低压工作的轨到轨输入／输出缓冲级放大器

本文提出了一种低压工作的轨到轨输入／输出缓冲级放大器。利用电阻产生的输入共模电平移动,该放大器可以在低于传统轨到轨输入级所限制的最小电压下工作,并在整个输入共模电压范围内获得恒定的输入跨导;它的输出级由电流镜驱动,实现了轨到轨电压输出,具有较强的负载驱动能力。该放大器在CSMCO．6-μmCMOS数模混合工艺下进行了HSPICE仿真和流片测试,结果表明：当供电电压为5V,偏置电流为60uA,负载电容为10pF时,开环增益为87．7dB,功耗为579uw,单位增益带宽为3．3MHz;当该放大器作为缓冲级时,输入3VPP10kHz正弦信号,总谐波失真THD为53．2dB。     

A high-speed low-power rail-to-rail column driver for AMLCD application

A high-speed rail-to-rail low-power column driver for active matrix liquid crystal display application is proposed. An inversion controller is attached to a typical column driver for rail-to-rail operation. Two high-speed complementary differential buffer amplifiers are proposed to drive a pair of column lines and to realize a rail-to-rail and high-speed drive. The output buffer amplifier achieves a large driving capability by employing a simple comparator to sense the transients of the input to turn on an auxiliary driving transistor, which is statically off in the stable state. This increases the speed without increasing static power consumption. The experimental prototype 6-bit column driver implemented in a 0.35-/spl mu/m CMOS technology demonstrates that the driver exhibits the maximum settling times of 1.2 /spl mu/s and 1.4 /spl mu/s for rising and falling edges with a dot inversion under a 680-pF capacitance load. The static current consumptions are 4.7 and 4.2 /spl mu/A for pMOS input buffers and nMOS input buffers, respectively. The values of the differential nonlinearity (DNL) and integral nonlinearity (INL) are less than 1/2 LSB.     

A high current drive CMOS output stage with a tunable quiescent current limiting circuit

A CMOS output stage based on a complementary common source with an original quiescent current limiting circuit is presented. The quiescent current can be varied over a wide range by means of a control current with no need to modify the transistor aspect ratios. The output stage has been coupled to a conventional complementary input stage to form a rail-to-rail buffer. A prototype with the inclusion of auxiliary pins for biasing and current monitoring purposes has been designed using the 1-/spl mu/m double-polysilicon BCD3S process of STMicroelectronics. On a single 5-V power supply, the maximum output current is 20 mA. The amplifier, biased for a total power dissipation of 1 mW, exhibits a total harmonic distortion of -58 dB at 1 kHz with 4-V peak-to-peak on a 330-/spl Omega/ load. Correct operation of the quiescent current limiting circuit has been demonstrated for a minimum supply voltage of 2.2 V.     

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°。     

An Ultra-Low-Voltage Ultra-Low-Power CMOS Miller OTA With Rail-to-Rail Input/Output Swing

An ultra-low-voltage ultra-low-power CMOS Miller operational transconductance amplifier (OTA) with rail-to-rail input/output swing is presented. The topology is based on combining bulk-driven differential pair and dc level shifters, with the transistors work in weak inversion. The improved Miller OTA has been successfully verified in a standard 0.35-mum CMOS process. Experimental results have confirmed that, at a minimum supply voltage of 600 mV, lower than the threshold voltage, the topology presents almost rail-to-rail input and output swings and consumes only 550 nW.     

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。     

A 0.9-V 0.5-μA rail-to-rail CMOS operational amplifier

A 0.9-V 0.5-μA, rail-to-rail CMOS operational amplifier designed with weak inversion techniques is presented. Depletion-mode nMOS transistors buffer a bulk-driven pMOS differential pair to realize wide input dynamic range, while the output stage architecture provides symmetric rail-to-rail output drive through the use of a low-voltage translinear control circuit     

Rail-to-rail low-power high-slew-rate CMOS analogue buffer

A low-power rail-to-rail CMOS analogue buffer is presented. The circuit is based on an input stage made up of two complementary class AB differential pairs, while a simple additional circuit allows rail-to-rail operation at the output terminal. The proposed circuit combines low static power consumption and high drive capability, resulting in suitability for applications with large capacitive loads. Simulated results are provided.     

