A high-frequency fully differential BiCMOS operational amplifier

A high-frequency fully differential BiCMOS operational amplifier design for use in switched-capacitor circuits is presented. The operational amplifier is integrated in a 3.0-GHz, 2-μm BiCMOS process with an active die area of 1.0 mm×1.2 mm. This BiCMOS op amp offers an infinite input resistance, a DC gain of 100 dB, a unity-gain frequency of 90 MHz with 45° phase margin, and a slew rate of 150 V/μs. The differential output range is 12 V. The circuit is operated from a ±5-V power supply and dissipates 125 mW. The op amp is unity-gain stable with 7 pF of capacitive loading at each output. The op amp is a two-stage, pole-split frequency compensated design that uses a PMOS input stage for infinite input resistance and an n-p-n bipolar second stage for high gain and high bandwidth. The frequency compensation network serves both the differential- and common-mode amplifiers so the differential- and common-mode amplifier dynamics are similar. A dynamic switched-capacitor common-mode feedback scheme is used to set the output common-mode level of the first and second stages     

A high-gain complementary metal-oxide semiconductor op amp using composite cascode stages

In this work, a complementary metal-oxide semiconductor (CMOS) op amp design using composite cascode stages is reported. The design follows the classic Widlar architecture and is fabricated on a 0.25 μm CMOS process. The measured gain of 117 dB is comparable to that achieved in bipolar designs in this architecture. This design is suited for precision instrumentation applications where high gain, low input offset voltage and small cell size are important. It provides a common-mode input range of ?1 to 0.7 V using±1 V power supplies with a quiescent current of 55 μA. The use of the composite cascode also allows for dominant pole compensation with a single capacitor. A phase margin of 43° is achieved with a 3.5 pF compensation capacitor. The resulting cell size for the core op-amp circuit is approximately 24 × 16 mils, including large common centroid input devices that achieve an input offset voltage in the 1 mV range.     

Design of Low Power 2.4GHz CMOS Cascode LNA with Reduced Noise Figure for WSN Applications

In this paper, a narrowband cascode Low Noise Amplifier (LNA) with shunt feedback is proposed. A typical inductively degenerated cascode LNA can be treated as a Common Source-Common Gate (CS-CG) two stage LNA. The series interstage inductance is connected between CS-CG stages to increase the power gain. An additional inductance which is connected at the gate of CG stage is used to cancel out the parasitic capacitance of CG stage therefore reduces the noise figure of CG stage. The shunt feedback is used to improve the stability and input impedance matching. This configuration provides better input matching, lower noise figure, low power consumption and good reverse isolation. The proposed LNA exhibits the gain of 13 dB, input return loss of ?11 dB, noise figure of 2.2 dB and good reverse isolation of ?42.8 dB at a frequency of 2.4GHz using TSMC 0.13 μm CMOS technology. It produces gain and noise figure better than conventional cascode LNA. The proposed LNA is biased in moderate inversion region for achieving sufficient gain with low power consumption of 1.5mW at a supply voltage of 1.5V.     

一种适合VLSI库的Rail-to-Rail运算放大器

介绍了一种适于 VLSI库单元的轨到轨 (Rail-to-Rail)运算放大器。低电压、低功耗、输入输出动态幅度达到 Rail-to-Rail的运放模块是研究的核心。文章分析了该运放模块的输入、输出级 ,并分析了 cascodedMiller频率补偿技术。芯片采用新加坡特许半导体制造公司 0 .6μm N阱 CMOS工艺 ,芯片面积 0 .0 2 4mm2 。测试结果表明 :该运放模块在 3 V工作电压下直流增益 90 d B,共模输入范围 -0 .4～ 4V,输出动态范围 0～ 2 .9V,单位增益带宽 7MHz,相位裕量 70°,静态功耗仅有 0 .3 m W,特别适合作为 VLSI的库单元     

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°。     

A Noise Reduction and Linearity Improvement Technique for a Differential Cascode LNA

A typical common source cascode low-noise amplifier (CS-LNA) can be treated as a CS-CG two stage amplifier. In the published literature, an inductor is added at the drain of the main transistor to reduce the noise contribution of the cascode transistors. In this work, an inductor connected at the gate of the cascode transistor and capacitive cross-coupling are strategically combined to reduce the noise and the nonlinearity influences of the cascode transistors in a differential cascode CS-LNA. It uses a smaller noise reduction inductor compared with the conventional inductor based technique. It can reduce the noise, improve the linearity and also increase the voltage gain of the LNA. The proposed technique is theoretically formulated. Furthermore, as a proof of concept, a 2.2 GHz inductively degenerated CS-LNA was fabricated using TSMC 0.35 mum CMOS technology. The resulting LNA achieves 1.92 dB noise figure, 8.4 dB power gain, better than 13 dB S11, more than 30 dB isolation (S12), and -2.55 dBm IIP3, with the core fully differential LNA consuming 9 mA from a 1.8 V power supply.     

