Expanding Ground Vehicle Autonomy into Unstructured, Off-Road Environments: Dataset Challenges

Q1 Mathematics

Applied Sciences Pub Date : 2024-09-18 DOI:10.3390/app14188410

Stanton R. Price, Haley B. Land, Samantha S. Carley, Steven R. Price, Stephanie J. Price, Joshua R. Fairley

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引用次数: 0

Abstract

As with the broad field of deep learning, autonomy is a research topic that has experienced a heavy explosion in attention from both the scientific and commercial industries due to its potential for the advancement of humanity in many cross-cutting disciplines. Recent advancements in computer vision-based autonomy has highlighted the potential for the realization of increasingly sophisticated autonomous ground vehicles for both commercial and non-traditional applications, such as grocery delivery. Part of the success of these technologies has been a boon in the abundance of training data that is available for training the autonomous behaviors associated with their autonomy software. These data abundance advantage is quickly diminished when an application moves from structured environments, i.e., well-defined city road networks, highways, street signage, etc., into unstructured environments, i.e., cross-country, off-road, non-traditional terrains. Herein, we aim to present insights, from a dataset perspective, into how the scientific community can begin to expand autonomy into unstructured environments, while highlighting some of the key challenges that are presented with such a dynamic and ever-changing environment. Finally, a foundation is laid for the creation of a robust off-road dataset being developed by the Engineer Research and Development Center and Mississippi State University’s Center for Advanced Vehicular Systems.

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将地面车辆自主性扩展到非结构化、非公路环境：数据集挑战

与广泛的深度学习领域一样，自动驾驶也是一个研究课题，由于其在许多交叉学科中推动人类进步的潜力，它受到了科学界和商业界的极大关注。基于计算机视觉的自动驾驶技术的最新进展凸显了在商业和非传统应用领域（如杂货配送）实现日益复杂的自动驾驶地面车辆的潜力。这些技术的成功部分得益于丰富的训练数据，这些数据可用于训练与自主软件相关的自主行为。当应用从结构化环境（即定义明确的城市路网、高速公路、街道标识等）转入非结构化环境（即越野、非公路、非传统地形）时，这些数据丰富的优势很快就会被削弱。在此，我们旨在从数据集的角度，深入探讨科学界如何开始将自主性扩展到非结构化环境，同时强调这种动态和不断变化的环境所带来的一些关键挑战。最后，为工程师研发中心和密西西比州立大学先进车辆系统中心正在开发的强大越野数据集的创建奠定了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Applied Sciences Mathematics-Applied Mathematics

CiteScore

6.40

自引率

0.00%

发文量

审稿时长

11 weeks

期刊介绍： APPS is an international journal. APPS covers a wide spectrum of pure and applied mathematics in science and technology, promoting especially papers presented at Carpato-Balkan meetings. The Editorial Board of APPS takes a very active role in selecting and refereeing papers, ensuring the best quality of contemporary mathematics and its applications. APPS is abstracted in Zentralblatt für Mathematik. The APPS journal uses Double blind peer review.