Active-feedback frequency-compensation technique for low-power multistage amplifiers

An active-feedback frequency-compensation (AFFC) technique for low-power operational amplifiers is presented in this paper. With an active-feedback mechanism, a high-speed block separates the low-frequency high-gain path and high-frequency signal path such that high gain and wide bandwidth can be achieved simultaneously in the AFFC amplifier. The gain stage in the active-feedback network also reduces the size of the compensation capacitors such that the overall chip area of the amplifier becomes smaller and the slew rate is improved. Furthermore, the presence of a left-half-plane zero in the proposed AFFC topology improves the stability and settling behavior of the amplifier. Three-stage amplifiers based on AFFC and nested-Miller compensation (NMC) techniques have been implemented by a commercial 0.8-/spl mu/m CMOS process. When driving a 120-pF capacitive load, the AFFC amplifier achieves over 100-dB dc gain, 4.5-MHz gain-bandwidth product (GBW) , 65/spl deg/ phase margin, and 1.5-V//spl mu/s average slew rate, while only dissipating 400-/spl mu/W power at a 2-V supply. Compared to a three-stage NMC amplifier, the proposed AFFC amplifier provides improvement in both the GBW and slew rate by 11 times and reduces the chip area by 2.3 times without significant increase in the power consumption.     

Advances in active-feedback frequency compensation with power optimization and transient improvement

This paper presents a low-power stability strategy to significantly reduce the power consumption of a three-stage amplifier using active-feedback frequency compensation (AFFC). The bandwidth of the amplifier can also be enhanced. Simulation results verify that the power dissipation of the AFFC amplifier is reduced by 43% and the bandwidth is improved by 32.5% by using the proposed stability strategy. In addition, a dynamic feedforward stage (DFS), which can be embedded into the AFFC amplifier to improve the transient responses without consuming extra power, is proposed. Implemented in a 0.6-/spl mu/m CMOS process, experimental results show that both AFFC amplifiers with and without DFS achieve almost the same small-signal performances while the amplifier with DFS improves both the negative slew rate and negative 1% settling time by two times.     

Positive feedback frequency compensation for low-voltage low-power three-stage amplifier

The use of a new frequency compensation scheme for a three-stage operational amplifier is presented. The use of a positive feedback compensation (PFC) is employed to improve frequency response when compared to nested Miller compensation. A set of design equations is derived to give insight into the sizing of the amplifier. In addition, some characteristics relevant to the low-voltage low-power circuits using operational amplifiers have been modeled. Finally, an optimization algorithm was used with the purpose of extracting the most efficient solution. The PFC is especially suitable for driving large capacitance loads. It improves frequency response, slew rate (SR), and settling time. Small compensation capacitors make it appropriate for integration in commercial CMOS processes. With an active area of 0.03 mm/sup 2/ and working at 1.5 V, the circuit dissipates 275 /spl mu/W, has more than a 100-dB gain, a gain bandwidth of 2.7 MHz, and 1.0 V/spl mu/s average SR while driving a 130-pF load. Both measured frequency and transient step response show that the amplifier is stable.     

Transconductance with capacitances feedback compensation for multistage amplifiers

A new performance-boosting frequency compensation technique is presented, named Transconductance with Capacitances Feedback Compensation (TCFC). A transconductance stage and two capacitors introduce negative feedback to a three-stage amplifier, which significantly improves the performance such as gain-bandwidth product, slew rate, stability and sensitivity. An optimized TCFC amplifier has been implemented, and fabricated in a 0.35-/spl mu/m CMOS process. The TCFC amplifier driving a 150-pF load capacitor achieved 2.9-MHz gain-bandwidth product dissipating only 45-/spl mu/W power with a 1.5 V supply, which shows a significant improvement in MHz/spl middot/pF/mA performance.     

Single-Capacitor Active-Feedback Compensation for Small-Capacitive-Load Three-Stage Amplifiers

This brief presents a single-capacitor active-feedback compensation (SCAFC) scheme for three-stage internal amplifiers driving small capacitive loads. The proposed SCAFC scheme can stabilize the three-stage amplifier by using only a single small-value compensation capacitor, thereby significantly reducing the amplifier implementation area. With the small-value compensation capacitor, the wide gain-bandwidth product (GBW) of the SCAFC amplifier can also be achieved under low-power conditions. Implemented in a standard 0.35-mum CMOS process, the proposed three-stage SCAFC amplifier achieves over 100-dB dc gain, 9.6-MHz GBW, and 6.1-V/mus average slew rate, by only dissipating 90 muW at 1.5 V and using a 1-pF compensation capacitor, when driving a 500-kOmega // 20-pF load. The proposed SCAFC amplifier experimentally improves both bandwidth-to-power and slew-rate-to-power efficiencies by more than 14 times and 9 times, respectively, as compared to a conventional three-stage nested-Miller-compensated amplifier.     

