Journal of Information & Computational Science 11:16 (2014) 5793–5800 Available at
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Journal of Information & Computational Science 11:16 (2014) 5793–5800 Available at
Journal of Information & Computational Science 11:16 (2014) 5793–5800 Available at http://www.joics.com November 1, 2014 Modeling and Optimization of Multiple Launchers and Weapons Fire Distribution Based on Lower Damage Bound Xiaoliang He ∗, Yiming Bi, Zhenxin He The Xi’an Research Institute of High Technology, Xi’an 710025, China Abstract According to the characteristics of multiple launchers and weapons fire distribution, the model of multiple launchers and weapons fire distribution is established, restricted by lower damage bound. Due to Genetic Algorithm (GA) is good at search capability macroscopically, and Simulated Annealing (SA) algorithm is good at seeking the best result microcosmically. Through combining their advantages, a new algorithm is designed and used to solve multiple launchers and weapons fire distribution. Simulation results show that this method could gain the best solution rather quickly, and the fire distribution results fit with the operational requirement well, verify that the model is useful and the algorithm is feasible. Keywords: Fire Distribution; Simulated Annealing; Genetic Algorithm; Multiple Launchers and Weapons 1 Introduction In modern warfare, with the integrated development of weapon system, a single launcher can support multiple types of weapon, which not only save resources, but also improve operational efficiency. In carrying out tasks, the type of weapon is selected to match the target in accordance with the needs of battlefield, in order to achieve the objective of operation. Moreover the fire distribution is an important part of decision-making [1], when multiple launchers and weapons are going to attack the targets; it is mainly that the limited number of weapons and ammunition are assigned to the relevant targets to maximize operational effectiveness, by using a reasonable method of combinatorial optimization. In the field of fire distribution, there is an extensive research literature by domestic and foreign scholars, who mainly focus on model and algorithm. In the study of model, the research results are mostly concentrated in the static model, and the essence of these models is the goal that a single type of weapon maximizes damage to the targets [2]-[5]. However, in the case of multiple launchers and weapons, through combinatorial optimization of them to achieve the best damage, ∗ Corresponding author. Email address: xiaoliang415222902@163.com (Xiaoliang He). 1548–7741 / Copyright © 2014 Binary Information Press DOI: 10.12733/jics20104857 5794 X. He et al. / Journal of Information & Computational Science 11:16 (2014) 5793–5800 the literature which focuses on this kind of problem is relatively less. In the study of algorithm, with the development of artificial intelligence technology, previous classical algorithm has shown insufficient [6]-[9]. Intelligent algorithm brings new ideas for solving. Modeling multiple launchers and weapons fire distribution and developing accurate and efficient intelligent algorithm, are the key point and difficulty in research [10]-[12]. Literature [14] about maximization of the benefitcost ratio established fire distribution model, but the mix of fire units was not considered in the solution process, the practicability of model still need further validation. Literature [15] used Lingo to solve fire distribution problem; for the data was large in scale and variety, it existed the problem which was operated inconveniently and difficult to be mastered. In order to obtain optimal operational effectiveness as a starting point, this paper comprehensively considers the matching relationship between launcher, weapon and target. The fire distribution model is established by the restriction of lower damage bound. In addition, against the large scale of data in the process of solving, GA is good at search capability macroscopically, while SA algorithm is good at seeking the best result microcosmically; a hybrid genetic simulated annealing algorithm combining both advantages is designed for the simulation calculation model; the solving speed and accuracy is also improved. 