. Scientific-educational, scientific, educational or associate title: senior lecturer 10.Work status: Full time 126 1. Name and Surname: Mr.sc. Slavko Petrinšak, predavač 2. Name of basic organisation: Odjel za fiziku 3. E-mail adress: slavko.petrinsak@fizika.unios.hr 4. Adress of private web page: http://www.fizika.unios.hr/cms/fizos/hr/opcipodaci/ured/web_imenik/slavko_petrinsak.html 5. Biography : Slavko Petrinšak, lecturer at the Department of Physics, University of Josip Juraj Strossmayer, was born May 5 1962 in Ivanovac. Attended elementary and secondary school in Osijek (CUO "Braća Ribar") and graduated 1987 at the Faculty of Pedagogy, University of Osijek (Professor of technical education). Started postgraduate computer science education studies at the Technical Faculty "Mihajlo Pupin" in Zrenjanin in 1987, where he graduated in 2005 (MSc in Informatics) mentored by Professor V. Sotirović. In September 1988 started working at Osijek’s Faculty of Pedagogy as an assistant intern on the project "Education and scientific - technological development of Yugoslavia." From 1992 until 1994 employed at the Center for Automatic Data Processing of Osijek-Baranja County. In 1993 passed the professional exam for Automatic Data Processing organizers before a commission of the Ministry of Science and Technology. From 1995 until 2006 employed as a teacher of computer science and technical education at the elementary school Tin Ujević in Osijek. Acquired full ECDL certificate in 2005. Since 2006 employed at the Department of Physics, University of Osijek, in the scientific area of technical sciences, scientific field of computer science and information systems. Attended E-learning Academy Carnet for two semesters during 2006 and 2007 and acquired the E-Learning Tutoring certificate. A student of technical sciences doctoral studies at the Faculty of Electrical Engineering in Osijek, University of Osijek. Primary area of scientific interest application of ICT in education. Regularly participates as speaker at conferences in the field of technical education, computer science and robotics as well as primary and secondary school teachers’ professional conferences in Croatia. Member of the computer science examination committee (as an educational expert) that conducts professional exams for teachers and assistants in primary and secondary schools. In January 2014 workshop coordinator of the IPA project "Child Safety on the Internet"; week long workshop covered topics like curriculum development based on pre-defined learning outcomes, development of teaching materials and the organization of lessons for teaching children to a safer use of the Internet. 6. List of papers (do 5 izabranih radova): 1. Gugić, Ivan; Smilevski, Cvetko; Petrinšak, Slavko. Analiza, koncepcija i organiziranost radno-tehničkog odgojno-obrazovnog područja kod nas u pogledu njegovog doprinosa znanstveno-tehnološkom razvoju Jugoslavije//Osijek, Život i škola, 1988., UDK 37 YU ISSN 0044-4855 (569.-581. str.) 2. Lončar-Vicković, Sanja; Dolaček-Alduk, Zlata. Ishodi učenja - priručnik za sveučilišne nastavnike// Osijek: Sveučilište Josipa jurja Štrossmayera, 2009., UDK 378.4(497.5 Osijek) (036) Autor dijela teksta (135. – 159. str.). 7. List of other papers: nije evidentirano 8. Last year of election in scientific-educational. scientific, educational or associate title:2008. 9. Scientific-educational, scientific, educational or associate title: lecturer 10. Work status: Full time 127 1. Name and Surname: Izv.prof.dr.sc. Krešimir Burazin 2. Name of basic organisation: Department of Mathematics, University of Osijek 3. E-mail adress: kburazin@mathos.hr 4. Adress of private web page: http://www.mathos.hr/~kburazin 5. Biography : Krešimir Burazin was born on February 22nd, 1977 in Osijek. He attended primary school in Komletinci and mathematical school in Vinkovci. In 1955 he enrolled at the Department of Mathematics, Faculty of Science in Zagreb, where he graduated in December 1999 (engineer of applied mathematics) under supervision of prof. N. Antonić. The graduate thesis was entitled Variational theory of phase transitions. In March 2004, at the same university, he defended his master thesis titled Application of compensated compactness in theory of hyperbolic systems (advisor prof. N. Antonić). In September 2008 he successfully defended his dissertation titled Contributions to the theory of Friedrichs and hyperbolic systems (advisor prof. N. Antonić). From March 2000 to July 2003 he worked as a teaching assistant at the Faculty of Electrical Engineering and Computing, University of Zagreb, from August 2003 to November 2009 he worked as a teaching assistant at the Department of Mathematics, University of Osijek, and since December 2009 he works as an assistant professor at the Department of Mathematics, University of Osijek. He is a vice chair for education and students of the chair of Department of mathematics. He has participated as an associate in the work of four scientific research projects financed by the Ministry of Science: three of them were entitled Oscillatory solutions of partial differential equations (1997 – 2002, 2002 – 2006 and 2007 – 2014), and bilateral projects with the Republic of Serbia Functional analysis methods in mathematical modeling (2011 - ). He was the principal researcher of the project Evolution Friedrichs systems funded by J.J. Strossmayer University