宽带CMOS可变增益放大器的设计

采用TSMC 0.18μm RF CMOS工艺设计实现了一种对数增益线性控制型的宽带可变增益放大器.电路采用两级结构,前级采用电压并联负反馈的Cascode结构以实现良好的输入匹配和噪声性能;后级采用信号相加式电路实现增益连续可调.同时本文设计了一种新型指数控制电压转换电路,解决了射频CMOS电路中,由于漏源电流与栅源电压通常不为指数关系而造成放大器对数增益与控制电压不成线性关系的难题,实现了可变增益放大器的对数增益随控制电压呈线性变化.芯片测试结果表明,电路在1.8V电源电压下,电流为9mA,3dB带宽为430～2330MHz.增益调节范围为-3.3～9.5dB,最大增益下噪声系数为6.2dB,最小增益下输入1dB压缩点为-9dBm.     

一种用于生物信号采集的CMOS全差分前置跨阻放大器设计

针对生物信号微弱、变化范围大等特点设计了一种用于检测微弱电流的全差分跨阻放大器(TIA)电路结构。不同于传统电路的单端输入,该结构采用高增益的全差分两级放大器实现小信号输入及轨到轨输出。基于CSMC 0.18μm CMOS工艺,采用1.8V电源电压对设计的电路进行了仿真,仿真结果表明:TIA输入电流动态范围为100nA^10μA,最大跨阻增益达到104.38dBΩ,-3dB带宽为4MHz,等效输入噪声电流为1.26pA/Hz。对电路进行跨阻动态特性仿真表明,在输入电流为100nA时,输出电压的动态摆幅达到3.24mV,功耗仅为250μW,总谐波失真(THD)为-49.93dB。所设计的高增益、低功耗、宽输入动态范围TIA适用于生物医疗中极微小生物信号的采集,可作为模块电路集成在便携设备中。     

微电容超声换能器的前端专用集成电路设计

针对微电容超声换能器(CMUT)微弱电流信号检测的要求,设计了一种用于CMUT的前端专用集成电路——运算放大器(OPA)电路。运算放大器电路采用两级放大结构,第一级采用全差分折叠-共源共栅结构,输出级采用AB类控制的轨到轨输出级,在运算放大器电路反相输入端和输出端通过一个反馈电阻实现CMUT电流信号到电压信号的转换。采用GlobalFoundries 0.18μm的标准CMOS工艺进行了仿真设计和流片,芯片尺寸为226μm×75μm。仿真结果表明,运算放大器的开环增益为62 dB,单位增益带宽为30 MHz,在3 MHz处的输入参考噪声电压为2.9μV/Hz^1/2,电路采用±3.3 V供电,静态功耗为11 mW。测试结果表明仿真与实测结果相符,该运算放大器电路能够实现CMUT微弱电流信号检测功能。     

A Precision High-Voltage Current Sensing Circuit

This paper presents a precision current sensor featuring a high voltage, high gain (~ 140 dB), and low input offset ( < 1 mV) current sense amplifier. This amplifier does not require offset trimming even for low offset applications. It is a single stage amplifier that has a common gate pMOS differential input pair, which makes it inherently stable. This amplifier topology allows for a wide input common-mode range, thus increasing the versatility of current sensing circuit.     

A 1.5-V current-mode CMOS sample-and-hold IC with 57-dB S/N at 20MS/s and 54-dB S/N at 30 MS/s

A new video-speed current-mode CMOS sample-and-hold IC has been developed. It operates with a supply voltage as low as 1.5 V, a signal-to-noise ratio (S/N) of 57 dB and 54 dB with a 1-MHz input signal at clock frequencies of 20 and 30 MHz, and a power dissipation of 2.3 mW. It consists of current-mirror circuits with the node voltages at the input and the output terminals which are kept constant in all phases of the input signal by the use of low-voltage operational amplifiers; this reduces the signal current dependency. The low-voltage operational amplifier consists of a MOS transistor and a constant current source in a common-gate amplifier configuration. Only two analog switches in differential form were used to construct the differential sample-and-hold circuit. This minimizes the error caused by the switch feed through, and thus high accuracy can be realized. Since there is no analog switch in the input path, it is possible to convert the input signal voltage to a current by simply connecting an external resistor. The circuit was fabricated using standard 0.6-μm MOS devices with normal threshold voltages (V_th) of +0.7 V (nMOS) and -0.7 V (pMOS)     

