Multimedia and Sense

Transcription

Multimedia and Sense
Multimedia and Sense
Sense of
Mode of Sense
vision
hear
smell
taste
balance
"5−Sense"
visual
auditory
olifactive
gustatorisch
vestibulär
pressure
vibration
cold
warmth
pain
skin
touch
tactil
position
power
Propriorezeptoren
kinesthetic
Display
optical
accoustic
−
−
−
haptic
[additional information]
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Multimedia and Sense
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Videos about our senses
Videos taken from TV: "nano", 3sat:
(language: german)
• sehen
• hören
• riechen
• tasten
• schmecken
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Videos about our senses
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Environment − Perception
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Environment − Perception
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Environment mediated by media
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Environment mediated by media
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General Assumption
The precondition to realize multimedia systems is, that the environmental signals can be digitized:
Example:
The voice signal in the telephone system is limited to
4000 Hertz. With a sampling rate of 8000 (125µs) and
8 bit per sample we have 64 Kbit/s
Nyquist Theorem
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General Assumption
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Enabling Multimedia
• Not all signals of the real environment have to be reproduced.
♦ only those signals which cause the same perception in the sense organs as the original signals
must be reproduced.
• Limited resolution of the human sensory system
♦ artificial signals only have to be transmitted in a proper resolution.
• The systems of senses is widely modular.
♦ e.g.: Text needs only a picture; Speaker needs voice and pictures
• Limitation of intensity
♦ Stimulus crossing a certain limit of intensity cause damage
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Enabling Multimedia
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Limitations of sense organs
All human sensory systems have limited spectrum of perception. Signals beyond this spectrum can´t be
perceived or lead to damage of the sense organ.
Examples:
• Audio:
Sound between 20 and 20000 Hertz
• Visual:
Electromagnetic waves between 380 and 720 nm
• Vibration:
oscillations between 10 and 500 Hertz
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Limitations of sense organs
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Sense of Vision
The interior of the eyeball is covered with photosensitive cells known as the retina.
The cells, known as rods and cones, form the layer of cells at the back of the retina.
The backward−design of the retina results in the so−called blindspot.
Rods (110−125 Mio.) are sensitive to very low levels of illumination and are responsible for our ability to see in
dim light (scotopic vision). They contain a pigment with a maximum sensitivity at about 510 nm, in the green
part of the spectrum. Scotopic vision is completely lacking in color.
Color vision is provided by the cones (photopic vision) (5−7 Mio.), of which there are three distinct classes
with absorptions at about 430, 530, and 560 nm.
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Sense of Vision
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Range of visibility
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Range of visibility
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Dynamic of see sense
Candela per square meter
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Dynamic of see sense
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Chromatic Aberration (1)
refraction power of the eye
wavelength (nm)
687
656
reference point−−> 589
527
486
431
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color description
dark red
medium red
yellow
yellow−green
blue
blue−violet
Chromatic Aberration (1)
refraction difference
+ 0.34 <−−
+0.25
can not be
0
fokused
−0.30
simultaneously
−0.58
−1.07 <−−
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Chromatic Aberration (2)
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Chromatic Aberration (2)
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Sense of Hearing
• 16.000 receptors (hair cells) in a human cochlea
♦ 3500 inner cells
♦ 12000 – 20000 outer hair cells
• Hearing range 20 Hz to 20000 Hz
• Number of fibers in auditory nerve 28000
• Detection threshold 10–12 W/m2
♦ Dynamic range 120 dB (12 orders of
magnitude)
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Sense of Hearing
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Human Aural Properties
Human ear can detect sounds between ~20Hz and 20kHz:
• Total audio range: 5Hz − 50 kHz
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Human Aural Properties
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Limitations of audio−frequencies
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Limitations of audio−frequencies
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Dynamic of hearing
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Dynamic of hearing
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Decibel
The decibel (dB) is a common unit of measurement for the relative loudness of a sound or, in electronics, for
the relative difference between two power levels.
