Optimization Design and Energy Efficiency Management of Robot Power Systems

Chenrui Hu

doi:10.54097/va1sr570

Authors

Chenrui Hu

DOI:

https://doi.org/10.54097/va1sr570

Keywords:

Robot Power Systems; Energy Efficiency; Optimization Design; Battery Technology; Power Management.

Abstract

This comprehensive review explores the critical field of robot power systems, focusing on optimization design principles and energy efficiency management strategies. The article examines the fundamental components of robot power systems, including power sources, distribution networks, and energy storage solutions. It delves into key optimization techniques, such as power source selection, thermal management, and weight reduction, while also discussing advanced energy efficiency management strategies like power-aware task planning and dynamic power management. The review highlights emerging technologies in the field, including next-generation batteries, energy harvesting techniques, and AI-driven power management. Additionally, it addresses current challenges and future research directions, emphasizing the interdisciplinary nature of the field and its crucial role in advancing robotics across various industries. This article provides valuable insights for researchers, engineers, and practitioners working on improving the performance, efficiency, and capabilities of robotic systems.

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