基于矩阵博弈的智能水声对抗建模与仿真

doi:10.16182/j.issn1004731x.joss.24-0044

摘要/Abstract

摘要：

鱼雷对水面战舰构成了巨大的威胁，需要高效的水声对抗系统来实时输出适应各种对抗场景的策略。提出了一种基于博弈论的智能对抗策略，通过离散化双方的战略空间，建立了一个博弈模型，其中支付由攻击鱼雷的捕获概率决定。进一步开发了一种改进的单纯形法算法，以获得博弈模型的混合策略纳什均衡。这种均衡可以提供优选的规避策略，以最大程度地降低被攻击鱼雷捕获的风险。基于优选对抗策略的概率观点，可以确定悬浮式声诱饵的投放策略，并同时确定水面战舰的规避轨迹。数值模拟结果表明，所提出的方法可以实时生成智能对抗策略，从而提高水面战舰在反鱼雷水声对抗场景中的生存率。

关键词: 水声对抗, 高斯分布, 博弈论, 线性规划, 单纯形法

Abstract:

Due to the great threat of torpedo against surface warships, an efficient hydroacoustic countermeasure system must output real-time strategies to accommodate varied antagonizing scenarios. Aiming at the decision-making problem in the anti-torpedo hydroacoustic countermeasure cases, an intelligent adversarial strategy is proposed based on the game theory. By discretizing the strategy space of both sides, a matrix game model is established where the payoff is characterised by the capture probability of attacking torpedo. An improved simplex algorithm is then developed to get the mixed-strategy Nash equilibrium of the game model, which can be used to obtain preferred avoidance strategies to minimize the risk of being captured by the attacking torpedo. Based on the probabilistic view of the preferred adversarial strategy, the launching strategy of the floating acoustic decoy can be achieved, and the evasion trajectory of warship can be confirmed simultaneously. Numerical simulation results demonstrate that the proposed method can generate real-time intelligent antagonizing strategy, and consequently, which can improve the survival rate of surface warships in the of anti-torpedo countermeasure scenarios.

Key words: underwater acoustic antagonizing, Gaussian distribution, game theory, linear programming, simplex method

中图分类号:

TP391.9

赵慧瑾,陈彧 . 基于矩阵博弈的智能水声对抗建模与仿真[J]. 系统仿真学报, 2025, 37(5): 1329-1342.

Zhao Huijin,Chen Yu . Modeling and Simulation of Intelligent Underwater Acoustic Countermeasure Based on the Matrix Game[J]. Journal of System Simulation, 2025, 37(5): 1329-1342.

图/表 11

图1

图2

图3

图4

图5

图6

表1

参数设置

序号	主要参数^{[18, 29]}	值	含义
1	$v w / k n$	18	舰艇直行航速
2	$θ m a x / (°)$	35	舰艇最大规避角度
3	$t M 1 / s$	30	舰艇系统反应时间
4	$r m / m$	200	舰艇圆周运动半径
5	$w m / (r a d / s)$	2	舰艇圆周运动角速度
6	$v r / k n$	50	鱼雷直行航速
7	$L m a x / m$	1 500	鱼雷自导扇面半径
8	$λ / (°)$	90	鱼雷自导扇面角
9	$r t / m$	300	鱼雷圆周运动半径
10	$w t / (r a d / s)$	2	鱼雷圆周运动角速度
11	$D L / m$	300	鱼雷识别目标阈值
12	$T M / s$	210	鱼雷总航程所用时间
13	$q / (°)$	30	初始位置鱼雷所在舰艇方位角
14	$d 0 / C a b$	28	鱼雷-舰艇初始位置距离
15	$σ x / m$	150	$x$ 轴方向标准误差
16	$σ y / m$	150	$y$ 轴方向标准误差
17	$D r, m a x / m$	3 680	声诱饵最远投放距离
18	$v m / (m / s)$	400	舰艇圆周运动线速度
19	$v t / (m / s)$	600	鱼雷圆周运动线速度

表1

表2

水声对抗各阶段结束时数值

舰艇

坐标/m

舰艇

航向/(°)

鱼雷

坐标/m

鱼雷

航向/(°)

鱼雷中线方向与鱼雷-舰艇连线的夹角/(°)

鱼雷-舰艇

的距离/m

声诱饵

布放坐标/m

第一阶段：经系统反应时间结束时

$M 1 = (181.26,$

$84.52)$

C M 1 = 95

$T 1 = (2 150.57,$

$3 859.30)$

C T 0 = 215

B θ = 7.5

d t = 4 257.6

$P = (1 873.65,$

$3 352.28)$

第二阶段：鱼雷检测到声诱饵为假时

$M 2 = (358.7,$

$- 69.73)$

C M 2 = 257

$T 2 = (1 820.72,$

$1 962.49)$

C T 2 = 170

B θ = 45.35

d t = 2 785.78

第三阶段：鱼雷做圆周运动航程耗尽时

$M 3 = (- 228.53,$

$- 386.71)$

C M 3 = - 100

$T 3 = (2 196.99,$

$1 725.67)$

C T 3 = 170

B θ = 73.52

d t = 3 216.41

表2

表3

水声对抗双方数据信息

编队

报警

舰艇

鱼雷报警

舷角 $q$ /(°)

鱼雷报警

距离 $d$ /Cab

鱼雷攻击

目标

舰队方

策略 $θ$ /(°)

鱼雷方

策略 $ϕ$ /(°)

声诱饵

坐标 $P$ /m

2舰编队

1号舰

32

20

1号舰

35

25

(503.9,2 075.9)

3舰编队

2号舰

30

30

2号舰

15

10

(5 214.72,9 350.67)

4舰编队

2号舰

40

30

2号舰

- 25

20

(5 505.33,3 797.98)

表3

图7

表4

随机鱼雷来袭方位的舰队规避成功率

报警舷角	2舰编队	3舰编队	4舰编队
$0 ~ 100$ °	$99$	$98$	$98$
$0 ~ 120$ °	$95$	$92$	$97$
$0 ~ 140$ °	$90$	$85$	$90$
$0 ~ 170$ °	$75$	$74$	$90$

表4

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