共源共栅CMOS运算放大器的分析与设计

本文描述了一个共源共栅差分输入级、电流镜偏置输出级结构的两级CMOS运放,它对常规运放的电源电压抑制比、增益、输出驱动能力、噪声、失调等有显著的改善。文中对运放的工作原理及设计技术等进行了详细的叙述,并采用标准CMOS工艺进行了投片试制和采用SPICE进行了电路模拟。结果令人满意,达到了设计指标,证明了设计理论的正确性。该运放已成功地应用于开关电容滤波器芯片的制造。     

低功耗恒定跨导轨对轨运算放大器设计技术研究

为了解决轨对轨运算放大器输入级跨导随共模输入电压变化的影响,采用实时共模电压监测技术,动态跟踪轨对轨运放输入级的跨导变化,通过对偏置电流的高精度定量补偿,从而实现了对输入级跨导的恒定性控制。基于0.18μm CMOS工艺进行了具体电路的设计实现,结果表明:在电源电压3.3 V、负载电阻100Ω、负载电容1 nF的条件下,运放增益为148 dB、相位裕度为61°、功耗为39.6μW,共模输入范围高达0~3.3 V,输入级跨导变化率仅为2.1%。     

A fast-settling CMOS op amp for SC circuits with 90-dB DC gain

A technique that combines the high-frequency behavior of a single-stage op amp with the high DC gain of a multistage design is presented. This technique is based on the concept that a very high DC gain can be achieved in combination with any unity-gain frequency achievable by a (folded-) cascode design. Bode-plot measurements for an op amp realized in a 1.6-μm process show a DC gain of 90 dB and a unity-gain frequency of 116 MHz (16-pF load). Settling measurements with a feedback factor of 1/3 show a fast single-pole settling behavior corresponding to a closed-loop bandwidth of 18 MHz (35-pF load) and a settling accuracy better than 0.03%. This technique does not cause any loss in output voltage swing. At a supply voltage of 5.0 V an output swing of about 4.2 V is achieved without loss in DC gain. The above advantages are achieved with a 30% increase in chip area and a 15% increase in power consumption     

An ultra-high gain low power two stage CMOS op-amp based on inverse aspect ratio self cascode structures

A very high gain (137 dB) two stage CMOS operational amplifier having structural simplicity of classical Widlar architecture has been presented. The differential input stage of proposed operational amplifier has been modified by incorporating inverse aspect ratio self cascode structures biased to operate in subthreshold region, to minimize the classical compensation capacitor to 0.1 pF and results in considerable saving in occupied chip area. P-SPICE simulations in 0.25 μm CMOS technology at ±1 V supply have been carried out to compare the performance of proposed operational amplifier with previously reported designs. The proposed operational amplifier demonstrated better gain-bandwidth product of 1.37 MHz, low power consumption of 21 μW and occupied smaller chip area of <400 (μm)².     

High-speed GaAs operational amplifier

An operational amplifier has been designed and fabricated using GaAs MESFETs. This amplifier is a general-purpose monolithic GaAs op amp designed as as a stand-alone component. The amplifier has a differential input, an open-loop gain in excess of 60 dB, and is internally compensated. The high open-loop gain (60 dB at 100 kHz) was achieved by using gain stages with positive feedback. The op amp incorporates a current-mirror level-shifting stage which allows the op amp to operate over a wide power-supply range (/spl plusmn/5-9 V). Previous designs have diodes to achieve level shifting, a practice that precludes operation over a wide supply range. This op amp is a true analog to its silicon counterparts, but it has a higher gain-bandwidth product.     

A fully-differential OTA based on CMOS cascode inverters operating from 1-V power supply

A low voltage operating fully-differential CMOS OTA construction, which uses dual-input CMOS cascode inverters, is proposed. The OTA is a two-stage configuration with dual-input CMOS cascode inverters at the input stage, and traditional CMOS inverters in the output stage, with a common-mode feedback path from the output terminals to one of the input terminals of cascode inverters. In order to effectively reduce its threshold voltages by bulk bias technique, the OTA has been designed and fabricated by using a 0.15 μm triple-well CMOS process. The OTA successfully operated from 1-V power supply, with 59 dB of differential voltage gain, 80.9 dB of CMRR and 25 MHz of unity gain frequency, at 60 μA of current consumption.     

