基于柔性线圈的信能同链路分时传输系统OA
Flexible Coil-Based Information-Power Co-Link Time-Division Transmission System
无线传能通信一体化技术以其方便灵活等特点,在生物电磁领域具有广阔的应用前景,为解决生物体内微电子系统的供能与信息传递问题提供了的技术支撑,但双通道串扰降低传能效率下降、线圈弯曲导致谐振点大幅偏移及传输信号还原度低等问题,不同程度地阻碍了该技术的应用与发展.对此,该文提出一种基于柔性线圈的信能同链路分时传输系统,通过双向开关控制能量和信息交替传输,有效地避免了双通道间的串扰问题.收发线圈采用弧段并联结构的柔性线圈,有效地抑制了线圈形变对电感的影响,减小了谐振点偏移程度.在传统的解调电路上增加峰值检波及判决电路,使传输信号更平滑.通过仿真并搭建实验平台,验证了该文所设计系统在 0~5 mm 范围内可实现 85%以上的传能效率及 5 Mbit/s 的数据传输速率.结果表明,该系统在生物电磁领域具有一定的应用潜力.
The integrated technology of wireless power transfer and communication has reduced power transfer efficiency due to dual-channel crosstalk,significant resonant frequency shifts caused by coil deformation,and compromised signal reconstruction fidelity,hindering its application in bio-electromagnetism.Most existing solutions are constrained by excessive hardware complexity and impractical coupling-coil dimensions.Therefore,this study introduces a flexible coil-based information-power co-link time-division transmission system. The proposed system employs a PWM-controlled bidirectional switch to alternate between energy and data transmission phases.The power delivery channel adopts a bilateral LCCL compensation topology,leveraging its pronounced frequency-dependent impedance characteristics to minimize cross-interference between the dual transmission paths.Based on an analysis of various coil configurations,the arc segment parallel connection structure is identified as the optimal coupling topology,demonstrating superior performance metrics.To ensure mechanical flexibility and conformability,polyimide film is adopted as the substrate material for both the coil and receiver circuitry.Furthermore,the demodulation process is enhanced by integrating a peak detection and decision circuit,thereby significantly improving signal integrity. Simulation results across the 1~20 MHz frequency band reveal that the arc-segment parallel coil exhibits a substantially higher quality factor than conventional single-layer,double-layer series,and double-layer parallel configurations.Experimental validation confirms the system's robust performance,with a power transfer efficiency exceeding 85%at a 5 mm transmission distance,a data rate of 5 Mbit/s,and a bit error rate(BER)as low as 2×10-6.The compact design features a coupling coil with an outer diameter of 22.56 mm,a receiver circuit measuring 45 mm×37 mm×2 mm,and a transmitter circuit sized at 60 mm×55 mm×10 mm.Inductance stability analysis under mechanical deformation demonstrates that the arc-segment parallel coil exhibits markedly reduced inductance variation compared to single-layer structures. Three key conclusions can be drawn.Firstly,the arc-segment parallel coil architecture not only improves power transfer efficiency but also effectively mitigates inductance fluctuations during deformation,thereby minimizing frequency detuning and associated performance degradation.Secondly,the addition of peak detection and decision circuitry improves the smoothness of the demodulated signal,ensuring consistently low BER.Thirdly,the time-division transmission strategy eliminates dual-channel crosstalk.High power transfer efficiency and high-speed data communication can be achieved without additional hardware or complex algorithms.As a result,the overall system volume is reduced.
周华康;严仲明;曹桂梅;刘俊
西南交通大学电气工程学院 成都 610031西南交通大学电气工程学院 成都 610031西南交通大学电气工程学院 成都 610031西南交通大学电气工程学院 成都 610031
信息技术与安全科学
传能通信生物电磁分时传输弧段并联柔性线圈
Power transfer and communicationbio-electromagnetismtime-division transmissionarc segment parallel connectionflexible coil
《电工技术学报》 2026 (12)
3987-3997,11
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