2 Modeling Multiple Launchers and Weapons Fire Distribution Based on Lower Damage Bound In order to discuss the problem conveniently, the concept of lower damage bound is introduced. Within a specific operational time, one target is attacked by a certain number of weapons. If the damage value is less than β ∈[0, 1], the target can quickly restore fighting capacity; if more than, the fighting capacity cannot be restored in the special operational time. The interval of [β, 1] is called for the effective damage interval, β is the effective lower damage bound. Let the number of launchers is a, the number of weapon’s types supported by the ith launcher is mi , i=1, 2, · · ·, a. There are n targets to attack, the threat coefficient of corresponding target is wk , k=1, 2, · · ·, n. From the j th weapon attached to the ith launcher, Single-shot damage probability is pijk (j=1, 2, · · ·, mi ) to the k th target. Draw into the decision matrix of fire distribution x11 x12 · · · x1n x21 x22 · · · x2n X= ··· xm1 xm2 · · · xmn Among them, xhk represents the∑ fire units to attack the k th target by using the j th weapon attached to the i th launcher; m = mi , h=1, 2, · · ·, m. Then, multiple launchers and weapons fire distribution model can be described as: Look for a set of solutions X, which satisfy the following objective function and constraint conditions. X. He et al. / Journal of Information & Computational Science 11:16 (2014) 5793–5800 Objective function F (X) = n ∑ [ wk 1 − k=1 m ∏ 5795 ] (1 − pijk )xhk (1) h=1 Constraint conditions 1− xhk ∈ Z (2) 0 ≤ pijk ≤ 1 (3) m ∏ (1 − pijk )xhk ≥ βk (4) h=1 Among them, the formula (2) indicates that weapons’ damage on target meets the requirements of the lower damage bound. The formula (3) shows the range of the damage probability on the target by weapon. The formula (4) shows the value of the decision variables from the set of integer Z. As can be seen, multiple launchers and weapons fire distribution is a combinatorial optimization problem. If the amount of launchers and weapons is less, the problem can be solved by some simple mathematical programming methods; but with the scale of solving larger, the classical algorithm cannot give satisfactory results faster, then you can develop efficient intelligent algorithm to solve the problem. 3 Implementation Algorithm GA and SA algorithm are excellent computational methods of modern intelligence. GA is an intelligent heuristic algorithm with inherent parallelism and better global optimization capability, has been widely applied in the field of combinatorial optimization, but there is also easy to converge to a local optimum, more time consuming, poor stability. The calculation process of SA algorithm is simple, better robust, excellent ability to choose better; it fits complex nonlinear optimization problems, meanwhile there are also shortcomings, such as strongly dependent on the original values, sensitive parameters and poor capability of global search for optimal solution. Accordingly, as can be seen that both are highly complementary. Firstly, SA algorithm enables GA more targeted to choose search space, to avoid premature local optimum. Secondly, in the crossover and mutation steps, GA provides new solutions for SA algorithm, enhancing the overall climbing characteristic. Finally, the solutions of SA algorithm provide new population for GA selectively; it improves the convergence rate of GA, so that the hybrid algorithm obtains the global optimal solution within a short time. This paper reasonably embeds SA algorithm in GA, and put forward a new global optimization algorithm, called hybrid genetic simulated annealing (SAGA) algorithm. The SAGA algorithm plays an important role in the process of crossover and mutation for generating new populations, resolves the difficulties of GA parameter selection, improves convergence, and makes the algorithm more advantages. The steps of SAGA algorithm are shown in Fig. 1. In Fig. 1, Tmin is the terminal condition of temperature falling in the process of simulated annealing. (1) Coding 5796 X. He et al. / Journal of Information & Computational Science 11:16 (2014) 5793–5800 Initialize Code: generate initial population Calculate individual fitness Evolution generation increased by 1 Adjust annealing temperature Select, Cross, Mutate Simulated annealing control search N T ≥Tmin Y Best individual fitness Export Fig. 1: SAGA algorithm flow chart Obviously, multiple launchers and weapons fire distribution is an integer programming problem. Here is the decimal coding, more intuitive performance, shorter coding length, simple and practical. Chromosome coding can be expressed as [x1 , x2 , · · ·, xt , · · ·, xm∗n ]. xt is a mathematical description of fire units used the hth weapon against the k th target. The logical relationship between