To Design a Cascode LNA by Using Channel-Length-Split Device with Constant-gm in a 0.35 μm Silicon CMOS Technology

The Open Materials Science Journal Pub Date : 2016-07-15 DOI:10.2174/1874088X01610010079

Jui-Lin Lai, Ting-You Lin, Cheng-Fang Tai, Rong-Jian Chen

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引用次数: 1

Abstract

Abstract: In the paper, the folded-cascode low-noise operational amplifier (LNA) with constant-gm is proposed and analyzed. The channel-length split technique adopted to expand ratio of W/L of the differential pair transistor to improve the performance of LNA for the gain bandwidth product, noise and offset voltage. The channel-length split method is separated differential input transistor into 2 transistors in series. The area of the transistor (W, L) can be properly increased to effectively decrease the flick noise. The double indirect-frequency compensation technique and the clamping circuit are adopted in amplifier to increase the bandwidth. The proposed two sets input differential pair can be provided a constant-gm value and rail-to-rail swing during the operating region. The floating-point structure is used to reach rail-to-rail swing at output stage. Simulation results show that the gain, constant-gm in input stag, noise, offset-voltage, PSRR, CMRR and ICMR of amplifier are improved. The characteristics of LNA are successfully verified by the TSMC 0.35um 2P4M CMOS technology. There have a great potential in the VLSI implementation used in the portable electronic and bio-medicine product applications.

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在0.35 μm硅CMOS工艺中，采用恒定gm的通道长度分割器件设计Cascode LNA

摘要:本文提出并分析了一种具有恒定gm的折叠级联低噪声运算放大器(LNA)。采用通道长度分路技术扩大差分对晶体管的W/L比，以提高LNA在增益带宽积、噪声和失调电压方面的性能。通道长度分割方法是将差分输入晶体管串联成2个晶体管。适当增加晶体管的面积(W, L)，可以有效地降低轻弹噪声。放大器采用双间接频率补偿技术和箝位电路来提高带宽。所提出的两组输入差动对可以在运行区域内提供恒定的gm值和轨间摆动。输出级采用浮点结构实现轨间摆动。仿真结果表明，该方法提高了放大器的增益、输入恒差、噪声、偏置电压、PSRR、CMRR和ICMR。LNA的特性通过台积电0.35um 2P4M CMOS技术成功验证。超大规模集成电路在便携式电子和生物医药产品中的应用具有很大的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Open Materials Science Journal

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