轴向力飞行器修正比例导引律与过载需求研究

doi:10.12305/j.issn.1001-506X.2026.01.29

Abstract

Abstract:

Axial force aircraft can provide greater available overload, offering an effective technical method for intercepting maneuvering targets. When the target’s maneuvering form is unknown but its maneuvering capability is bounded, determining the required axial overload for the aircraft becomes a crucial issue in the aircraft overall design. Firstly, considering the aircraft’s attitude constraints, we derive the axial force aircraft’s modified proportional guidance law for intercepting maneuvering targets, demonstrating that line-of-sight rate converges within a finite time. Secondly, based on the obtained guidance law, an analytical solution for the aircraft’s axial overload requirement when the target’s maneuvering form is unknown and its maneuvering magnitude is bounded. By considering the target’s maneuvering capability, the remaining flight time during target maneuvering, and the miss distance, we can determine the aircraft’s axial overload requirement. Then, we derive an analytical expression for the aircraft’s axial overload requirement in the presence of system time delay. If the target performs evasive maneuvers with limited remaining flight time, system time delay significantly increases the aircraft’s axial overload requirement. Finally, numerical simulations demonstrate that the proposed guidance law can achieve target impact under direct collision conditions when the derived axial overload requirement is satisfied; however, this requirement increases significantly if the target executes an evasive maneuver with a short time-to-go.

Key words: axial force aircraft, modified proportional guidance, Lyapunov method, axial overload, system time delay

CLC Number:

V 448.23

Bowei ZHOU, Junyan XU. Research on modified proportional guidance laws and overload requirements for axial force aircraft[J]. Systems Engineering and Electronics, 2026, 48(1): 331-341.

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飞行器与目标参数	初值
飞行器初速度/（m/s）	2000
目标初速度/（m/s）	3000
飞行器初始位置/km	（0,0）
目标初始位置/km	（50,0）
飞行器弹道倾角/（°）	160
目标弹道倾角/（°）	20

飞行器轴向过载	脱靶量/m	命中时间/s
6.0 g	236.062	−
6.5 g	0.001	11.27
7.0 g	0.001	9.89

飞行器轴向过载	脱靶量/m	命中时间/s
10.0g	3193.2	−
16.5g	0.001	11.27
20.0g	0.002	9.89

飞行器轴向过载	脱靶量/m	命中时间/s
10.0g	6.35	−
16.5g	0.001	9.59
20.0g	0.003	9.21

飞行器轴向过载	脱靶量/m
10.9g	9.833
43.6g	0.004

Research on modified proportional guidance laws and overload requirements for axial force aircraft

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