一种采用噪声抵消及多重功耗优化技术的UWB-LNA

采用噪声抵消及多重功耗优化技术,提出了一种超宽带低噪声低功耗放大器。它主要包括采用RL网络的共栅输入级、电流复用型噪声抵消级、放大输出级以及偏置电路四个部分。验证结果表明,该放大器,在2-6GHz频带内,增益(S21)可以在14dB以上;输入回波损耗(S11)小于-10dB;输出回波损耗(S22)小于-25dB;噪声系数(NF)小于3.2dB;在3.8V的工作电压下,功耗仅为14mW。     

A Current-Mode Circuit With a Linearized Input V/I Conversion Scheme and the Realization of a 2-V/2.5-V Operational, 100-MS/s, MOS SHA

This paper proposes a circuit to linearize the signal current and improve the distortion characteristics at the input of a current-mode circuit. Input voltage-to-current (V/I) conversion is carried out by a resistor that connects the signal source and the current input terminal of the current-mode circuit. The signal current flowing into the current-mode circuit through this resistor is distorted because of the signal-dependent voltage change at the current input terminal, and it is linearized by injecting a current that is proportional to the signal-dependent voltage change at the current input terminal, into the same current input terminal of the current-mode circuit. A current-mode sample-and-hold amplifier (SHA) that adopts the proposed scheme was fabricated and a 0.35-$mu{hbox {m}}$ CMOS process was used to verify the effectiveness of the scheme. It operated from a 2-V supply voltage in the analog part and a 2.5 V in the digital part with a 100-MHz clock and realized a 77- and a 86-dB spurious-free dynamic range values for 0 and $-$10 dB of full-scale signal current level $(pm hbox{100} mu{hbox {A}})$, respectively, of the 1-MHz signal input. More than a 13-bit equivalent SFDR for $-$14 to $-$4 dB of full-scale input was obtained, proving the effectiveness of the proposed scheme at realizing distortionless signal current processing.      

一种低失调高压大电流集成运算放大器

基于结型场效应晶体管(JFET)和双极型晶体管(BJT)兼容工艺,设计了一种低失调高压大电流集成运算放大器。电路输入级采用p沟道JFET (p-JFET)差分对共源共栅结构;中间级以BJT作为放大管,采用复合有源负载结构;输出级采用复合npn达林顿管阵列,与常规推挽输出结构相比,在输出相同电流的情况下,节省了大量芯片面积。基于Cadence Spectre软件对该运算放大器电路进行了仿真分析和优化设计,在±35 V电源供电下,最小负载电阻为6Ω时的电压增益为95 dB,输入失调电压为0.224 5 mV,输入偏置电流为31.34 pA,输入失调电流为3.3 pA,单位增益带宽为9.6 MHz,具有输出9 A峰值大电流能力。     

一种采用共栅频率补偿的轨到轨输入/输出放大器

提出了一种采用共栅频率补偿的轨到轨输入/输出放大器,与传统的Miller补偿相比,该放大器不仅可以消除相平面右边的低频零点,减少频率补偿所需要的电容,还可获得较高的单位增益带宽.所提出的放大器通过CSMC 0.6μm CMOS数模混合工艺进行了仿真设计和流片测试:当供电电压为5V,偏置电流为20μA,负载电容为10pF时,其功耗为1.34mW,单位增益带宽为25MHz;当该放大器作为缓冲器,供电电压为3V,负载电容为150pF,输入2.66 Vpp10kHz正弦信号时,总谐波失真THD为-51.6dB.     

