一种恒跨导高增益轨到轨运算放大器

基于TSMC 0.18 μm CMOS工艺,设计了一种新颖的恒跨导高增益轨到轨运算放大器。输入级仅由NMOS管差分对构成,采用电平移位及两路复用选择器控制技术,在轨到轨共模输入范围内实现了输入级恒跨导。中间级采用折叠式共源共栅放大器结构,运算放大器能获得高增益。输出级采用前馈型AB类推挽放大器,实现轨到轨全摆幅输出。利用密勒补偿技术进行频率补偿,运算放大器工作稳定。仿真结果表明,在1.8 V电源电压下,该运算放大器的直流开环增益为129.3 dB,单位增益带宽为7.22 MHz,相位裕度为60.1°,整个轨到轨共模输入范围内跨导的变化率为1.44%。     

恒跨导轨对轨CMOS运算放大器的设计

为了提高运算放大器对电源电压的利用率,基于GSMC 0.18 μm CMOS工艺模型,设计了一种高增益恒跨导轨对轨CMOS运算放大器。该运算放大器的输入级采用了互补差分对,并通过3倍电流镜法保证输入级总跨导在整个共模输入范围内恒定;为了获得较大的增益和输出摆幅,中间级采用了折叠式共源共栅结构;输出级采用了AB类输出控制电路,使输出摆幅基本实现了轨对轨。在3.3 V供电电压以及1.6 V输入电压下,该放大器的直流增益为126 dB,单位增益带宽为50 MHz,相位裕度为65°。电路结构简单,易于调试,可大大缩减设计周期和成本。     

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%。     

一种前馈型全摆幅恒跨导准恒增益CMOS运放设计

设计了一种适合在低电源电压下工作的前馈型输入级放大结构，在全摆幅的动态工作范围内，输入级跨导保持不变，采用负载电流补偿以保证增益近似恒定，输出采用前馈型AB类输结构，实现全摆幅输出。     

一种轨至轨输入的低压低功耗运放的设计

本文采用0.35μm的CMOS标准工艺,设计了一种轨至轨输入,静态功耗150μW,相位增益86dB,单位增益带宽2.3MHz的低压低功耗运算放大器。该运放在共模输入电平下有着几乎恒定的跨导,使频率补偿更容易实现,可应用于VLSI库单元及其相关技术领域。     

低功耗轨至轨CMOS运算放大器设计

设计了一个1.5 V低功耗轨至轨CMOS运算放大器。电路设计中为了使输入共模电压范围达到轨至轨性能,采用了NMOS管和PMOS管并联的互补差动对输入结构,并采用成比例的电流镜技术实现了输入级跨导的恒定。在中间增益级设计中,采用了适合在低压工作的低压宽摆幅共源共栅结构;在输出级设计时,为了提高效率,采用了简单的推挽共源级放大器作为输出级,使得输出电压摆幅基本上达到了轨至轨。当接100 pF电容负载和1 kΩ电阻负载时,运放的静态功耗只有290μW,直流开环增益约为76 dB,相位裕度约为69°,单位增益带宽约为1 MHz。     

一种恒跨导轨对轨CMOS运算放大器的设计

设计了一种新颖的恒跨导轨对轨CMOS运算放大器结构。输入级采用轨对轨的结构,在输入级采用4个虚拟差分对管来对输入差分对的电流进行限制,使运放的输入级跨导在工作范围内保持恒定。输出级采用前馈式AB类输出结构,以使输出达到全摆幅。仿真结果显示,在5 V电源电压和带有10 pF电容与10 kΩ电阻并联的负载下,该运放在共模输入范围内实现了恒跨导,在整个共模输入范围内跨导变化率仅为3%,输出摆幅也达到了轨对轨全摆幅,运放的开环增益为108.5 dB,增益带宽积为26.7 MHz,相位裕度为76.3°。     

一种恒跨导轨对轨输入/输出CMOS运算放大器

设计了一种CMOS恒跨导轨对轨输入/输出运算放大器,输入级采用负反馈技术控制尾电流,能自调整gm并使之保持恒定;输出级采用前向偏置AB类输出结构,实现轨对轨输出的同时减小了静态功耗。整个电路在5 V电源电压下,电压增益达到136 dB(1 MΩ电阻和1 pF电容并联负载),单位增益带宽为9.7 MHz,相位裕度62.4°。     

