3D Path Planning of UAV Based on Adaptive Slime Mould Algorithm Optimization

doi:10.16183/j.cnki.jsjtu.2022.191

Abstract

Abstract:

Aimed at the problems of insufficient search range and optimization performance in 3D path planning of unmanned aerial vehicles (UAVs), and the lack of optimization accuracy of the existing slime mould algorithm (SMA), which is easy to fall into local optimization, a 3D path planning method for UAV based on adaptive slime mould algorithm optimization is proposed. First, according to the actual environment that the UAV passes through, the 3D terrain, the threat source and the constraints of the AUV were established. Next, for the problem of insufficient search range, an improved Logistic chaotic map is designed to increase the diversity of the population and expand the search range, which improves the global search ability of SMA. Then, a nonlinear adaptive inertia weight factor is designed to change the linear convergence method into nonlinear convergence, and the weight value is used to update the position of the slime mould, which improves the convergence speed. Finally, in the later stage of the algorithm, the adaptive cauchy mutation is designed, which increases the search space of the slime mould and improves the optimization accuracy. The experimental results show that GSMA has a shorter and smoother path, a faster convergence, a higher optimization accuracy, and a lower energy consumption compared with the gray wolf optimizer (GWO) algorithm, the SMA, and the seagull algorithm (SOA), which further improves the path planning capability of the UAV.

Key words: unmanned aerial vehicle (UAV), path planning, slime mould algorithm (SMA), chaos mapping, adaptive Cauchy variation, adaptive weights

CLC Number:

U666.1

HUANG He, GAO Yongbo, RU Feng, YANG Lan, WANG Huifeng. 3D Path Planning of UAV Based on Adaptive Slime Mould Algorithm Optimization[J]. Journal of Shanghai Jiao Tong University, 2023, 57(10): 1282-1291.

Figures/Tables 10

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测试函数	算法	F_best	F_avg
Rosenbrock	SMA	28.63	28.98
	GWO	28.17	28.34
	SOA	29.67	29.93
	GSMA	27.89	28.15
Schwefel	SMA	-1.22×10⁴	-1.31×10⁴
	GWO	-5.66×10³	-5.61×10³
	SOA	-5.66×10³	-5.66×10³
	GSMA	-1.26×10⁴	-1.32×10⁴
Foxholes	SMA	0.068	0.153 8
	GWO	2.699	2.981
	SOA	0.928	0.563
	GSMA	0.076	0.095
Kowalik	SMA	1.28×10^-3	1.71×10^-3
	GWO	2.04×10^-3	2.43×10^-3
	SOA	2.04×10^-3	2.12×10^-3
	GSMA	6.34×10^-4	6.97×10^-4
Hartman 6	SMA	-3.11	-3.19
	GWO	-3.17	-3.75
	SOA	-2.65	-2.82
	GSMA	-3.16	-3.27
Shekel 10	SMA	-3.75	-3.63
	GWO	-10.50	-10.46
	SOA	-4.87	-4.87
	GSMA	-10.56	-10.53

参数	数值
v/(km·h^-1)	30~40
K_Z	100
K'_Z	100
K_F	100
k_d	0.6
k_g/(km·s^-2)	5
Q_h	10
Q_v	10
a_max	60
β_max	60
K_thr	R_max,_p/3
ω₁	0.23
ω₂	0.45
ω₃	0.2
ω₄	0.12
d	15

算法	航程/km	最优适应度	转弯和爬升角代价	寻优成功率/%
SMA	166.23	30.86	100	76
GWO	159.38	34.09	70	79
SOA	162.17	36.72	120	82
GSMA	133.54	29.43	10	95

算法	航程/km	最优适应度	转弯和爬升角代价	寻优成功率/%
SMA	165.43	27.06	100	85
GWO	163.85	34.37	80	78
SOA	171.65	37.78	90	75
GSMA	139.86	28.89	20	93