of Osijeku. He is the researcher on the project Week convergence methods and applications funded by Croatian Science Foundation and the coordinator for the University of Osijek of DAAD Project Center of Excellence for Applications of Mathematics. Scientific interests of Krešimir Burazin are in the field of mathematical analysis (partial differential equations, functional analysis, continuum mechanics), and he participated in more than 20 international conferences and mathematical school, where he gave a speech multiple times. He has published 11 papers in scientific journals, 6 of which are cited in the Science Citation Index Expanded and one research paper published in proceeding of international conference. He was teaching a number of different courses in universities at home and abroad. He was a leader of the student team of University of Osijek that participated in international student competitions in mathematics. He is a member of the Osijek Mathematical Society, Croatian Mathematical Society and a moderator of the Working seminar of the Department of Mathematics. 6. List of papers (do 5 izabranih radova): 1. N. Antonić, K. Burazin, Graph representation for asymptotic expansion in homogenisation of nonlinear first-order equations, Annali dell’Universita di Ferrara. Sezione VII. Scienze Matematiche. 53 (2007), 2: 149–176. 128 2. N. Antonić, K. Burazin, Intrinsic boundary conditions for Friedrichs systems, Communications in Partial Diferential Equations, 35 (2010), 9, 1690-1715. 3. Antonić Nenad, Burazin Krešimir, Vrdoljak Marko, Heat equation as a Friedrichs system , Journal of Mathematical Analysis and Application 404 (2013), 537-553 4. N. Antonić, K. Burazin, M. Vrdoljak, Second-order equations as Friedrichs systems, Nonlinear Analysis: Real World Applications, 14 (2014), 290-305 5. Burazin Krešimir, Vrdoljak Marko, Homogenisation theory for Friedrichs systems, Communications on Pure and Applied Analysis 13 (2014), 1017-1044 7. List of other papers: http://bib.irb.hr/mzos/lista-radova?autor=252985 8. Last year of election in scientific-educational. scientific, educational or associate title: 2014. 9. Scientific-educational, scientific, educational or associate title: Associate Professor. 10. Work status: Full time 129 1. Name and Surname: prof.dr.sc. Antoaneta Klobučar 2. Name of basic organisation: Department of Mathematics, University of Osijek 3. E-mail adress: aneta@efos.hr 4. Adress of private web page: http://oliver.efos.hr/~aneta/indexhrv.html 5. Biography : Antoaneta Klobučar, full professor at the Department of Mathematics, University of Osijek, was born on 17 September 1963 in Vinkovci. Since 1967 she has lived in Osijek, where she completed her primary and secondary school education. In 1986 she obtained her BSc degree in mathematics and physics from the Faculty of Education, J.J. Strossmayer University of Osijek. In 1990 and 1997 she obtained her MSc and PhD degree (field: combinatorics and graph theory), respectively, both from the Department of Mathematics, University of Zagreb. From 1986 to 1999 she worked as an assistant at the Faculty of Economics, University of Osijek. In 1999 Dr. Klobučar was appointed assistant professor. Since 2001 she has also worked at the Department of Mathematics. Since 2014 she was full professor. Dr. Klobučar has had several one-month study stays at the Montanuniversität Leoben, Austria, where she established good cooperation with Prof. N. Seiter who was her dissertation advisor. Dr. Klobučar has published 17 papers in international journals, two papers in international conference proceedings and three professional papers in Croatian journals. She is a member of the Croatian Mathematical Society. She has taken part in several projects. 6. List of papers (do 5 izabranih radova): [1] S. Majstorović, I. Gutman, A. Klobučar, Tricyclic Biregular Graphs Whose Energy Exceeds the Number of Vertices, Mathematical Communication, Vol. 15, Number 1 (2010), 213-222. [2] I. Gutman, A. Klobučar, S. Majstorović, C. Adiga, Biregular Graphs Whose Energy Exceeds the Number of Vertices, MATCH, Vol. 62, Number 3 (2009), 499-508. [3] S. Majstorović, A. Klobučar, I. Gutman, Triregular Graphs Whose Energy Exceeds the Number of Vertices, MATCH, Vol. 62, Number 3 (2009), 509-524. [4] M. El-Zahar, S. Gravier, A. Klobučar, Total Domination Number of Cross Products of Graphs, Discrete Mathematics, 308 (2008), 2025-2029. [5] A. Klobučar, K-dominating Sets on the Associative and Commutative Products of Two Paths, Croatica Chemica Acta, Vol. 80, Number 2 (2008), 181-185. 7. List of other papers: http://bib.irb.hr/mzos/listtia-radova?autor=145815 8. Last year of election in scientific-educational. scientific, educational or associate title:2014. 