Abstract

The paper presents the concept of planning the optimal trajectory of fixed-wing unmanned aerial vehicle (UAV) of a short-range tactical class, whose task is to recognize a set of ground objects as a part of a reconnaissance mission. Tasks carried out by such systems are mainly associated with an aerial reconnaissance using Electro-Optical/Infrared (EO/IR) systems and Synthetic Aperture Radars (SARs) to support military operations. Execution of a professional reconnaissance of the indicated objects requires determining the UAV flight trajectory in the close neighborhood of the target, in order to collect as much interesting information as possible. The paper describes the algorithm for determining UAV flight trajectories, which is tasked with identifying the indicated objectives using the sensors specified in the order. The presence of UAV threatening objects is taken into account. The task of determining the UAV flight trajectory for recognition of the target is a component of the planning process of the tactical class UAV mission, which is also presented in the article. The problem of determining the optimal UAV trajectory has been decomposed into several subproblems: determining the reconnaissance flight method in the vicinity of the currently recognized target depending on the sensor used and the required parameters of the recognition product (photo, film, or SAR scan), determining the initial possible flight trajectory that takes into account potential UAV threats, and planning detailed flight trajectory considering the parameters of the air platform based on the maneuver planning algorithm designed for tactical class platforms. UAV route planning algorithms with time constraints imposed on the implementation of individual tasks were used to solve the task of determining UAV flight trajectories. The problem was formulated in the form of a Mixed Integer Linear Problem (MILP) model. For determining the flight path in the neighborhood of the target, the optimal control algorithm was also presented in the form of a MILP model. The determined trajectory is then corrected based on the construction algorithm for determining real UAV flight segments based on Dubin curves.

Highlights

  • In the literature describing the problems of planning unmanned systems missions, there are theoretical algorithms for determining unmanned aerial vehicle (UAV) flight routes for individualUAVs or UAV swarms that cooperate together

  • This article presents an in-depth analysis of the mission planning method for tactical class fixed-wing UAV and introduces new algorithms related to determining the UAV flight trajectory in the neighborhood of the recognized target

  • This paper presents an improved heuristic algorithm based on Sparse A∗ Search for UAV path planning problem

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Summary

Introduction

In the literature describing the problems of planning unmanned systems missions, there are theoretical algorithms for determining unmanned aerial vehicle (UAV) flight routes for individual. This article presents an in-depth analysis of the mission planning method for tactical class fixed-wing UAV and introduces new algorithms related to determining the UAV flight trajectory in the neighborhood of the recognized target. The article presents the algorithms for planning the detailed flight trajectory of a fixed-wing UAV, which uses EO/IR and SAR for recognition. Based on the definitions introduced by Coutinhoa et al [1], it can be said that the article presents the problem of planning flight routes and determining the UAV flight trajectory operating alone in which a Dubin’s vehicle model has been used. For each of the presented tasks, exemplary results are provided along with examples of recognition materials collected at the designated trajectories

Quality of Reconnaissance Products and NIIRS Scale
NIIRS for EO Camera—CIQE Estimation
Sensor Field of View Calculation
NIIRS for SAR
SAR Scans from a Variable Angle
SAR Continuous Scan Planning
UAV Flight Planning Procedure Using Sensors to Recognize Targets
6: Transform generated path into a feasible trajectories
VRPTW Model Redefinition
Optimal Trajectory Calculation
Trajectory Calculation
Smoothing the Trajectory—UAV Crossing the Waypoint
Smoothing the Trajectory—UAV Crossing a Segment
Mission Plans with Payload Usage
Trajectory Generation and Optimization Function
Conclusions

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