Performance Comparison between Decawave DW1000 and DW3000 in low-power double side ranging applications

2022 IEEE Sensors Applications Symposium (SAS) Pub Date : 2022-08-01 DOI:10.1109/SAS54819.2022.9881375

T. Polonelli, Simon Schläpfer, M. Magno

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引用次数: 3

Abstract

Indoor localization and context-awareness are becoming two of the key technologies for a large variety of applications. Real-time locating systems with centimeter accuracy and low power consumption have recently been made available by employing the Ultra WideBand (UWB) technology. Since 2015, Decawave has produced commercial UWB integrated circuits, exploiting time-of-flight measurement techniques to estimate the distance between two agents. This work presents a performance study between two Decawave transceivers, the DW1000 and the new DW3000 released in 2020. The testing space includes areas under line-of-sight and diverse non-line-of-sight conditions caused by the reflection of the UWB radio signals across various obstacles. Finally, we analyze the power consumption in distinct configurations, comparing the two devices. Results show that the two have similar precision in measurement ranges above one meter, while the DW3000 performs, on average, 33.2% better considering shorter distances. Moreover, the new transceiver features reduced power consumption by almost 50% during real-time measurements reaching an average value of 55 mW.

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Decawave DW1000和DW3000在低功耗双侧测距应用中的性能比较

室内定位和环境感知正在成为各种应用的两个关键技术。最近，利用超宽带(UWB)技术，可以实现厘米级精度和低功耗的实时定位系统。自2015年以来，Decawave已经生产了商用UWB集成电路，利用飞行时间测量技术来估计两个agent之间的距离。这项工作介绍了两个十波收发器DW1000和2020年发布的新DW3000之间的性能研究。测试空间包括视线和各种非视线条件下的区域，这些条件是由UWB无线电信号在各种障碍物上的反射引起的。最后，我们分析了不同配置下的功耗，并对两种器件进行了比较。结果表明，两者在1米以上的测量范围内具有相似的精度，而DW3000在考虑较短距离时的平均精度高出33.2%。此外，在实时测量期间，新型收发器的功耗降低了近50%，平均达到55 mW。

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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2022 IEEE Sensors Applications Symposium (SAS)

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