9. Scientific-educational, scientific, educational or associate title: full professor 10. Work status: Radni odnos na neodređeno vrijeme - puno radno vrijeme 130 1. Name and Surname: prof.dr.sc. Ninoslav Truhar 2. Name of basic organisation: Department of Mathematics, University of Osijek 3. E-mail adress: ntruhar@mathos.hr 4. Adress of private web page: http://www.mathos.hr/~ntruhar 5. Biography : Ninoslav Truhar was born on 04 May 1963 in Osijek. He completed his primary and secondary school education in Osijek. In 1987 he obtained his BSc degree in mathematics and physics from the Faculty of Education, University of Osijek. From 1989 to 1991 he attended postgraduate study programme in mathematics at the University of Novi Sad (Serbia). In 1995 he obtained his MSc degree from the Department of Mathematics, University of Zagreb, with the thesis entitled Perturbation of Invariant Subspaces. In 2000 he obtained his PhD degree from the Department of Mathematics, University of Zagreb, with the dissertation entitled Relative Perturbation Theory for Matrix Spectral Decompositions. In 1997 Dr. Truhar spent two months as a visiting researcher at the Pennsylvania State University, State College, PA, USA. From 1999 to 2001 he stayed at the Department of Mathematical Physics, Faculty of Mathematics, Fernuniversität Hagen, Germany for the purpose of carrying out postdoctoral research. In 2006 he was visiting researher at Department of Mathematics, University of Kentucky, Lexington, Kentucky, USA and 2007 and 2013. he was visiting professor at Department of Mathematics at the University of Texas at Arlington, Arlington, Texas, USA. From 1989 to 2001 Dr. Truhar worked as an assistant at the Faculty of Civil Engineering in Osijek. In 2001 he was appointed assistant professor at the same institution. From 2005. he work as assistant professor at the Department of Mathematics, University of Osijek and Faculty of Civil Engineering in Osijek (joint position 50% + 50%). From 01.10.2005 he works as the full time assistant professor at the Department of Mathematics, University of Osijek and on 14.12.2009 he was appointed full professor at the Department of Mathematics, University of Osijek.. Prof. dr. sc. Truhar's main scientific interest are applied and numerical mathematics, as well as mathematical physics. He has published more then 30 scientific papers in journals cited in Current Contents and Science Citation Index and 7 scientific papers in other journals. He has also published 5 papers in conference proceedings and 3 profesional papers. He is a member of the Management committee of the project European Model Reduction Network (EU-Morne), funded under the COST action TD1307. He was the leader of the research project: "Passive control of mechanical models", and has been a researcher in the following projects: "Estimation of parameters in mathematical models," Accurate and fast numerical algorithms and applications "," Numerical linear algebra", all supported by Ministry of Science, Education and Sports of the Republic of Croatian Dr. Truhar is a member of the Croatian Mathematical Society and currenly he is head of the Osijek Division. He is also a member of the American Mathematical Society (AMS), t he GAMM Activity Group on Applied and Numerical Linear Algebra, the British Computer Society and the Canadian Mathematical Society. 6. List of papers (do 5 izabranih radova): 1. Mengi Emre, Kressner Daniel , Nakić Ivica, Truhar Ninoslav, eneralized Eigenvalue Problems with Specified Eigenvalues, The IMA Journal of Numerical Analysis 34 (2014), 480-501 2. Benner, Peter; Tomljanović, Zoran; Truhar, Ninoslav.; Optimal Damping of Selected Eigenfrequencies Using Dimension Reduction, Numerical Linear Algebra with Applications 20 (2013), 1-17 131 3. Benner, Peter; Truhar, Ninoslav; Li, Ren-Cang.; On ADI Method for Sylvester Equations. Journal of computational and applied mathematics. 233 (2009) , 4; 1035-1045 4. Truhar, Ninoslav; Veselić, Krešimir.; Bounds on the trace of a solution to the Lyapunov equation with a general stable matrix. Systems and Control Letters. 56 (2007) , 7-8; 493-503. 5. Truhar, Ninoslav. An efficient algorithm for damper optimization for linear vibrating systems using Lyapunov equation. Journal of Computational and Applied Mathematics, 172 (2004), 169--182. 7. List of other papers: http://www.mathos.unios.hr/index.php/kadrovi/nastavnici-i-suradnici/120 8. Last year of election in scientific-educational. scientific, educational or associate title:2 013. 9. Scientific-educational, scientific, educational or associate title: full professor 10. Work status: Full time 132 1. Name and Surname: doc.dr.sc. Darija Marković 2. Name of basic organisation: Department of Mathematics, University of Osijek 3. E-mail adress: darija@mathos.hr 4. Adress of private web page: http://www.mathos.hr/~darija/ 5. Biography : Darija Marković, assistant professor of the Department of Mathematics was born on 7 July 1976. in Osijek, where she completed her primary and high school education. She graduated in 2000. at the Department of Mathematics, University of Osijek, obtained her MSc degree in 2005. from the Department of Mathematics, and obtained her PhD degree in 2009. from the Department of Mathematics, University of Zagreb in the field of applied and numerical mathematics. For the purpose of professional improvement and advanced in-service training in the field of mathematics she has spent some time at the following institutions: Max-Planck-Institut für Informatik Saarbrücken (2005), Technische Universität Berlin (2007), Eidgenössische Technische Hochschule Zürich (2008.). In 2000 she started to work at the Department of Mathematics in Osijek. In 2008 she was appointed lecturer. In 2010 she was appointed assistant professor at the Department of Mathematics. Dr. Marković's field of research interest is applied and numerical mathematics – espetially Least Squares Problems, Mathematical Modeling and Parameter Estimation Problems. Aspects: egzistence of solution, numerical methods for solving. Applications: by solving parameter identification problems in mathematical models, (agriculture, economy, marketing, electrical engineering, medicine, food technology). She has published 6 scientific papers in internationally reviewed journals, 3 of whiche are cited in Current Contents and 6 in Science Citation Index expanded (J. Comput. Appl. Math., Appl.Math.Model, Appl. Math. Comput., Math. Commun., Int. J. Appl. Math. Comput. Sci.). She has published 4 expert papers which was presented at international scientific and expert meetings. 