1-V rail-to-rail operational amplifiers in standard CMOS technology

The constraints on the design of CMOS operational amplifiers with rail-to-rail input range for extremely low supply voltage operation, are addressed. Two design approaches for amplifiers based on complementary input differential pairs and a single input pair, respectively, are presented. The first realizes a feedforward action to accommodate the common-mode (CM) component of the input signals to the amplifier input range. The second approach performs a negative feedback action over the input CM signal. Two operational amplifiers based on the proposed approaches have been designed for 1-V total supply operation, and fabricated in a standard 1.2-μm CMOS process. Experimental results are provided and the corresponding performances are discussed and compared     

A -90-dB THD rail-to-rail input opamp using a new local charge pumpin CMOS

This paper describes the principle and design of a CMOS rail-to-rail input operational amplifier with THD performance of -90 dB which is suited for high-quality audio systems. A new output stage has been used featuring an output suing that extends to either supply rail and is capable of driving a low ohmic load (32 Ω). The opamp, which is realized in a 0.5-μm 3.3-V digital CMOS process, uses a standard two-stage Miller configuration. The rail-to-rail input functionality is achieved with a new area-efficient on-chip charge pump which provides the local supply voltage for the input differential pair. THD levels below -90 dB have not yet been shown with existing rail-to-rail techniques. This rail-to-rail input configuration also behaves independently of the common mode level with respect to transconductance and slewing characteristics     

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.     

A CMOS Voltage Comparator with Rail-to-Rail Input-Range

A simple new continuous-time CMOS comparator circuit with rail-to-rail input common-mode range and rail-to-rail output is presented. This design uses parallel complementary decision paths to accommodate power-supply-valued inputs. The 2 decision results are combined at a current summing node, converted to a voltage, and buffered to drive voltage loads. The circuit has been realized in an area of 416 m×221 m in a MOSIS 2-micron CMOS technology. Average delay of about 63 ns has been measured at 3 V (1.3 mA), and about 89 ns at 5 V (1.1 mA).     

A compact rail-to-rail CMOS buffer amplifier with very low quiescent current

In this work, a very compact, rail-to-rail, high-speed buffer amplifier for liquid crystal display (LCD) applications is proposed. Compared to other buffer amplifiers, the proposed circuit has a very simple architecture, occupies a small number of transistors and also has a large driving capacity with very low quiescent current. It is composed of two complementary differential input stages to provide rail-to-rail driving capacity. The push–pull transistors are directly connected to the differential input stage, and the output is taken from an inverter. The proposed buffer circuit is laid out using Mentor Graphics IC Station layout editor using AMS 0.35 μm process parameters. It is shown by post-layout simulations that the proposed buffer can drive a 1 nF capacitive load within a small settling time under a full voltage swing, while drawing only 1.6 μA quiescent current from a 3.3 V power supply.     

Input/Output Rail-to-Rail CMOS Operational Amplifier with Shaped Common-Mode Response

This paper presents an input/output rail-to-rail class-AB CMOS operational amplifier with reduced variations in unity-gain frequency over the entire voltage range. The rail-to-rail amplifier input stage is based on two parallel-connected complementary differential pairs. Variations in the small-signal response are kept to a minimum by realizing an adequate shaping of the CM response of the input stage, while still reducing deviations in the total limiting current of the two input pairs with respect to traditional solutions. This is achieved independently of the g _m -I _D characteristic of the amplifier input devices and of any strict matching condition between the complementary input pairs. Experimental results from a 3-V 0.8-m CMOS test-chip are given.     

