M. Cimino, H. Lapuyade, M. De matos, T. Taris, Y. Deval, J. Bégueret
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引用次数: 1
摘要
本文提出了一种可靠的射频集成电路设计方法。该方法基于通用掩模设计技术,以避免CMOS故障,并基于允许容错的冷备用冗余。该方法已应用于专用于ZigBee应用的低噪声放大器(LNA)演示器。该测试芯片采用0.13 μ m CMOS VLSI技术实现。LNA提供12 clBm的测量功率增益和3.6 dB的噪声系数,而在1.2 V电源下仅消耗4 mW。在测试芯片上的测量表明,增加的模块实现了可靠的方法,对LNA性能没有影响,同时效率很高。
A RF circuit design methodology dedicated to critical applications
This paper presents a reliable design methodology dedicated to radio frequency integrated circuits. This methodology is based on common mask design techniques to avoid CMOS failure and on a cold standby redundancy that permits fault tolerance. The methodology has been applied to a low noise amplifier (LNA) demonstrator dedicated to ZigBee applications. The test chip has been realized in a 0.13 mum CMOS VLSI technology. The LNA provides a measured power gain of 12 clBm and a 3.6 dB noise figure, while consuming only 4 mW under a 1.2 V power supply. Measurements on the test chip demonstrate that the addition of the blocks, which achieve the reliable methodology, have no impact on the LNA performances while being efficient.
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