新型高频高线性CMOS跨导线性电流模乘/除法器设计被引量：2

Novel High-frequency High-linear CMOS Translinear Current-mode Multiplier/Divider

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摘要针对传统CMOS电流乘除法器存在线性度不高、工作频率低等缺点,提出一种以平方根电路、平方/除法器电路为核心的基于MOS管跨导线性原理的新型高频高线性CMOS电流模乘/除法器。在TSMC0.35μm CMOS集成工艺下进行HSPICE仿真测试表明:该电路在3V电源电压下,-3dB带宽可达到35.1MHz,电源静态功耗为202.68μW,输出电流为0～25.1μA,非线性误差为0.85%,总谐波失真为0.14%。本文提出的乘除法器电路与Tanno、Lopez等提出的基于跨导线性原理的乘除法器电路相比,优点在于-3dB带宽提高了,功耗降低了,电源电压降低了,线性度提高了,精度提高了,并且采用了相对更先进的0.35μmCMOS工艺,可缩小芯片面积,节约成本。 In view of the shortcoming of conventional CMOS current multiplier/divider in low linearity and low frequency ,a novel CMOS current mode multiplier/divider based on MOS Translinear rule,with square-root and squarer/divider circuit for core circuit, is proposed. HSPICE simulation test using TSMC＇s 0.35μm CMOS process model show a -3 dB bandwidth of 35. 1 MHz for the circuit,working at a supply voltage of 3 V,and its static power consumption is 202.68 #W,output current range 0-25.1 9A,nonlinear error 0.85% and total harmonic distortion 0. 14 %. Compared with the multipliers/dividers designed by Tanno,Lopez,et al. ,the proposed multiplier/divider circuit has many advantages,using -3 dB bandwidth ,reduced power consumption,reduced power supply voltage,improved linearity,raised accuracy,and a relatively more advanced 0. 35 μm CMOS technology,and saving chip area.

作者解鸿国宋树祥

机构地区广西师范大学电子工程学院

出处《广西师范大学学报（自然科学版）》 CAS 北大核心 2012年第2期12-16,共5页 Journal of Guangxi Normal University:Natural Science Edition

基金国家自然科学基金资助项目(61061006)

关键词平方根电路平方/除法器电路乘法器/除法器跨导线性原理 square-root circuit squarer/divider circuit multiplier/divider translinear principle

分类号 TN432 [电子电信—微电子学与固体电子学]

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参考文献8

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共引文献1

1解鸿国,颜菱.新型高线性CMOS可编程电流模放大器设计[J].广东通信技术,2016,36(6):52-55.

同被引文献14

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引证文献2

1凡东东,宋树祥,蒋品群,岑明灿.新型高增益CMOS跨导运算放大器[J].广西师范大学学报（自然科学版）,2014,32(4):6-10. 被引量：7
2高瑜宏,朱平.一种高增益带宽积CMOS跨导运算放大器[J].微电子学,2017,47(5):597-600. 被引量：5

二级引证文献12

1蔡超波,凡东东,宋树祥,岑明灿.一款带POR的可校正低功耗电压基准源[J].广西师范大学学报（自然科学版）,2016,34(1):26-31. 被引量：2
2张娜,金涛.10位高速分级比较型单斜模数转换器[J].广西师范大学学报（自然科学版）,2016,34(1):32-37.
3王军,韦笃取.一种分段补偿带隙基准电压源的设计[J].广西师范大学学报（自然科学版）,2017,35(2):17-23. 被引量：1
4高瑜宏,朱平.一种高增益带宽积CMOS跨导运算放大器[J].微电子学,2017,47(5):597-600. 被引量：5
5邓亚彬,蒋品群,宋树祥.新型低压微功耗伪差分跨导放大器设计[J].广西师范大学学报（自然科学版）,2018,36(1):17-24. 被引量：2
6苑隆寅,陈晓曼.计算机实验信息应用的器件研究[J].实验室研究与探索,2018,37(2):90-92. 被引量：2
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9高瑜宏,李俊龙.一种低压恒跨导轨对轨CMOS运算放大器设计[J].电子技术应用,2020,46(1):48-51. 被引量：4
10廉鹏飞,孔泽斌,陈倩,杨洋,李娟,祝伟明,楼建设,王昆黍.一种功率运算放大器失效机理的研究[J].半导体技术,2020,45(1):77-83.

1解鸿国,颜菱.新型高线性CMOS可编程电流模放大器设计[J].广东通信技术,2016,36(6):52-55.
2李志军,刘荣.基于平方根电路的电流模式乘法/除法器的实现[J].微电子学,2010,40(5):705-708. 被引量：3
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6徐跃,杨英强.1V高线性度2.4GHz CMOS低噪声放大器[J].电路与系统学报,2009,14(4):97-100. 被引量：3
7张黎黎,李志军.可编程神经元sigmoid函数及其导数发生器的实现[J].云南大学学报（自然科学版）,2016,38(1):44-53.
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10用于汽车LED照明的全新线性电流稳压器[J].今日电子,2016,0(12):65-66.

广西师范大学学报（自然科学版）

2012年第2期

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新型高频高线性CMOS跨导线性电流模乘/除法器设计被引量：2

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新型高频高线性CMOS跨导线性电流模乘/除法器设计 被引量：2

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新型高频高线性CMOS跨导线性电流模乘/除法器设计被引量：2