Optimizing energy expenditure in agricultural autonomous ground vehicles through a GPU-accelerated particle swarm optimization-artificial neural network framework

Ambuj, Rajendra Machavaram
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Abstract

The accurate energy consumption prediction in Agricultural Ground Vehicles (AGVs) holds immense potential for optimizing operational efficiency and minimizing environmental impact. However, existing optimization methods for such prediction tasks often suffer from high computational demands, hindering their practical implementation. This paper introduces a ground-breaking approach that overcomes this limitation by leveraging the potent computational power of Graphics Processing Units (GPUs) to accelerate the optimization process dramatically. We propose a novel adaptation of the Particle Swarm Optimization (PSO) algorithm, specifically tailored to the intricate multi-objective challenges of AGV energy prediction. This framework harnesses the strengths of a multi-objective approach, enabling the simultaneous optimization of prediction accuracy and model complexity. To further enhance efficiency, we seamlessly integrate GPU parallelization techniques, significantly expediting both the optimization process and the training of Artificial Neural Networks (ANNs) employed for prediction. Preliminary results demonstrate a remarkable improvement in the accuracy of AGV energy consumption predictions, directly attributed to the synergistic effect of optimizing the ANN architecture and parameters through our proposed PSO framework. This tailored PSO adaptation distinguishes itself by its ability to tackle the complex multi-objective nature of AGV energy prediction with enhanced efficiency and precision. It thus emerges as a compelling and novel solution within the realm of Machine Learning and heuristic methods for agricultural robotics, paving the way for sustainable and optimal AGV operations.

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通过 GPU 加速的粒子群优化-人工神经网络框架优化农业自主地面车辆的能源消耗
准确预测农业地面车辆(AGV)的能耗对于优化运行效率和减少对环境的影响具有巨大潜力。然而,用于此类预测任务的现有优化方法往往存在计算量大的问题,阻碍了其实际应用。本文介绍了一种突破性的方法,它利用图形处理器(GPU)强大的计算能力显著加快了优化过程,从而克服了这一限制。我们提出了一种新颖的粒子群优化(PSO)算法,专门针对 AGV 能量预测所面临的错综复杂的多目标挑战而量身定制。该框架利用了多目标方法的优势,能够同时优化预测准确性和模型复杂性。为了进一步提高效率,我们无缝集成了 GPU 并行化技术,大大加快了优化过程和用于预测的人工神经网络(ANN)的训练。初步结果表明,AGV 能耗预测的准确性有了显著提高,这直接归功于通过我们提出的 PSO 框架优化人工神经网络架构和参数的协同效应。这种量身定制的 PSO 适应性因其能够以更高的效率和精度解决 AGV 能量预测的复杂多目标特性而与众不同。因此,它是机器学习领域和农业机器人启发式方法中一个引人注目的新颖解决方案,为实现可持续的最佳 AGV 运营铺平了道路。
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