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Main Authors: Chen, Yicheng, Li, Jinjie, Qin, Wenyuan, Hua, Yongzhao, Dong, Xiwang, Li, Qingdong
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2309.10683
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author Chen, Yicheng
Li, Jinjie
Qin, Wenyuan
Hua, Yongzhao
Dong, Xiwang
Li, Qingdong
author_facet Chen, Yicheng
Li, Jinjie
Qin, Wenyuan
Hua, Yongzhao
Dong, Xiwang
Li, Qingdong
contents Autonomous flight in unknown environments requires precise spatial and temporal trajectory planning, often involving computationally expensive nonconvex optimization prone to local optima. To overcome these challenges, we present the Neural-Enhanced Trajectory Planner (NEO-Planner), a novel approach that leverages a Neural Network (NN) Planner to provide informed initial values for trajectory optimization. The NN-Planner is trained on a dataset generated by an expert planner using batch sampling, capturing multimodal trajectory solutions. It learns to predict spatial and temporal parameters for trajectories directly from raw sensor observations. NEO-Planner starts optimization from these predictions, accelerating computation speed while maintaining explainability. Furthermore, we introduce a robust online replanning framework that accommodates planning latency for smooth trajectory tracking. Extensive simulations demonstrate that NEO-Planner reduces optimization iterations by 20%, leading to a 26% decrease in computation time compared with pure optimization-based methods. It maintains trajectory quality comparable to baseline approaches and generalizes well to unseen environments. Real-world experiments validate its effectiveness for autonomous drone navigation in cluttered, unknown environments.
format Preprint
id arxiv_https___arxiv_org_abs_2309_10683
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Learning to Initialize Trajectory Optimization for Vision-Based Autonomous Flight in Unknown Environments
Chen, Yicheng
Li, Jinjie
Qin, Wenyuan
Hua, Yongzhao
Dong, Xiwang
Li, Qingdong
Robotics
Artificial Intelligence
Autonomous flight in unknown environments requires precise spatial and temporal trajectory planning, often involving computationally expensive nonconvex optimization prone to local optima. To overcome these challenges, we present the Neural-Enhanced Trajectory Planner (NEO-Planner), a novel approach that leverages a Neural Network (NN) Planner to provide informed initial values for trajectory optimization. The NN-Planner is trained on a dataset generated by an expert planner using batch sampling, capturing multimodal trajectory solutions. It learns to predict spatial and temporal parameters for trajectories directly from raw sensor observations. NEO-Planner starts optimization from these predictions, accelerating computation speed while maintaining explainability. Furthermore, we introduce a robust online replanning framework that accommodates planning latency for smooth trajectory tracking. Extensive simulations demonstrate that NEO-Planner reduces optimization iterations by 20%, leading to a 26% decrease in computation time compared with pure optimization-based methods. It maintains trajectory quality comparable to baseline approaches and generalizes well to unseen environments. Real-world experiments validate its effectiveness for autonomous drone navigation in cluttered, unknown environments.
title Learning to Initialize Trajectory Optimization for Vision-Based Autonomous Flight in Unknown Environments
topic Robotics
Artificial Intelligence
url https://arxiv.org/abs/2309.10683