一种低电压恒定跨导轨到轨运算放大器的设计

设计了一种低电压恒定跨导的轨到轨运算放大器,作为误差放大器用在BUCK型DC-DC上实现对输出电压的调节。该运算放大器采用两级结构,输入级采用互补差分对的结构,实现了轨到轨电压的输入,并且利用2倍电流镜技术实现了跨导的恒定;输出级采用AB类放大器的结构,提高了输出电压摆幅和效率,实现了轨到轨电压的输出。该电路基于CSMC 0.25μm EN BCDMOS工艺进行设计,仿真结果表明:电源电压为2.8 V时,在输出端负载电容为160 pF、负载电阻为10 kΩ的情况下,增益为124 dB,单位增益带宽积为5.76 MHz,相位裕度为59.9℃,输入跨导为5.2 mΩ~(-1),共模抑制比为123 dB,输入共模信号范围为0～2.8V,输出电压摆幅为0～2.8 V。     

Class-AB型低功耗轨到轨CMOS模拟缓冲器设计

设计了一种新型Class-AB轨到轨CMOS单位增益模拟缓冲器。实现电路基于并行互补差分对输入,在保持整个电路简洁的同时,可提供低功耗Class-AB输出方式,使电路实现轨到轨的电平跟踪功能。使用0.35μm工艺库仿真,结果表明,该缓冲器具备较大的电容驱动能力,可以应用在具有大电容负载的场合。使用特殊设计方式,使电路主极点移动到输出节点上,彻底解决了大负载电容下电路的稳定性问题。电路使用3.3V单极性电源,在负载电阻大于1MΩ时,可以提供完全的轨到轨输出。在20pF负载电容时,输出摆率为+7.9V/μs和-5.8V/μs,整个电路的静态功耗仅为184μW。     

CMOS low-voltage operational amplifiers with constant-gm rail-to-rail input stage

Two 3.3-V operational amplifiers with constant-g _m rail-to-rail input stage and rail-to-rail output stage are presented. The constant transconductance (g _m ) ensures a constant unity-gain frequency within the whole commonmode input range. Two new methods to control theg _m are introduced. Both operational amplifiers use the same rail-to-rail output stage. The operational amplifiers have been integrated in a CMOS semicustom process with transistor lengths of 10µm. The common-mode input voltage swing extends beyond the positive supply rail by 400 mV and beyond the negative supply rail by 200 mV. The output voltage is able to reach within 130 mV of the supply rails. The output current of the operational amplifiers is 2 mA and the voltage gain is 85 dB. The unity-gain frquency is 165 kHz, which is mainly limited by the relatively long transistor lengths of 10µm. In another process with channel lengths of 2µm, simulation results showed that a unity-gain frequency of 4 MHz can easily be obtained.     

High-gain,high-bandwidth,rail-to-rail,constant-gm CMOS operational amplifier

This study presents a high-gain, high-bandwidth, constant-g_m , rail-to-rail operational amplifier (op-amp). The constant transconductance is improved with a source-to-bulk bias control of an input pair. A source degeneration scheme is also adapted to the output stage for receiving wide input range without degradation of the gain. Additionally, several compensation schemes are employed to enhance the stability. A test chip is fabricated in a 0.18?µm complementary metal-oxide semiconductor process. The active area of the op-amp is 181?×?173?µm² and it consumes a power of 2.41?mW at a supply voltage of 1.8?V. The op-amp achieves a dc gain of 94.3?dB and a bandwidth of 45?MHz when the output capacitive load is connected to an effective load of 42.5?pF. A class-AB output stage combining a slew rate (SR) boost circuit provides a sinking current of 6?mA and an SR of 17?V/µs.     