6. List of papers (do 5 izabranih radova): 1. Marković, Darija; Jukić, Dragan. On parameter estimation in the Bass model by nonlinear least squares fitting the adoption curve. // Int. J. Appl. Math. Comput. Sci. 23 (2013); 145-155. 2. Jukić, Dragan; Marković, Darija. On nonlinear weighted errors-in-variables parameter estimation problem in the three-parameter Weibull model. // Appl. Math. Comput. 215 (2010); 3599-3609. 3. Jukić, Dragan; Marković, Darija. Least squares fitting inverse Weibull distribution. // Mathematical Communications 15 (2010); 13-24. 4. Jukić, Dragan; Marković, Darija. On nonlinear weighted total least squares parameter estimation problem for the three-parameter Weibull density. // Applied Mathematical Modelling 34 (2010); 1838-1848. 5. Marković, Darija; Jukić, Dragan; Benšić, Mirta. Nonlinear weighted least squares estimation of a three-parameter Weibull density with a nonparametric start. // J. Comput. Appl. Math. 228 (2009); 304-312. 7. List of other papers: http://bib.irb.hr/lista-radova?autor=246382&lang=EN 8. Last year of election in scientific-educational. scientific, educational or associate title:2011. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10. Work status: Radni odnos na neodređeno vrijeme - puno radno vrijeme 133 1. Name and Surname: prof. dr. sc. Branimir Dukić 2. Name of basic organisation: Ekonomski fakultet u Osijeku 3. E-mail adress: bdukic@efos.hr 4. Adress of private web page: http://oliver.efos.hr/~bdukic/Index.htm 5. Biography : Branimir Dukić was born in Osijek on 15 September 1965. He has been working full-time at the Faculty of Economics in Osijek since 1 November 1998. Foreign languages: English Branimir Dukić completed his primary and secondary school education in Osijek. He graduated from the Faculty of Economics in Osijek in 1989 in the field of economic cybernetics, which was followed by employment at the same institution as junior researcher. In 1993, he obtained his MSc degree in business policies from the Faculty of Economics in Osijek by the thesis entitled “Computer-Based Monitoring of Enterprise Profitability – A Concept”. After completing his junior researcher’s internship, he began to work as the Osijek branch manager for the company OBM d.o.o. Velika Gorica. The responsibilities included organization of wholesale business, but he also participated in designing computer programs and providing accountancy services for the branch and for the company’s business partners. In 1995, he started to work in a privately-owned company dux Mission d.o.o. Osijek as the CEO where he was responsible for programming, business consulting, devising investment programs, accounting, business analysis and auditing. In 1997, he was appointed permanent court expert witness in the area of economic, financial, actuarial and ICT-related disputes at the Municipal Court and the Commercial Court in Osijek. In November 1998, Branimir Dukić returned to the Faculty of Economics in Osijek as an assistant involved in teaching the course Informatics. He obtained his PhD degree from the Faculty of Economics in Osijek on 11 December 2002 by defending his doctoral dissertation entitled “Managing Databases of Marketing Models”. He was appointed senior assistant and then assistant professor in 2003 and 2005, respectively. In 2007, he was appointed assistant research scientist. On 3 June 2008 and on 16 September 2008, he was appointed associate professor and senior research scientist, respectively. On 20 September 2011, Dr. Dukić was appointed full professor. He has worked as a researcher in seven scientific projects financed by the Ministry of Science. He is either the sole author or co-author of 49 scientific papers and 6 textbooks/course materials. Furthermore, he devised a number of computer applications, and authored various expert materials, such as investment programs, expert witness analyses and business-related studies. He regularly attends scientific conferences as a speaker, presenting his research, and continues to explore new areas. 6. List of papers (do 5 izabranih radova): Mesarić, J., Dovedan,,Z., Dukić, B.:Information and Communication Tehnologies in European Research Enviroment, Informatologia (1330-0067) 42 (2009), 3; pp. 209-221 (pregledni rad), Dukić, B., Mesarić, J., Katić, M.: Conceptual Model of Information System Reengineering in Processing Industry of Bread Cereals as an Implication of ERP System Application, Proceedings of 4th International Congress FLOUR-BREAD '07, Osijek, 2007., pp. 118-122. (Referencirano u CABAbstracts.) Dukić, B., Mesarić, J.: Reengineering of accounting information system of companies aimed at creating new knowledge and knowledge management, in Aurer, B., Kermek, D. (Eds.): Conference Proceeding IIS 2004, 15th International Conference on Information and Intelligent Systems, FOI Varaždin, Varaždin 2004., pp. 291-298. Novak, N., Dukić, B.: A Data Model of Information Management System in Croatian Higher 134 Education in the Function of Economic Development and Integration Processes of the Republic of Croatia under Conditions of Digital Economy, in Carrasquero, J. V., Welsch, F., Urrea, C., Tso C-D. (Eds.): Proceedings: Political and Information Systems: Technologies and Applications, PISTA '03, Orlando 2003., pp. 192-196. (Referencirano u ISI proceedings) Dukić, B.: Elimination of Information Gap in Marketing Decision-making, Conference Proceeding of 14th International Conference on Information and Intelligent Systems, IIS 2003, FOI Varaždin, Varaždin 2003., pp. 29-37. 