Power supply energy optimization for ultra low-power wireless sensor nodes

M. Tanevski, A. Boegli, P. Farine
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引用次数: 9

Abstract

The wireless sensor nodes are most energy-efficient when they operate at the minimal operating voltage. The nominal voltage of the batteries used is often significantly higher. This paper analyzes DC-DC power conversion from the point of view of ultra low-power wireless sensor nodes. Using a modified circuit of a suitable commercial DC-DC converter and a supercapacitor, this paper shows that it is possible to extend battery lifetime of a wireless sensor node for certain spectrum of applications. The efficiency of the DC-DC conversion as well as supercapacitor charge-discharge efficiency have been analyzed and measured. The influence of battery discharge currents and leakage currents is also presented. Furthermore, in this paper, we outline the specifications of a module needed between the battery and the sensor node that will be controlled by the node's MCU and will keep the node operating at minimal operational voltage while at the same time maximizing the energy delivered from the battery to the node. Thus, this paper also aims at setting foundations for future development of an energy-optimization module for ultra low power wireless sensor nodes.
超低功耗无线传感器节点电源能量优化
当无线传感器节点在最小工作电压下工作时,它们是最节能的。所用电池的标称电压通常要高得多。本文从超低功耗无线传感器节点的角度分析了DC-DC功率转换。利用一种合适的商用DC-DC转换器和一个超级电容器的改进电路,本文表明,在某些频谱应用中,延长无线传感器节点的电池寿命是可能的。对DC-DC转换效率和超级电容器充放电效率进行了分析和测量。研究了电池放电电流和漏电流的影响。此外,在本文中,我们概述了电池和传感器节点之间所需模块的规格,该模块将由节点的MCU控制,并将使节点在最小的工作电压下运行,同时最大限度地提高从电池传递到节点的能量。因此,本文也旨在为未来超低功耗无线传感器节点能量优化模块的开发奠定基础。
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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