A Novel Real-Time Penetration Path Planning Algorithm for Stealth UAV in 3D Complex Dynamic Environment

Zhe Zhang,Jiyang Dai,Cheng He,Jian Wu

doi:10.1109/access.2020.3007496

Zhe Zhang, Jiyang Dai + Show 2 more

Open Access

https://doi.org/10.1109/access.2020.3007496

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Journal: IEEE Access	Publication Date: Jan 1, 2020
Citations: 60	License type: CC BY 4.0

Affiliation: Nanchang Hangkong University, Beihang University

Abstract

In recent years, stealth aircraft penetration path planning has been a significant research subject in the field of low altitude combat. However, previous works have mainly concentrated on the path planning for stealth unmanned aerial vehicle(UAV) in 2D static environment. In contrast, this paper addresses a novel real-time path planning algorithm for stealth UAV to realize the rapid penetration, which aims to devise a route penetration strategy based on the improved A-Star algorithm to address the problems of replanning for stealth UAV in 3D complex dynamic environment. The proposed method introduces the kinematic model of stealth UAV and detection performance of netted radar in the process of low altitude penetration. Additionally, POP-UP threats are adopted into three different threat scenarios, which is closer to the real combat environment. Moreover, further combined with the prediction technique and route planning algorithm, the multi-step search strategy is developed for stealth UAV to deal with POP-UP threats and complete the replanning of the route in different scenarios. Furthermore, the attitude angle information is integrated into the improved A-Star algorithm, which reflects the characteristics of the dynamic radar cross section(RCS) and conforms to the actual flight requirements for the stealth UAV. Finally, the improved A-Star algorithm, the sparse A-Star search (SAS), and the dynamic A-Star algorithm(D-Star) are respectively adopted to address the problem of penetration route planning for stealth UAV in three different threat scenarios. Numerical simulations are performed to illustrate that the proposed approach can achieve rapid penetration route planning for stealth UAV in a dynamic threat scenario, and verify the validity of the improved A-Star algorithm which is compared to the other two algorithms

Highlights

With the development and application of high-tech military equipment, stealth technology has been applied in modern air warfare [1]–[3]
NUMERICAL RESULTS Numerical simulations of penetration route planning are performed by the improved A-Star algorithm, Sparse A-Star Search algorithm, and D-Star algorithm in different threat scenarios, which aims to verify the validity of the improved A-Star algorithm
An improved A-Star algorithm based on a multi-step search strategy is designed by model-based predictive control and the A-Star algorithm

Summary

Introduction

With the development and application of high-tech military equipment, stealth technology has been applied in modern air warfare [1]–[3]. Many countries are actively applying stealth technology to equipment and weapons, such as stealth aircraft and stealth missiles. The survivability and combat capability of aircraft will play a crucial role in warfare [4], [5]. There are many theoretical challenges and practical problems in the penetration path planning technology of stealth UAV, such as the complexity of the combat environment, the constraints of attitude, and control of stealth UAV, the efficiency of the route planning algorithm, optimal and real-time performance of the routes.

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Results

Conclusion