Performance evaluation of an architecture for the characterisation of photo-devices: design,fabrication and test on a CMOS technology

In this report, the performance of a particular pixel's architecture is evaluated. It consists mainly of an optical sensor coupled to an amplifier. The circuit contains photoreceptors such as phototransistors and photodiodes. The circuit integrates two main blocks: (a) the pixel architecture, containing four p-channel transistors and a photoreceptor, and (b) a current source for biasing the signal conditioning amplifier. The generated photocurrent is integrated through the gate capacitance of the input p-channel MOS transistor, then converted to voltage and amplified. Both input transistor and current source are implemented as a voltage amplifier having variable gain (between 10dB and 32dB). Considering characterisation purposes, this last fact is relevant since it gives a degree of freedom to the measurement of different kinds of photo-devices and is not limited to either a single operating point of the circuit or one kind and size of photo-sensor. The gain of the amplifier can be adjusted with an external DC power supply that also sets the DC quiescent point of the circuit. Design of the row-select transistor's aspect ratio used in the matrix array is critical for the pixel's amplifier performance. Based on circuit design data such as capacitance magnitude, time and voltage integration, and amplifier gain, characterisation of all the architecture can be readily carried out and evaluated. For the specific technology used in this work, the spectral response of photo-sensors reveals performance differences between phototransistors and photodiodes. Good approximation between simulation and measurement was obtained.     

应用于S波段AESA的射频收发前端设计

采用0．18μm Si RFCMOS工艺设计了应用于s波段AESA的高集成度射频收发前端芯片。系统由发射与接收前端组成,包括低噪声放大器、混频器、可变增益放大器、驱动放大器和带隙基准电路。后仿真结果表明,在3．3V电源电压下,发射前端工作电流为85mA,输出ldB压缩点为5．0dBm,射频输出在2～3．5GHz频带内电压增益为6．3～9．2dB,噪声系数小于14．5dB;接收前端工作电流为50mA,输入1dB压缩点为-5．6dBm,射频输入在2～3．5GHz频带内电压增益为12—14．5dB,噪声系数小于11dB;所有端口电压驻波比均小于1．8：芯片面积1．8×2．6mm0。     

A low-voltage low-power instrumentation amplifier based on supply current sensing technique

In this paper a new low-voltage low-power instrumentation amplifier (IA) is presented. The proposed IA is based on supply current sensing technique where Op-Amps in traditional IA based on this technique are replaced with voltage buffers (VBs). This modification results in a very simplified circuit, robust performance against mismatches and high frequency performance. To reduce the required supply voltage, a low-voltage resistor-based current mirror is used to transfer the input current to the load. The input and output signals are of voltage kind and the proposed IA shows ideal infinite input impedance and a very low output one. PSPICE simulation results, using 0.18 μm TSMC CMOS technology and supply voltage of ±0.9 V, show a 71 dB CMRR and a 85 MHz constant −3 dB bandwidth for differential-mode gain (ranging from 0 dB to 18 dB). The output impedance of the proposed circuit is 1.7 Ω and its power consumption is 770 µW. The method introduced in this paper can also be applied to traditional circuits based on Op-Amp supply current sensing technique.     

220GHz低噪声放大器研究

基于IHP锗硅BiCMOS工艺,研究和实现了两种220 GHz低噪声放大器电路,并将其应用于220 GHz太赫兹无线高速通信收发机电路。一种是220 GHz四级单端共基极低噪声放大电路,每级电路采用了共基极（Common Base, CB）电路结构,利用传输线和金属-绝缘体-金属(Metal-Insulator-Metal, MIM)电容等无源电路元器件构成输入、输出和级间匹配网络。该低噪放电源的电压为1.8 V,功耗为25 mW,在220 GHz频点处实现了16 dB的增益,3 dB带宽达到了27 GHz。另一种是220 GHz四级共射共基差分低噪声放大电路,每级都采用共射共基的电路结构,放大器利用微带传输线和MIM电容构成每级的负载、Marchand-Balun、输入、输出和级间匹配网络等。该低噪放电源的电压为3 V,功耗为234 mW,在224 GHz频点实现了22 dB的增益,3 dB带宽超过6 GHz。这两个低噪声放大器可应用于220 GHz太赫兹无线高速通信收发机电路。     