A rail-to-rail ping-pong op-amp

A rail-to-rail ping-pong op-amp achieves offset cancellation and 1/f noise reduction without folding of the input spectrum. The clocking scheme minimizes the clock feedthrough and the residual offset due to charge injection. With a clock frequency of 100 kHz, the residual offset is less than 100 μV, and the input referred noise is about 225 nV/Hz ^1/2. The rail-to-rail distortion at 1 kHz is lower than -71 dB. The total silicon area is 610×420 μm², and the circuit dissipates 1.5 mW from a single 5 V supply     

Constant-gm rail-to-rail CMOS op-amp input stage withoverlapped transition regions

Conventional techniques to achieve a constant-g_m rail-to-rail complementary N-P differential input stage require complex additional circuitry. In addition, the frequency response and common-mode rejection ratio (CMRR) are degraded. An economical but efficient design technique to overcome these problems is proposed. The proposed technique strategically overlaps the transition regions of the tail currents for the n- and p-pairs to achieve constant overall transconductance. Experimental results demonstrate that g_m variation can be restricted to within ±4% with improved CMRR and frequency response     

恒跨导高摆率轨对轨运算放大器的设计

本文在分析MOS管恒跨导输入级和AB类输出级运算放大器的基础上设计了一个高摆率、恒跨导的轨对轨运算放大器。在输入级中采用了齐纳二极管的稳压原理,保证Rail-to-Rail运算放大器的输入跨导恒定。为了实现高转换率,本文采用了一种新型的压摆率提高电路。另外,为了提高系统的稳定性,采用了控制零点的米勒补偿进行频率补偿。采...     

A low-power and high-gain fully integrated CMOS LNA

In this paper, we present the design of a fully integrated CMOS low noise amplifier (LNA) with on-chip spiral inductors in 0.18 μm CMOS technology for 2.4 GHz frequency range. Using cascode configuration, lower power consumption with higher voltage and power gain are achieved. In this configuration, we managed to have a good trade off among low noise, high gain, and stability. Using common-gate (CG) configuration, we reduced the parasitic effects of C_gd and therefore alleviated the stability and linearity of the amplifier. This configuration provides more reverse isolation that is also important in LNA design. The LNA presented here offers a good noise performance. Complete simulation analysis of the circuit results in center frequency of 2.4 GHz, with 37.6 dB voltage gain, 2.3 dB noise figure (NF), 50 Ω input impedance, 450 MHz 3 dB power bandwidth, 11.2 dB power gain (S₂₁), high reverse isolation (S₁₂)<−60 dB, while dissipating 2.7 mW at 1.8 V power supply.     

一种新型高速CMOS全差分运算放大器设计

设计了一种基于流水线模/数转换系统应用的低压高速CMOS全差分运算放大器。该运放采用了折叠式共源共栅放大结构与一种新型连续时间共模反馈电路相结合以达到高速度及较好的稳定性。设计基于SMIC 0.25μm CMOS标准工艺模型,在Cadence环境下对电路进行了Spectre仿真。在2.5V单电源电压下,驱动0.5pF负载时,开环增益为71.1dB,单位增益带宽为303MHz,相位裕度为52°,转换速率高达368.7V/μs,建立时间为12.4ns。     

A rail-to-rail CMOS op amp

A CMOS op amp (operational amplifier) is reported which has a rail-to-rail voltage range at its input as well as its output. An area-efficient output stage has been used. While the entire op amp occupies only 600 mil², when used as a unity-gain buffer and with ±5-V supplies, the op amp can drive a 9-V_pp/1-kHz sine wave across a 300-Ω load with -64 dB of harmonic distortion     

Design of a CMOS low-power and low-voltage four-quadrant analog multiplier

A New CMOS four-quadrant analog multiplier is presented in this paper. The proposed multiplier is suitable for low supply-voltage operation and its power consumption is also very low. The proposed circuit has been simulated with the HSPICE and simulation results are given to confirm the feasibility of the proposed analog multiplier. According to the simulation results, under the supply voltage of 1.5 V, the input range of the proposed multiplier can be 120 mV and the corresponding maximum linearity error is less than 3.2%. Moreover, the power dissipation of the proposed circuit is only 6.7 μW. The proposed circuit is expected to be useful in analog signal processing applications.