7. List of other papers: http://bib.irb.hr/mzos/lista-radova?autor=170723 8. Last year of election in scientific-educational. scientific, educational or associate title: 2011. 9. Scientific-educational, scientific, educational or associate title: full professor 10. Work status: Honorarni nastavnik (ugovor o djelu). 135 1. Name and Surname: Izv.prof.dr.sc. Gordana Dukić 2. Name of basic organisation: Filozofski fakultet u Osijeku 3. E-mail adress: gdukic@ffos.hr 4. Adress of private web page: http://web.ffos.hr/infoznanosti/mods/nastavnici/?id=257 5. Biography : Gordana Dukić is an associate professor in the Department of Information Sciences at the Faculty of Humanities and Social Sciences, Josip Juraj Strossmayer University of Osijek. She was born on October 31, 1970, in Đakovo, where she finished elementary school and high school, passing all her classes with the highest marks. She graduated in 1995 at the Faculty of Economics in Osijek with an average grade of 4.71/5.00. In 1998, she received her MSc from the same faculty with an average grade of 4.77/5.00. In 2006, she defended her doctoral thesis and received her PhD degree from the Faculty of Economics in Osijek. From March 1995 to March 1996 Gordana Dukić was employed at the Croatian Health Insurance Fund in Osijek where she handled the accounting and legal matters, and participated in the informatization process of health care system. During 1997 she was employed in Fiatslavonija d.o.o. Osijek as an Assistant Executive Director. From 1999 to 2002 she worked for Dux-mission d.o.o. Osijek. In Abacus Osijek she was engaged in organization activities, managing, tuition, statistical research and IT consulting from 2003 to 2008. She joined the Faculty of Humanities and Social Sciences as a senior assistant in 2008. She became an assistant professor in 2010 and an associate professor in 2013. Her research interests include management and organisation, project management, library management, statistics, decision support systems, and quantitative methods. On these topics, she has published more than 50 scientific articles in international journals, conference proceedings, and book chapters. She has worked on several scientific projects, whose results were presented at national and international conferences. She is married and the mother of two children. 6. List of papers (do 5 izabranih radova): 1. Kozina, Goran; Keček, Damira; Dukić, Gordana: Knowledge management at Croatian polytechnics – Assessment of the knowledge transfer process. // Technics Technologies Education Management, 8 (2013), 158-168. 2. Dukić, Darko, Dukić, Gordana, Penny, Kay: Knowledge management and e-learning in higher education: A research study based on students’ perception. // International Journal of Knowledge and Learning, 8, (2012), 313-327. 3. Dukić, Gordana: A decision model for bakery production using a Monte Carlo approach. // Koceva Komlenić, Daliborka (ed.): Proceedings of the 6th International Congress "Flour - Bread '11" / Osijek: University of J.J. Strossmayer in Osijek - Faculty of Food Technology in Osijek (2012), 556-562. 4. Dukić, Darko; Dukić, Gordana; Kozina, Goran: Analysis of students’ ICT usage in the function of Croatian higher education development management. // Technical Gazette, 19 (2012), 273-280. 5. Dukić, Gordana; Turkalj, Davorin; Sesar, Mate: Sustav podrške marketing-odlučivanju baziran na teoriji igara. // Ekonomski vjesnik, 21 (2008), 75-81. 7. List of other papers: http://bib.irb.hr/lista-radova?autor=260082 8. Last year of election in scientific-educational. scientific, educational or associate title: 2013. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10. Work status: Full time. 136 1. Name and Surname: dr.sc. Ivan Soldo, viši asistent 2. Name of basic organisation Department of Mathematics, University of Osijek 3. E-mail adress: isoldo@mathos.hr 4. Adress of private web page: http://www.mathos.hr/~isoldo 5. Biography : Ivan Soldo, senior research assistant at the Department of Mathematics, University of Osijek, was born on March 23, 1982 in Požega. In 1992, he finished four years primary school Antun Kanižlić in Vidovci, and in 1996 primary school Antun Kanižlić in Požega. In 2000. he completed the natural-mathematics high school, also in Požega, and enrolled to study mathematics and computer science at Department of Mathematics, University of Osijek. In February 2005, he graduated and becomes a professor of mathematics and computer science. In November 2005, he enrolled in postgraduate study of mathematics - PhD student at the Department of Mathematics, University of Zagreb. From March 2005 he was employed as an assistant on Department of Mathematics, University of Osijek. He also taught at the College in Vukovar, Faculty of Economics, Faculty