h, k and t can be determined by formula (5); h and k are respectively the number of weapon’s types and targets. { h = ceil(t/n), h = 1, 2, · · · , m If rem(t, n) = 0, k = n (5) k = rem(t, n), k = 1, 2, · · · , n Among them, ceil and rem are respectively the functions in Matlab for integer and remainder. (2) Population initialization Due to the large scale of weapons and targets, the initial solution of population is caused some difficulties. In order to quicken the convergence speed and increase the ability of searching optimization, the initial solution of population adopts the following methods: Step 1 Generate m*n null matrix. Through the function X =zeros(m, n), generate m*n null matrix; m and n are respectively the number of weapon’s types and targets. Step 2 Put one number from randperm(µi ) into the random column of the i th row of matrix X . µi is the maximum number of fire units of the ith weapon, the random column of the ith row is found by the function randperm(n), n is the number of targets. Step 3 Verify the updated matrix X from Step 2 whether meets the lower damage bound to target. If it meets, the matrix X can be used as the initial solution; otherwise, go to Step 1. Calculate the damage probability of each column’s elements to the corresponding target, to obtain the sum of damage probability of each column, and to determine whether the sum satisfies the lower damage bound. Step 4 Have on Steps 1, 2, 3 iteratively until meeting the requirement of initial population. X. He et al. / Journal of Information & Computational Science 11:16 (2014) 5793–5800 5797 By the formula (5), the element of matrix X can correspond to the element’s position on the chromosome. (3) Fitness Fitness is used to calculate the value of each chromosome, judge its quality, to be tradeoffs. In the early GA running, due to the large difference in the fitness of chromosomes, when using roulette selection, the possibility of offspring produced is proportional to the size of parent chromosome fitness; So in the early, the entire population is prone to produce more individual offspring, early to fall into local optimal value. In the late, the fitness of chromosomes tends to consistency; when the good chromosomes produce offspring, there are not obvious advantages, so as to the stagnation phenomenon of the entire population exists. To solve these problems, combining with multiple launchers and weapons fire distribution, the fitness stretching method is used as follows: exp(fi /T ) Fi = M (6) ∑ exp(fi /T ) i=1 Among them, fi is the fitness of the ith chromosome, the objective function can be directly used as the chromosome fitness function. M is the size of population. T is the current temperature. The formula (6) is served as the new fitness function in the algorithm. So early in the GA (high temperature), the probabilities of producing offspring are similar, while the fitness of chromosomes is similar. With the temperature falling, stretching effect highlights, the differences among the similar fitness of chromosomes can be amplified, so that make the advantages of excellent chromosomes more obvious. (4) Selection, crossover and mutation At the selection, adopt the method of roulette, keep chromosomes which have large occurrence probability of fitness. At the crossover, randomly select parent chromosomes needed to be crossed, use multi-point crossover way to select individuals, for offspring chromosomes, to ensure the diversity of population. If appear the same weapon to two targets at the same time, this kind of crossover result is illegal. At this point, adopt Zeros method to eliminate illegal distribution, that is 0 in place of xt , make the distribution legalized. At the mutation, randomly find multiple non-zero points on the chromosome, make them randomly variation within the largest amount of fire units of the corresponding weapon; it can jump out of local search, accurately determine the optimal solution. (5) Simulated annealing control search SA algorithm has strong ability of local optimum, which can effectively avoid the GA into local extremum, eventually reach a global optimization. In order to ensure the organic combination of GA and SA algorithm, to complement each other, during the crossover and mutation operations, this paper uses simulated annealing to control the search. The specific steps are as follows: Step 1 Crossover and simulated annealing. According to certain conditions, Genes a1 and a2 generate offspring c1 and c2 ; calculate the fitness f (ai ) and f (ci ), i=1, 2. If f (ci )≤f (ai ), ci takes the place of ai ; if not, accept ci with the probability of exp(- (f (ci ) - f (ai ))/T ). Step 2 Mutation and simulated annealing. The same way is with Step 1. Step 3 Temperature falling. T = T0 × α, α is a constant in [0, 1]. 