S. Kasnavi, S. Kilambi, B. Crowley, K. Iniewski, B. Kaminska
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引用次数: 9
Abstract
Wireless sensor networks provide the ability to gather and communicate critical environmental, industrial or security information to enable rapid responses to potential problems. The limited embedded battery life time requires ultra low power sensing, processing and communication systems. To achieve this goal, new approaches at the device, circuit, system and network level need to be pursued (Roundy et al., 2003). Adoption of error control codes (ECC) reduces the required transmit power for reliable communication, while increasing the processing energy of the encoding and decoding operations. This paper discusses the above trade off for systems with and without standard ECC, such as convolutional and Reed Solomon codes. The comparison of the required energy per bit, based on several implemented decoders, shows that the adoption of an ECC with simple decoding structures (such as Reed Solomon) is quite energy efficient. This has specially been observed for long distances.
无线传感器网络提供了收集和交流关键环境、工业或安全信息的能力,从而能够对潜在问题做出快速反应。有限的嵌入式电池寿命需要超低功耗的传感、处理和通信系统。为了实现这一目标,需要在设备、电路、系统和网络层面寻求新的方法(Roundy et al., 2003)。采用错误控制码(error control code, ECC)降低了可靠通信所需的发射功率,同时增加了编解码操作的处理能量。本文讨论了具有和不具有标准ECC的系统的上述权衡,例如卷积码和里德所罗门码。基于几个实现的解码器的每比特所需能量的比较表明,采用具有简单解码结构(如Reed Solomon)的ECC是相当节能的。这是特别在远距离观察到的。
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