Broad-band distributed amplifier impedance-matching techniques

A circuit concept is developed which allows impedance transformations to be performed over extremely broad bandwidths. The transformation is obtained by coupling one or more input or output lines of a distributed amplifier into several output or input lines, respectively. The circuit technique is demonstrated by results for an amplifier for a 1:2 impedance transformation over a 2-20-GHz bandwidth. The amplifier yields a voltage standing wave ratio (VSWR) of better than 1.7:1 into 25 Ω at the input and better than 1.5:1 into 50 Ω at the output while maintaining a gain of 9±1 dB. An application of the technique to the broadband impedance-matching problem of a laser diode driver is discussed. The circuit has a gain of 8.5±1 dB from 0.5 to 12.5 GHz and better than 10 dB return loss at both the input and output     

0．6VCMOS轨至轨运算放大器

为适应低压低功耗设计的应用,设计了一种超低电源电压的轨至轨CMOS运算放大器。采用N沟道差分对和共模电平偏移的P沟道差分对来实现轨至轨信号输入．。当输入信号的共模电平处于中间时,P沟道差分对的输入共模电平会由共模电平偏移电路降低,以使得P沟道差分对工作。采用对称运算放大器结构,并结合电平偏移电路来构成互补输入差分对。采用0．13μm的CMOS工艺制程,在0．6V电源电压下,HSpice模拟结果表明,带10pF电容负载时,运算放大器能实现轨至轨输入,其性能为：功耗390μw,直流增益60dB,单位增益带宽22MHz,相位裕度80°。     

一种跨阻放大器的设计

文章提出了一种基于调节型共源共栅电路结构（RGC）的跨阻放大器,采用0.5μm的标准互补型金属氧化物半导体（CMOS）工艺进行设计,仿真。测试结果表明,该电路具有69.93dB的跨阻增益,830MHz的-3dB带宽。在输入电流为1μA时,其输出电压的动态摆幅达到4.5mV,在5V电源电压下功耗仅为63.16mW。     

二极管型非制冷红外探测器的前端电路设计

设计了一种二极管型非制冷红外探测器的前端电路,该电路采用Gm-C-OP积分放大器的结构,将探测器输出的微弱电压信号经跨导放大器(OTA)转化为电流信号,再经电容反馈跨阻放大器(CTIA)积分转化为电压信号输出。该OTA采用电流反馈型结构,可以获得比传统OTA更高的线性度和跨导值。输入采用差分结构,可以有效地消除环境温度及制造工艺对探测器输出信号的影响。电路采用0.35 m CMOS工艺进行设计并流片,5 V电源电压供电。Gm-C-OP积分放大器总面积0.012 6 mm2,当输入差分电压为0~5 mV时,测试结果表明:OTA跨导值与仿真结果保持一致,Gm-C-OP积分放大器可实现对动态输入差分信号到输出电压的线性转化,线性度达97%,输出范围大于2 V。     

一种增益和摆率提升的电流镜运算放大器

提出了一种应用于低压低功耗电路的新型电流镜运算放大器。该运算放大器在传统电流镜运算放大器结构的基础上,在输入级增加电流复用模块,在输出级增加动态调控单元,提升了电路的增益和摆率,且不产生额外的静态功耗,不影响电路的稳定性。在UMC 28 nm CMOS工艺下进行设计和验证。仿真结果表明,在1.05 V电源电压下,与传统电流镜运算放大器相比,该运算放大器的摆率提高了11倍,增益提升了20 dB。     

一种S波段平衡式限幅低噪声放大器的设计

介绍了一种小型化平衡式限幅低噪声放大器。该放大器采用Lange桥平衡结构,在实现低噪声的同时,保证了小电压驻波比;在3.0～3.5GHz频带内,噪声系数小于1.3dB,输入输出驻波系数小于1.3,增益大于27dB,平坦度±0.6dB以内,输出1dB压缩点大于12dBm。该放大器能够承受最大5W的连续波功率输入,且大功率输入时的驻波系数小于1.3。     

提高读出电路输入电流动态范围的新方法

设计了一个由CMOS差分放大器构成的电容反馈跨阻型紫外焦平面单元读出电路。该电路在传统的读出电路基础上进行改进,大幅度的提高了输入电流的动态范围。该单元读出电路可应用于工作在快照模式下的128×128FPA读出电路,像素输出速率达10MHz,为探测器提供0．3V～2V的稳定偏置电压,输入电流的动态范围达52dB。