of Electrical Engineering, and Department of Physics of University of Osijek. The main area of research interest of Ivan Soldo is number theory, especially Diophantine equations and Diophantine m-tuples over the imaginary quadratic fields. He is active member of the Seminar on Number Theory and Algebra (leaders Andrej Dujella and Ivica Gusić), part of which regularly holds lectures. He has participated in several conferences in Zagreb (Croatia), Graz (Austria), Debrecen and Budapest (Hungary). Since 2009, he works as a technical editor of the international journal Mathematical Communications, and perform the review process for the journal Osječki matematički list. Since 2012, he is a secretary of the Croatian Operational Research Society. On 2nd July, 2012 he finished his PhD with PhD thesis “Some Diophantine problems over the imaginary quadratic fields” created under the supervision of Andrej Dujella. 6. List of papers (do 5 izabranih radova): 1. Dujella, Andrej; Soldo, Ivan. Diophantine quadruples in Z[√ -2]. // Analele Stiintifice ale Universitatii "Ovidius" Constanta Seria Matematica. 18 (2010), 1; 81-98. 2. Soldo, Ivan. On the extensibility of D(-1)-triples {1, b, c} in the ring Z[√ -t], t > 0. // Studia scientiarum mathematicarum Hungarica. 50 (2013) , 3; 296-330. 3. Soldo, Ivan. On the existence of Diophantine quadruples in Z[√ -2]. // Miskolc Mathematical Notes. 14 (2013), 1; 265-277. 4. Soldo, Ivan. D(-1)-triples of the form {1, b, c} in the ring Z[√ -t], t>0. // Bulletin of the Malaysian Mathematical Sciences Society. (2014). 5. Franušić, Zrinka; Soldo, Ivan. The problem of Diophantus for integers of Q[√-3]. // Rad HAZU, Matematičke znanosti. (2014). 7. List of other papers: http://bib.irb.hr/lista-radova?autor=280141&lang=EN 8. Last year of election in scientific-educational. scientific, educational or associate title: 2012. 9. Scientific-educational, scientific, educational or associate title: senior instructor 10. Work status: Full time. 137 1. Name and Surname: Josip Cvenić, prof., viši predavač 2. Name of basic organisation: Department of Mathematics, University of Osijek 3. E-mail adress: jcvenic@mathos.hr 4. Adress of private web page: http://www.mathos.hr/~jcvenic 5. Biography : Josip Cvenić, a higher lecturer on the Department of Mathematics, University of Osijek was born on 10. February 1978. in Osijek. Elementary and high school ended in Valpovo. He graduated in 2002., currently attending postgraduate doctoral studies at the Faculty of Kinesiology in Zagreb, kinesiology education. Since 2001. employed as a teacher of physical education in High school Valpovo. Since 2007. was elected to the teaching position of the lecturer and is employed at the Department of Mathematics, University of J.J. Strossmayer in Osijek. From 2010. was elected to the position of higher lecturer. Area of scientific interests: methodology of physical education - educational tasks, conditional strength, planning and programming teaching physical education in high education. He has published 11 papers in the proceedings of scientific conferences, of which 3 from international scientific conferences. President of the Tennis Club Valpovo and the Society for Sport and Recreation Lifestyle Valpovo, Tennis Association Secretary of Osječko-Baranjska county, national tennis referee and a member of the ZTSH, a handball coach of University J.J. Storssmayer team, organizer of sport workshop Sport Billy in kindergarten, manager of Tennis center Valpovo, ski license and member of HZUTS. 6. List of papers (do 5 izabranih radova): 1. Cvenić, J. (2004.). Utjecaj pohađanja nastave tjelesne i zdravstvene kulture na zaključnu ocjenu na polugodištu. U V. Findak (urednik), Zbornik radova 13. ljetne škole kineziologa Republike Hrvatske, Rovinj, 2004., „Vrednovanje u području edukacije, sporta i sportske rekreacije“,(str. 226-229). Hrvatski kineziološki savez. (prethodno znanstveno priopćenje) 2. Cvenić, J. (2005.). Sports-recreational potential in croatian five-star hotels according to Internet. In D. Milanović i F. Prot (Eds.), Proceedings book of 4th International scientific conference on kinesiology, Opatija, 2005., „Science and profession – challenge for the future“, (pp. 289-292). Faculty of Kinesiology, University of Zagreb, Croatia. 3. Cvenić, J. (2007.). Neke metrijske karakteristike testa za procjenu koordinacije. U V. Findak (urednik), Zbornik radova 16. ljetne škole kineziologa Republike Hrvatske, Poreč, 2007., „Antropološke, metodičke, metodološke i stručne pretpostavke rada u područjima edukacije, sporta, sportske rekreacije i kineziterapije“,(str. 415-419). Hrvatski kineziološki savez. (stručni rad) 4. Cvenić, J. (2008.). The proposal of new grading system of goalkeeper's efficiency in handball. In D. Milanović i F. Prot (Eds.), Proceedings book of 5th International scientific conference on kinesiology, Zagreb, 2008., „Kinesiology research trends and applications“, (pp. 683-687). Faculty of Kinesiology, University of Zagreb, Croatia. 5. Cvenić, J. (2009.). Educational tasks in kinesiological culture. In I. Prskalo, V. Findak, J. Strel (Eds.), Pre-conference proceedings of 3rd Special Focus Symposium, Zadar, 2009., „Kinesiological Education - Heading Towards The Future“,(pp.171-179). Faculty of teacher education, University of Zagreb, Croatia. (Professional paper) 7. List of other papers: http://www.mathos.hr/~jcvenic/publications.html 8. Last year of election in scientific-educational. scientific, educational or associate title: 2011. 