5798 X. He et al. / Journal of Information & Computational Science 11:16 (2014) 5793–5800 Step 4 Judge termination condition of algorithm. T ≥ Tmin , if meet the termination condition, output the optimal solution, the algorithm is over; otherwise, turn to Step 1. 4 Simulation Application To test the performance of SAGA algorithm to deal with multiple launchers and weapons fire distribution problem, the following scenario data is introduced. Let there are three launchers L1 -L3 , the number of weapon’s types each launcher supports and fire units are shown in Table 1. There are ten main targets T1 -T10 , the damage probability of weapon to target and threat coefficient of target are shown in Table 2. Table 1: The scale of launchers and weapons Launcher Types of weapon Fire units L1 2 [3 3] L2 3 [2 4 2] L3 3 [4 5 2] Table 2: The damage probability and threat degree of target Targets T1 T2 T3 T4 T5 T6 T7 T8 T9 T10 T hreat 0.25 0.06 0.10 0.03 0.13 0.08 0.01 0.18 0.07 0.09 ML1−1 0.20 0.33 0.25 0.31 0.23 0.27 0.38 0.23 0.35 0.31 ML1−2 0.32 0.40 0.31 0.40 0.29 0.35 0.49 0.27 0.48 0.43 ML2−1 0.26 0.35 0.27 0.32 0.33 0.40 0.52 0.26 0.42 0.40 ML2−2 0.35 0.47 0.34 0.45 0.40 0.52 0.64 0.38 0.53 0.54 ML2−3 0.44 0.69 0.52 0.56 0.50 0.66 0.70 0.42 0.64 0.65 ML3−1 0.33 0.65 0.43 0.54 0.45 0.50 0.66 0.40 0.58 0.51 ML3−2 0.40 0.71 0.57 0.69 0.51 0.60 0.72 0.51 0.66 0.62 ML3−3 0.56 0.80 0.68 0.77 0.62 0.73 0.85 0.63 0.82 0.71 In Table 2, ML1−1 -ML3−3 are respectively corresponding to the types of weapon supported by L1 -L3 . Before the simulation, it is still to set some parameters; give the lower damage bound all as β=0.8; set GA parameters, give the size of initial population N =100, crossover probability pc =0.8, mutation probability pm =0.1; set SA algorithm parameters, give the initial temperature T0 =100, temperature falling coefficient α=0.99, terminal condition Tmin =5. This paper adopts Matlab to simulate and calculate, the number of iterations is 300, and the results are shown in Fig. 2 and Table 3. As can be seen from Fig. 2, SAGA algorithm has better convergence performance, can quickly find the optimal solution; the objective function value converges to 0.81, that is the fire distribution may destroy the enemy’s target threat by 0.81. As can be seen from Table 3, the launchers concentrate fire units on the target with greater threat, and combine different launchers’ weapons to strike on the same target, to meet the lower damage bound for maximum damage. The calculation results show the fire distribution plan not only meets the operational requirement, but also largely destroys the threat of enemy targets, can provide a viable reference for relevant operational units. X. He et al. / Journal of Information & Computational Science 11:16 (2014) 5793–5800 5799 Fitness curve termination=300 0.9 0.8 Fitness 0.7 0.6 0.5 0.4 SAGA GA SA 0.3 0.2 0 50 100 150 200 Iteration 250 300 350 Fig. 2: Algorithm performance comparison Table 3: The fire distribution result Damages targets Launchers W eapons T2 T3 T5 T8 T10 L2 +L3 L1 +L2 L3 L2 L3 L1 ML1−3 : 2+ML3−2 : 3 ML1−1 : 3+ML2−1 : 2 ML3−1 : 3 ML2−2 : 4 ML3−3 : 2 ML1−2 : 3 Damageprobability 5 T1 0.93 0.92 0.89 0.87 0.86 0.81 Conclusion The problem of multiple launchers and weapons fire distribution is a complex system engineering, needs to consider many factors, involves broad areas. According to this characteristic, this paper establishes the model of multiple launchers and weapons based on SAGA algorithm; on the basis of the previous maximum damage to target, the model adds in the factor of lower damage bound, and put forward SAGA algorithm to solve the problem. Algorithm effectively combines the intelligent algorithm and simulated annealing algorithm, has rapid convergence and excellent optimization ability. The simulation results show that the built model is ingenious about combining operational mission with effective damage to target, reflects the need of real battlefield, high credibility. Development of the algorithm is simple and reasonable, easy to realize the global optimization, easy to promote. References [1] Z. X. Wang, L. Chen, Implementation of three shooting modes for distributed fire control system of antiaircraft gun [J], Acta Armamentarii, 32(7), 2011, 795-800 [2] H. Cai, J. Liu, Y. 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