A fully integrated 2.4-GHz receiver in a 0.18-μm CMOS process for low-power body-area-network applications

2007 IEEE Biomedical Circuits and Systems Conference Pub Date : 2007-11-01 DOI:10.1109/BIOCAS.2007.4463336

A. Cabuk, A. Do, C. Boon, K. Yeo, M. Do

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引用次数: 2

Abstract

A fully integrated 2.4-GHz receiver targeting body sensor network applications is designed in 0.18-μm CMOS technology. The receiver includes a subthreshold biased low-noise amplifier (LNA), a passive mixer, two variable gain amplifiers (VGA) and a channel select filter (CSF). Several circuit design techniques are employed in order to reduce the silicon area and the power consumption of the receiver. The measured gain and the noise figure of the LNA are 20dB and 5.2dB, respectively. These values are obtained with a very low current of 630 μA from a 1.8-V supply. By employing a digitally switched-load gain variation scheme, the gain of the first VGA and the second VGA can be varied linearly from -18.5dB to +24.5dB, and from +16dB to +54dB, respectively. Input-referred noise at maximum gain mode is less than 17nV/radicHz and the current consumption is less than 400 μA from a 1.8-V supply for both circuits. The VGAs exhibit excellent linearity in terms of gain variation and gain compression. Small silicon area is achieved by avoiding bulky passive components.

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采用0.18 μm CMOS工艺的全集成2.4 ghz接收器，适用于低功耗体域网络应用

采用0.18 μm CMOS技术设计了一款针对人体传感器网络应用的全集成2.4 ghz接收器。接收机包括一个亚阈值偏置低噪声放大器(LNA)，一个无源混频器，两个可变增益放大器(VGA)和一个通道选择滤波器(CSF)。为了减少接收器的硅面积和功耗，采用了几种电路设计技术。LNA的实测增益和噪声系数分别为20dB和5.2dB。这些数值是在1.8 v电源630 μA的极低电流下获得的。通过采用数字开关负载增益变化方案，第一个VGA和第二个VGA的增益可以分别从-18.5dB到+24.5dB和+16dB到+54dB线性变化。两个电路在最大增益模式下的输入参考噪声小于17nV/radicHz，在1.8 v电源下的电流消耗小于400 μA。VGAs在增益变化和增益压缩方面表现出良好的线性。通过避免笨重的无源元件，实现了小硅面积。

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2007 IEEE Biomedical Circuits and Systems Conference

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