9. Scientific-educational, scientific, educational or associate title: senior lecturer 10.Work status: Radni odnos na neodređeno vrijeme - puno radno vrijeme 138 1. Name and Surname: doc.dr.sc. Goran Šmit 2. Name of basic organisation: Department of Chemistry, University of Osijek 3. E-mail adress: gsmit@kemija.unios.hr 4. Adress of private web page: nije evidentirano 5. Biography : Goran Šmit was born on 5 August 1965 in Osijek. He finished primary and secondary school in Osijek. In 1990 he was granted a BSc degree in biology and chemistry from the Faculty of Education in Osijek. In 1997 he obtained his MSc degree at the Faculty of Science in Zagreb and in 2004 his PhD degree at the Faculty of Chemical Engineering and Technology in Zagreb. From September 1990 to August 1992 Dr. Šmit worked as a primary school biology and chemistry teacher. Then he started to work at the Faculty of Education, University of Osijek, as an assistant. In March 2007 he was appointed assistant professor at the Department of Chemistry, University of Osijek. From 2008 to 2010 he was appointed deputy head of the Department of Chemistry, University of Osijek. Dr. Šmit's major research fields of interest are heterogeneous catalysis and low energy nuclear physics. He has published 10 scientific papers in journals cited in the Current Contents. Dr. Šmit is a member of the Croatian Chemical Society, the Croatian Society of Chemical Engineers and the Croatian Radiation Protection Association. 6. List of papers (do 5 izabranih radova): 1. G. Šmit, K. Lázár & M.W.J. Crajé, Influence of Water Vapour on Low-Temperature CO Oxidation over Au/Fe2O3 Catalyst, Croatica Chemica Acta, 80 (2007) 141-145. 2. G. Šmit, N. Strukan, M.W.J. Crajé & K. Lázár, A Comparative Study of CO Adsorption and Oxidation on Au/Fe2O3 Catalysts by FT-IR and DRIFTS Spectroscopies, Journal of Molecular Catalysis A: Chemical 252 (2006) 163-170. 3. G. Šmit, S. Zrnčević & K. Lázár, Adsorption and Low-Temperature Oxidation of CO over Iron Oxides, Journal of Molecular Catalysis A: Chemical 252 (2006) 103-106. 4. V. Radolić, B. Vuković, G. Šmit, D. Stanić & J. Planinić, Radon in the Spas of Croatia, Journal of Environmental Radioactivity 83 (2005) 191-198. 5. G. Šmit, Magnetite and Maghemite as Gold-Supports for Catalyzed CO Oxidation at Low Temperature, Croatica Chemica Acta 76 (2003) 269-271. 7. List of other papers: http://bib.irb.hr/lista-radova?autor=201703&lang=EN 8. Last year of election in scientific-educational. scientific, educational or associate title: 2012. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10. Work status: Radni odnos na neodređeno vrijeme - puno radno vrijeme 139 1. Name and Surname: prof. dr. sc. Tomislav Mrčela 2. Name of basic organisation: Elektrotehnički fakultet 3. E-mail adress: tomislav.mrcela@etfos.hr 4. Adress of private web page: http://www.etfos.unios.hr/fakultet/imenikdjelatnika/tmrcela/znanstveni-radovi 5. Biography : Born: Osijek, 13.10.1956. Graduated: Faculty of Mechanical Engineering and Naval Architecture 03.07.1980. Master's degree: Faculty of Mechanical Engineering and Naval Architecture 1987. Ph. D. Faculty of Mechanical Engineering and Naval Architecture 1998. Employment and duties: 1980 Faculty of Electrical Engineering, University of Osijek, vice dean for professional studies, head of Department. Teaching activity: Basics of constructions, Engineering Graphics, Mechanical constructions, Introduction to AutoCAD. Professional activities: the expert of county court in Osijek, member of HDMT. Scientific activities: the development of metal materials, FSB, Zagreb. Materials subsystem agricultural machinery, ETF, Osijek. Biomechanics of Human Support System in a variety of conditions, MF, Osijek. 6. List of papers (do 5 izabranih radova): 1. Baličević, Pavo; Kozak, Dražan; Mrčela, Tomislav: „Strength of Pressure Vessels with Ellipsoidal Heads“ , Strojniški vestnik (ISSN 0039 – 2480) - Journal of Mechanical Engineering,Vol. 54 (2008) , No. 10; p. 685-692 (članak, znanstveni). 2. Mrčela, Tomislav; Žeželj, Dragan; Panić, Nenad: „Linear Loading Measurement Line for Static torque and its Performance“, Tehnički vjesnik (ISSN 1330 – 3651), Vol. 16 (2009) , No. 2; p. 37-42 (prethodno priopćenje, znanstveni). 3. Mrčela, Tomislav; Opalić, Milan; Kljajin, Milan: „Influence of Low Temperatures on No-Load Power Losses in Worm Gears“, Strojarstvo (ISSN 0562 – 1887), Vol. 51 (2009) ,No 2; 139-142 (prethodno priopćenje, znanstveni). 4. Vladimir, Šišljagić; Savo, Jovanović; Tomislav, Mrčela; Radivoje, Radić; Tatjana, Belovari: “Advantages of Modified Osteosynthesis in Treatment of Osteoporotic Long Bones Fractures – Experimental Model”, Collegium Antropologicum (UDC 572, ISSN 0350-6134) Vol. 34 (2009) No. 4; p. 1125-1132 (članak, znanstveni). 5. Vladimir, Šisljagić; Savo, Jovanovic; Tomislav, Mrčela; Radivoje, Radić; Robert, Selthofer; Milanka Mrčela: “Numerical analysis of standard and modified osteosynthesis in long bone fractures treatment” Collegium Antropologicum. (UDC 572, ISSN 0350-6134) Vol 34 (2010) ; 83-87 (članak, znanstveni). 7. List of other papers: http://bib.irb.hr/mzos/lista-radova?autor=129742 8. Last year of election in scientific-educational. scientific, educational or associate title: 2010. 