Constant-g/sub m/ constant-slew-rate high-bandwidth low-voltage rail-to-rail CMOS input stage for VLSI cell libraries

This paper introduces a general-purpose low-voltage rail-to-rail input stage suitable for analog and mixed-signal applications. The proposed circuit provides, simultaneously, constant small-signal and large-signal behaviors over the entire input common-mode voltage range, while imposing no appreciable constraint for high-frequency operation. In addition, the accuracy of the circuit does not rely on any strict matching of the devices, unlike most of the traditional approaches based on complementary input pairs, which need to compensate for the difference in mobility between electrons and holes with the transistor aspect ratios. Also, the technique is compatible with deep submicrometer CMOS devices, where the familiar voltage-to-current square law in saturation is not completely satisfied. Based on the proposed input stage, a transconductor with rail-to-rail input common-mode range and an input/output rail-to-rail operational amplifier were developed. Both cells were designed to operate with a 3-V single supply and fabricated in standard 0.8-/spl mu/m CMOS technology. Experimental results are provided.     

1 V rail-to-rail constant-gm CMOS op amp

A 1 V rail-to-rail constant-g_m CMOS operational amplifier is proposed. This study shows that keeping the sum of currents in the complementary differential pairs constant rather than controlling the tail currents produces a constant-g_m input stage operating in the weak inversion. The currents in the n-channel differential pair are regulated to keep the sum of currents in the complementary differential pairs constant using a negative feedback loop. This study also provides experimental results obtained from a 0.35 μm CMOS prototype chip.     

A low-voltage complementary metal-oxide semiconductor adapter circuit suitable for input rail-to-rail operation

In this article, a low-voltage complementary metal-oxide semiconductor (CMOS) input signal adapter (ISA) suitable for input rail-to-rail operation of various types of analogue basic building blocks is presented. The adapter acts as a pre-stage with infinite input resistance and linear transfer characteristics. Its input signal is translated into the region fitting the operating range of the following stage. The generality of the proposed method is proven through the application of the ISA in different types of analogue basic building blocks designed in 0.5 μm CMOS technology. They are the following: below-negative-rail-to-above-positive-rail voltage-controlled transconductor, quasi rail-to-rail voltage-controlled resistor (VCR), rail-to-rail operational amplifier (OA) and quasi rail-to-rail second generation current conveyor. The proposed negative resistance quasi rail-to-rail VCR and rail-to-rail OA have been used in a Sallen and Key band-pass filter. All of these analogue basic building blocks and their applications in the form of the Sallen and Key band-pass filter operate from a single supply of 1.5 V. Simulation results confirm the predictions of the analysis performed.     

Some Design Aspects of a Two-Stage Rail-to-Rail CMOS Op Amp

A two-stage low-voltage CMOS op amp with rail-to-rail input and output voltage ranges is presented. The circuit uses complementary differential input pairs to achieve the rail-to-rail common-mode input voltage range. The differential pairs operate in strong inversion, and the constant transconductance is obtained by keeping the sum of the square roots of the tail currents constant. Such an input stage has an offset voltage which depends on the common input voltage level, resulting in a poor common-mode rejection ratio. Therefore, special attention has been given to the reduction of the op amp's systematic offset voltage. Gain-boost amplifiers are connected in a special way to provide not only an increase of the low-frequency open-loop gain, but also to provide a significant reduction of the systematic offset voltage.     

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°。     

Robust Design of LV/LP Low-Distortion CMOS Rail-to-Rail Input Stages

Two robust CMOS rail-to-rail OpAmp input stages are presented for low voltage ( 3 V) applications. The robust input stages are implemented using two recently reported universal approaches to achieve constant transconductance. Transconductance control circuit is also introduced to compensate for K _p , K _n mismatch of PMOS and NMOS differential pairs in the input stage. The input stages are designed for operation in the strong inversion and have a rail-to-rail common mode input voltage range. Compared with an OpAmp with simple complementary input pairs, a two stage rail-to-rail OpAmp design example exhibits lower total harmonic distortion (THD) levels over the entire common mode input voltage range.currently on leave as a visiting scholar at OSU