基于随机响应面与混沌多项式的鲁棒轨迹优化

doi:10.12305/j.issn.1001-506X.2023.10.27

摘要/Abstract

摘要：

为提升多参数不确定性条件下鲁棒轨迹优化求解技术的通用性和效率, 设计了一种基于随机响应面法与混沌多项式的鲁棒轨迹优化方法。首先, 将非嵌入式混沌多项式与随机响应面法相结合, 引入拉丁超立方采样策略, 构建了具有普适性的多维不确定性量化传播模型, 在实现不确定随机问题有效转化的同时, 保证了问题转化的精度和计算效率; 随后, 将该模型与凸优化方法相结合, 设计了一种基于序列凸优化算法的确定性轨迹优化求解策略, 以实现对该高维确定性优化问题的快速求解; 最终, 以考虑初始状态和过程参数等多参数不确定性的高超声速滑翔轨迹优化问题为例进行了仿真, 并与现有方法进行了对比分析。结果表明, 与传统确定性轨迹优化算法相比, 所提方法可获得兼具可靠性和鲁棒性的高超声速滑翔优化轨迹; 与现有典型鲁棒轨迹优化方法相比, 所提方法具有相当的精度和显著的计算效率优势, 且在不确定性维数增多的情况下, 仍能保证鲁棒轨迹优化生成的高效性和可靠性。

关键词: 不确定性, 鲁棒轨迹优化, 混沌多项式, 随机响应面, 凸优化, 高超声速滑翔

Abstract:

To improve the generality and computational efficiency of robust trajectory optimization technology under multi parameter uncertainty, a robust trajectory optimization method based on stochastic response surface method and polynomial chaos is designed. Firstly, non-intrusive polynomial chaos is combined with stochastic response surface, and a Latin hypercube sampling strategy is introduced to establish a multi-dimensional uncertainty quantification model, which realizes the effective and accurate transformation of the uncertain optimization problem. Secondly, combining the model with the convex optimization method, a trajectory optimization solution strategy based on the sequential convex optimization algorithm is designed to realize the rapid solution of the high-dimensional deterministic optimization problem. Finally, a hypersonic glide trajectory optimization problem considering multi parameter uncertainty such as initial state and process parameters is simulated and compared with the existing methods. The results show that compared with the traditional deterministic trajectory optimization algorithm, the proposed method can obtain the hypersonic glide trajectory with both reliability and robustness. Compared with the existing robust trajectory optimization methods, the proposed method has considerable accuracy and significant computational efficiency, which can ensure the efficiency and reliability of the robust trajectory optimization trajectory generation when the dimension of random variables increases.

Key words: uncertainty, robust trajectory optimization, polynomial chaos, stochastic response surface, convex optimization, hypersonic glide

中图分类号:

V412.44

王培臣, 闫循良, 王宽, 郑雄. 基于随机响应面与混沌多项式的鲁棒轨迹优化[J]. 系统工程与电子技术, 2023, 45(10): 3226-3239.

Peichen WANG, Xunliang YAN, Kuan WANG, Xiong ZHENG. Robust trajectory optimization method based on stochastic response surface and polynomial chaos[J]. Systems Engineering and Electronics, 2023, 45(10): 3226-3239.

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Δ分布类型	正交基函数{ϕ_j(Δ_l)}	概率密度函数
高斯分布	Hermite	$\mathrm{e}^{-\Delta^2 / 2} / \sqrt{2 {\rm{\mathsf{π}}}}$
均匀分布	Legendre	1/2
伽马分布	Laguerre	$\Delta^\alpha \mathrm{e}^{-\Delta} / \varGamma(\alpha+1)$

p	d=3 GQ/SRSM	d=5 GQ/SRSM	d=8 GQ/SRSM
1	8/8	32/12	256/18
2	27/20	243/42	6 561/90
3	64/40	1 024/112	65 536/330

状态量	初始	终端
H/km	80	25
θ/(°)	0	70
ϕ/(°)	0	0
V/(m·s^-1)	6 500	2 000
γ/(°)	0	[-5, 0]
$\psi$/(°)	60	80

不确定参数	符号	分布类型	3σ
大气密度/%	δ_ρ	高斯	15
升力系数/%	δ_{C_L}	高斯	15
阻力系数/%	δ_{C_D}	高斯	15
初始地心距/km	δ_r0	均匀	5
初始经度/(°)	δ_θ0	均匀	0.5
初始纬度/(°)	δ_ϕ0	均匀	0.5
初始倾角/(°)	δ_γ0	均匀	0.5
初始偏角/(°)	δ₀	均匀	0.5

仿真算法	MC	GQ-PC	SRSM-PC
H_μf/km	24.982	25.026	24.967
H_σf/km	0.344	0.338	0.332
θ_μf/(°)	70.032	70.035	70.034
θ_σf/(°)	4.145	4.156	4.153
ϕ_μf/(°)	-0.171	-0.176	-0.175
ϕ_σf/(°)	2.551	2.562	2.567