9. Scientific-educational, scientific, educational or associate title: full professor 10. Work status: Radni odnos na neodređeno vrijeme - puno radno vrijeme 140 1. Name and Surname: doc. dr. sc. Tomislav Marošević 2. Name of basic organisation: Department of Mathematics, University of Osijek 3. E-mail adress: tmarosev@mathos.hr 4. Adress of private web page: http://www.mathos.unios.hr/~tmarosev/ 5. Biography : Tomislav Marošević was born in 1962 in Osijek. He finished primary school and secondary school in Osijek. In 1987 he was granted a BSc degree in mathematics and physics from the Faculty of Education, University of Osijek. In 1994 he obtained his MSc degree and in 1998 his PhD degree (mentor prof.dr.sc. Rudolf Scitovski) in the field of applied and numerical mathematics, both at the Department of Mathematics, University of Zagreb. From 1987 to 1999 he worked as a teaching assistant at Faculty of Electrical Enginering, University of Osijek. In 1999 he was chosen as assistant professor at the Faculty of Electrical Enginering, University of Osijek. Since 2000 he has been being employed (with 50% working time) at the Department of Mathematics, University of Osijek, and since 2005 with full working time. Dr. Marošević's major research field of interest is applied and numerical mathematics. He has published as author or coauthor 22 scientific and professional papers from an area of mathematics in journals and proccedings of scientific conferences. He has taken part as collaborator in four scientific projects which were supported by Ministry of Science of Republic of Croatia. He is a member of the Croatian Mathematical Society, the Croatian Operational Research Society and SIAM (Society for Industrial and Applied Mathematics). 6. List of papers (do 5 izabranih radova): 1. R. Scitovski, T. Marošević, Multiple circle detection based on center-based clustering, Pattern Recognition Letters (2014), to apear 2. T. Marošević, Data clustering for circle detection, Croat. Oper. Res. Rev. 5(2014), 15-24. (http://hrcak.srce.hr/crorr) 3. T. Marošević, K. Sabo and P. Taler, A mathematical model for uniform distribution of voters per constituencies, Croatian Operational Research Review 4(2013), 53-64. (http://hrcak.srce.hr/crorr) 4. T. Marošević and R. Scitovski, An application of a few inequalities among sequences in electoral systems, Applied Mathematics and Computation 194 (2007) 480-485. (http://dx.doi.org/10.1016/j.amc.2007.04.050) 5. D. Jukić, T. Marošević, R. Scitovski, Discrete total L_p-norm approximation problem for the exponential function, Applied Mathematics and Computation 94(1998), 137-143. 7.List of other papers: http://www.mathos.unios.hr/~tmarosev . 8. Last year of election in scientific-educational. scientific, educational or associate title: 2014. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10.Work status: Radni odnos na neodređeno vrijeme - puno radno vrijeme 141 1. Name and Surname: doc. dr. sc. Alfonso Baumgartner 2. Name of basic organisation: Elektrotehnički fakultet 3. E-mail adress: baumgart@etfos.unios.hr 4. Adress of private web page: 5. Biography : Alfonzo Baumgartner was born on the 3rd May 1975. in Doboj, Bosnia and Herzegovina. He graduated in 1999. He got M.Sc. degree in 2003., and a PhD in 2010. at the Faculty of Electrical Engineering in the field of theoretical computer science. He visited the Univ. des Saarlandes (Saarbrücken, 2001 to 2002). Since 1999. employed as an assistant at the Faculty of Electrical Engineering. From 2010. he works as an assistant professor. He has worked on two research projects MSES. 6. List of papers (do 5 izabranih radova): 1. A. Baumgartner, T. Rudec, R. Manger, „The design and analysis of a modified work function algorithm for solving the on-line k-server problem“, Computing and Informatics 29 (2010) , 4; 681-700. 2. G. Martinović, I. Aleksi, A. Baumgartner, “Single-Commodity Vehicle Routing Problem with Pick-up and Delivery Service“, Mathematical Problems in Engineering. 2008 (2008) ; 697981-1-697981-17. 3. T. Rudec, A. Baumgartner, R. Manger, „A fast implementation of the optimal off-line algorithm for solving the k-server problem“, Mathematical communications 14 (2009) , 1; 123-138. 4. A. Baumgartner, R. Manger, Ž. Hocenski, „Work Function Algorithm with a Moving Window for Solving the On-line k-server Problem“, Journal of Computing and Information Technology - CIT. 15 (2007) , 4; 325-330. 5. K. Sabo, A. Baumgartner, „One method for searching the best discrete TL_p approximation“, Mathematical Communications - Supplement. 1 (2001) , 1; 63-68. 7.List of other papers: http://bib.irb.hr/lista-radova?autor=231574&lang=EN 8. Last year of election in scientific-educational. scientific, educational or associate title:2010. 9. Scientific-educational, scientific, educational or associate title: assistant professor 10. Work status: Full time. 142 4.5. List of teaching basis -- 4.6. Optimal number of students The optimal number of students that can be enrolled in terms of space, equipment and number of teachers: 60 4.7. Estimated costs per student The estimated average cost per student for one academic year: KN 24.000,00 4.8. Method of monitoring the quality and performance of a study program The quality and success of the study programme is continuously monitored through a single university student survey at the University level, students' evaluation, evaluations by teachers and field experts, analysis of success in exams,... 143