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。     

Low-power CMOS continuous-time filters

A design technique for low-power continuous-time filters using digital CMOS technology is presented. The basic building block is a fully-balanced integrator with its unity-gain frequency determined by a small-signal transconductance and MOSFET gate capacitance. Integrator excess phase shift is reduced using balanced signal paths, and open-loop gain is increased using low-voltage cascode amplifiers. Two-pole bandpass and five-pole lowpass ladder filters have been implemented in a 1.2 μm n-well CMOS process. The lowpass prototypes provided 300 kHz-1000 kHz bias-current-tunable -3 dB bandwidth, 67 dB dynamic range with 1% total harmonic distortion (THD), and 30 μW/pole (300 kHz bandwidth) power dissipation with a 1.5 V supply; the bandpass prototypes had a tunable center frequency of 300 kHz-1000 kHz, Q of 8.5, and power dissipation of 75 μW/pole (525 kHz center frequency) from a 1.5 V supply. The active filter area was 0.1 mm²/pole for both designs     

Enhanced source-degenerated CMOS differential transconductor

A simple technique to improve the output resistance and the linearity of a source-degenerated differential CMOS transconductor is presented, useful even under low supply voltage. It combines the utilization of a super-transistor as a unity-gain buffer and the use of the weak inversion region to optimize a regulated cascode source. Using a standard 0.13 μm CMOS technology with 1.5 V supply voltage, simulation results show the transconductor attains more than 1 GΩ as differential output resistance and a third-order harmonic distortion factor less than −110 dB at 1 kHz for a 0.35 V_pp differential input signal. Other performances are 126 μW power consumption and 65 MHz bandwidth.     

A 10-b 20-Msample/s low-power CMOS ADC

A single-ended input but internally differential 10 b, 20 Msample/s pipelined analog-to-digital converter (ADC) is demonstrated with 4 mW per stage using a single 5 V supply. The prototype ADC made of an input sample and hold (S/H) plus 8 identical unscaled pipelined stages consumes 50 mW including power consumed by a bias generator and two internal buffer amplifiers driving common-mode bias lines. Key circuits developed for this low-power ADC are a dynamic comparator with a capacitive reference voltage divider that consumes no static power, a source-follower buffered op amp that achieves wide bandwidth using large input devices, and a self-biased cascode biasing circuit that tracks power supply variation. The ADC implemented using a double-poly 1.2 μm CMOS technology exhibits a DNL of ±0.65 LSB and a SNDR of 54 dB while sampling at 20 MHz. The chip die area is 13 mm²     

Fast settling opamp with low power consumption

This paper presents a design strategy to minimize step response settling time of a two stage miller opamp with low power consumption. Appropriate spacing between poles and zero has been kept, so an underdamped transient response with minimum settling time is obtained. Analytical results show that for a specific load capacitor, if zero frequency is placed at appropriate distance from unity gain frequency, then minimum settling time can be obtained. Analysis using device modelling has been carried out to determine element values for optimum compensation followed by its simulations in triple metal layer n-well CMOS process using 0.5?µ technology. Best simulation results obtained on Tanner tool show 86.2?dB gain, 136.6?MHz unity gain frequency (ω_μ ), 25?ns settling time (t_s ) with 1pf load, 211?V/µs slew rate (SR) with 1pf load, and 2.56?mW of power dissipation. The approach reported has been found to be the best after carrying out extensive performance evaluation through simulation.     

一种增益提升高速CMOS运算跨导放大器的设计

设计了用于高速高分辨率ADC的CMOS全差分运算放大器,采用套筒式级联增益自举电路,达到高增益带宽且低功耗。在3.3V电源电压下,用TSMC0.35μmCMOS工艺模型,通过Cadence软件Spectre仿真平台,驱动1PF负载时,相位裕度为65度,单位增益带宽为316MHz,功耗5.7mW,压摆率200V/μs。     

Design and analysis of high Transconductance Current Follower Transconductance Amplifier (CFTA) and its applications

In this paper, a single-stage class AB bulk-driven amplifier operating in weak inversion region is proposed. The presented amplifier benefits from an improved high input swing structure using quasi-floating-gate technique. The composite transistors and recycling configuration used at the input stage enable the input differential pair to operate under low supply voltages with larger transconductance as compared to the conventional models at no expense of power budget. The circuit is designed in 0.18 µm CMOS technology and simulation results show 61.5 dB low frequency gain with the gain bandwidth of 30.15 kHz and 55.3 V/ms average slew rate. The total current of 275 nA and 0.6 V supply voltage make the proposed amplifier a suitable choice for ultra-low-power applications.     

Using the weak inversion region to optimize input stage design of CMOS op amps

Operation of MOS devices in the strong, moderate, and weak inversion regions is considered. The advantages of designing the input differential stage of a CMOS op amp to operate in the weak or moderate inversion region are presented. These advantages include higher voltage gain, less distortion, and ease of compensation. Specific design guidelines are presented to optimize amplifier performance. Simulations that demonstrate the expected improvements are given.