一种基于死区放大器的RFID接收机信号泄漏抑制新技术

Sang-Sung Lee, Jaeheon Lee, In-Young Lee, Sang-Gug Lee, J. Ko
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引用次数: 16

摘要

RFID系统使用后向散射通信,其中TX发送连续波(CW)为标签提供能量,而RX从标签接收数据。由于RX和TX同时工作,大的TX泄漏是确保RX灵敏度的主要问题。尽管环行器或定向耦合器等外部隔离组件广泛应用于RFID系统,但由于其有限的隔离和环境相关的天线反射比,TX泄漏仍然是灵敏度下降的主要来源,如图5.6.1(a)所示。在基于单天线的RFID系统中,尽管有片外隔离元件,但在RX输入处,TX载波泄漏通常在0dBm以上[1]。由图5.6.1(b)可以看出,当TX载波的近端相位噪声为-85dBc/Hz时,接收通道中0dBm TX泄漏的相位噪声电平比热噪声电平高89dB,直接降低了信噪比。为了解决泄漏问题,已经报道了泄漏抵消[2,3]和自相关RX[4]技术。然而,泄漏副本生成的高功耗和长校准时间(如[2,3])以及45度相移[4]的硬件复杂性是需要解决的问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A new TX leakage-suppression technique for an RFID receiver using a dead-zone amplifier
RFID systems use backscattering communication in which the TX transmits a continuous wave (CW) to provide energy to the tag while the RX receives data from it. Due to the simultaneous operation of the RX and TX, large TX leakage is the main issue in securing RX sensitivity. Although external isolation components such as a circulator or directional coupler are widely used in RFID systems, TX leakage is still a dominant source of sensitivity degradation due to its finite isolation and environmentally dependent antenna reflection ratio, as shown in Fig. 5.6.1(a). In a single-antenna-based RFID system, the TX carrier leakage is typically above 0dBm at the RX input despite off-chip isolation components [1]. As can be seen in Fig. 5.6.1(b), when the close-in phase noise of the TX carrier is -85dBc/Hz, the phase noise level of 0dBm TX leakage in the receive channel reaches 89dB higher than the thermal noise level, thus directly degrading the SNR. In efforts to solve the leakage problem, leakage cancellation [2,3] and self-correlated RX [4] techniques have been reported. However, high power consumption for leakage replica generation and long calibration time, as in [2,3], and hardware complexity for a 45 degree phase shift [4] are issues that need to be resolved.
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