• In sound, decibels measure a scale from the threshold of human hearing, 0 dB, upward towards the
threshold of pain, about 120−140 dB.
• I := 2*I0 −> 3 db
• I := 10*I0 −> 10 db
• I := 100*I0 −> 20 db
• I := 1012*I0 −> 120 db
[What is a decibel]
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Decibel
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The Physics of Acoustics
Sound can be considered in one of two ways:
• In the time domain
• In the frequency domain
• Transformation is accomplished by a Fourier transform
Fourier:
• Any waveform can be created by a series of sine waves summed together
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The Physics of Acoustics
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Sense of Smell
Electronic Nose
• Analysis of smells
• Synthesis of smells
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Sense of Smell
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The fragrance of the Internet
The Ruetz company together with France Telecom will develop a device which will extend the audio−visual
experience in cinema or even in the internet by a smelling component.
The prototype has 64 fragrances which can be changed for special events. A future device can be attached to
the PC and is equipped with fragrance−chips, which can be adopted to the individual demands.
The Sniffman consist of different fragrance−chambers and a heating−chamber. From the heating−chamber
the fragrance will reach the nose.
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The fragrance of the Internet
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Sense of Taste
Fungiform papillae are located on the most
Circumvallate papillae are sunken papillae, with a trough
anterior part of the tongue and generally contain separating them from surrounding wall. They confer a
one to several taste buds per papilla. They appear sour/bitter sensitivity to the posterior 2/3 of the tongue.
as red spots on the tongue.
Foliate papillae are situated on the edge of the
tongue slightly anterior of the circumvallate line.
They are predominantly sensitive to sour tastes.
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Sense of Taste
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Sense of Touch
The mechanics of electronic touch devices are neither purely
electronic nor simply mechanical. They're both. As
electro−mechanical devices, they translate digital information into
physical sensations. For example, when you push on a mouse or
a joystick, the device pushes back—using magnetic actuators
and sensors built into the device.
Technically speaking, this process is called force feedback. And
resistance is only one of the hundreds of sensations like springs,
liquids, textures, vibrations and so on. One can simulate the
sensation, as long as it can be translated into a mathematical
equation.
http://www.immersion.com/
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Sense of Touch
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Vibration thresholds
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Vibration thresholds
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Additional Information (1)
MIT encyclopedia of cognitive science
http://cognet.mit.edu/
Mark Newbold's Animated Necker Cube
http://dogfeathers.com/java/necker.html
Visual Cognition Demonstrations
http://www.viscog.net/demos.html
Perception
http://psych.la.psu.edu/clip/Perception.htm
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Additional Information (1)
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Additional Information (2)
Your Sense of Hearing
http://tqjunior.thinkquest.org/3750/hear/hear.html
The Human Body's Senses: Hearing Theme Page
http://www.cln.org/themes/hearing.html
The Human Body's Senses: Sight Theme Page
http://www.cln.org/themes/sight.html
The Human Body's Senses: Smell Theme Page
http://www.cln.org/themes/smell.html
The Human Body's Senses: Taste Theme Page
http://www.cln.org/themes/taste.html
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Additional Information (2)
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Additional Information (3)
The Human Body's Senses: Touch Theme Page
http://www.cln.org/themes/touch.html
That's Tasty
http://faculty.washington.edu/chudler/tasty.html
ARTIFICIAL RETINAS
http://www.optobionics.com/
TOUCHING.....
http://sln.fi.edu/qa97/me10/me10.html
Introduction to the Skin
http://www.meddean.luc.edu/lumen/MedEd/medicine/dermatology/
skinlsn/skini.htm
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Additional Information (3)
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Additional Information (4)
Retina Reference
http://retina.anatomy.upenn.edu/~lance/retina/retina.html
Artificial hearing
http://www.allhear.com/monographs/m−96−htm.html
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Additional Information (4)
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