基于肌肉组织特性的路径损耗测量和通道建模。

Q3 Medicine
Open Biomedical Engineering Journal Pub Date : 2017-01-20 eCollection Date: 2017-01-01 DOI:10.2174/1874120701711010001
Yu-Ping Qin, Shuang Zhang, Hai-Yan Liu, Yi-He Liu, You-Zhi Li, Xue Peng, Xiu Ma, Qi-Li Li, Xuan Huang
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引用次数: 2

摘要

背景:电偶体内通信辐射低,抗干扰能力强,在无线通信中具有诸多优势。方法:为分析肌肉组织特性对通讯信道的影响,选取猪臀肌肉作为实验样本,研究了电偶联体内通讯信道相对于肌纤维线沿平行方向和横向方向以及受损肌纤维表面的衰减特性;研究频率范围从1kHz到10MHz。在各向同性实验中,为了破坏肌肉的纤维特性,我们对肌肉进行了四次研磨,每次至少5分钟。输入0dbm正弦波信号,测量发射器和接收器放置在不同位置、不同距离d1和d2 (20mm、40mm、60mm)时的信道衰减参数S21,分析信道损耗。结论:在相同频率范围内,在相同通信距离下,信道衰减的最大误差为10dB;在同一频率内,随着通信距离的增加,信道衰减逐渐增大,每20mm增加4dB。该结论为今后建立理论模型提供了依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Path Loss Measurement and Channel Modeling with Muscular Tissue Characteristics.

Path Loss Measurement and Channel Modeling with Muscular Tissue Characteristics.

Path Loss Measurement and Channel Modeling with Muscular Tissue Characteristics.

Path Loss Measurement and Channel Modeling with Muscular Tissue Characteristics.

Background: The galvanic coupling intra-body communication has low radiation and strong anti-interference ability, so it has many advantages in the wireless communication.

Method: In order to analyze the effect of muscle tissue's characteristics upon the communication channel, we selected the muscle of pig buttock as the experimental sample, and used it to study the attenuation property with the galvanic coupling intra-body communication channel along the parallel direction and the transverse direction relative to the muscular fibre line as well as on the surface of destroyed muscular fibre; the study frequency ranges from 1kHz to 10MHz.In the isotropic experiment, in order to destroy muscle's fibre characteristics, we grinded the muscle four times, at least five minutes for each time. 0dbm sine-wave signal was input to measure the channel attenuation parameter S21 when the transmitter and the receiver were placed at different positions and different distances d1 and d2 (20mm, 40mm, 60mm), so as to analyze channel loss.

Conclusion: Within the same frequency range and at the same communication distance, the maximum error of channel attenuation was 10dB; within the same frequency, as the communication distance was increased, the channel attenuation rose gradually, with 4dB increased every 20mm. The conclusion provides the basis for building the theoretical model in the future.

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来源期刊
Open Biomedical Engineering Journal
Open Biomedical Engineering Journal Medicine-Medicine (miscellaneous)
CiteScore
1.60
自引率
0.00%
发文量
4
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