Single Miller capacitor frequency compensation technique for low-power multistage amplifiers

Due to the rising demand for low-power portable battery-operated electronic devices, there is an increasing need for low-voltage low-power low-drop-out (LDO) regulators. This provides motivation for research on high-gain wide-bandwidth amplifiers driving large capacitive loads. These amplifiers serve as error amplifiers in low-voltage LDO regulators. Two low-power efficient three-stage amplifier topologies suitable for large capacitive load applications are introduced here: single Miller capacitor compensation (SMC) and single Miller capacitor feedforward compensation (SMFFC). Using a single Miller compensation capacitor in three-stage amplifiers can significantly reduce the total capacitor value, and therefore, the overall area of the amplifiers without influencing their stability. Pole-splitting and feedforward techniques are effectively combined to achieve better small-signal and large-signal performances. The 0.5-/spl mu/m CMOS amplifiers, SMC, and SMFFC driving a 25-k/spl Omega///120-pF load achieve 4.6-MHz and 9-MHz gain-bandwidth product, respectively, each dissipates less than 0.42 mW of power with a /spl plusmn/1-V power supply, and each occupies less than 0.02 mm/sup 2/ of silicon area.     

An accurate analysis of slew rate for two-stage CMOS opamps

This brief presents a time-domain model for the slew rate of CMOS two-stage Miller compensated operational transconductance amplifiers. The effects of both the first- and second-stage currents are considered in this model and a simple analytical expression is given in terms of the compensation and load capacitors, output voltage change, and device sizes. HSPICE simulation results are provided to show the validity of the proposed model using a 0.25-/spl mu/m CMOS technology.     

A high precision monolithic super-beta operational amplifier

A single-chip (67/spl times/90 mil) integrated-circuit operational amplifier using thin-film resistors and super-gain transistors has been designed to achieve dc follower accuracies of 0.001 percent with 100-k/spl Omega/ source resistance. The circuit achieves gains of 140 dB using thermally balanced layout designs for both input and output stages, nulled drifts of 0.3 /spl mu/V//spl deg/C, and offset currents well under 1 nA. All other dc specifications including power-supply variation error (PSRR), common-mode gain error (CMRR), etc., are in the 1-10 ppm error range; and a procedure is given by which long-term drifts of less than 10 /spl mu/V/month can be assured. AC performance is comparable to general-purpose integrated-circuit operational amplifiers, i.e., f/SUB t/=300 kHz and slew rate of 1.2 V//spl mu/s at gain of ten. The circuit is externally compensated for unity gain with a single 390-pF capacitor and is fully input and output protected.     

Self-biased cross-coupled low-cost fully-differential CMOS operational amplifier

A low-cost fully-differential operational amplifier (opamp) using a novel self-biased cascode output stage and cross-coupled input stage is proposed. Fabricated in only an 84/spl times/67 /spl mu/m/sup 2/ area with TSMC 0.35 /spl mu/m technology, and loaded with more than 100 pF capacitance, the opamp possesses 60 dB DC gain, 3 V//spl mu/s slew rate, 7.8 MHz unity-gain bandwidth, and -48 dB total harmonic distortion.     

Low-power high-slew-rate CMOS buffer amplifier for flat panel display drivers

A new high-slew-rate CMOS buffer amplifier consuming a very small quiescent current is proposed. This buffer amplifier recursively copies the output driving current and increases the tail current of the input differential pair during slewing. Since the proposed buffer has a possible slew rate higher than 10 V//spl mu/s for a load capacitance of 1 nF almost independently of static currents as low as 1 /spl mu/A, this buffer amplifier is promising for column driver ICs of flat panel displays that require low static power consumption, high current driving capabilities, and small silicon areas.     

High-speed driving scheme and compact high-speed low-power rail-to-rail class-B buffer amplifier for LCD applications

A high-speed driving scheme and a compact high-speed low-power rail-to-rail class-B buffer amplifier, which are suitable for small- and large-size liquid crystal display applications, are proposed. The driving scheme incorporates two output driving stages in which the output of the first output driving stage is connected to the inverting input and that of the second driving stage is connected to the capacitive load. A compensation resistor is connected between the two output stages for stability. The second output stage is used to improve the slew rate and the settling time. The buffer draws little current while static but has a large driving capability while transient. The circuit achieves the large driving capability by employing simple comparators to sense the transients of the input to turn on the output stages, which are statically off in the stable state. This increases the speed of the circuit without increasing static power consumption too much. A rail-to-rail folded-cascode differential amplifier is used to amplify the input signal difference and supply the bias voltages for the second stage. An experimental prototype output buffer implemented in a 0.35-/spl mu/m CMOS technology demonstrates that the circuit draws only 7-/spl mu/A static current and exhibits the settling times of 2.7 /spl mu/s for rising and 2.9 /spl mu/s for falling edges for a voltage swing of 3.3 V under a 600-pF capacitance load with a power supply of 3.3 V. The active area of this buffer is only 46.5/spl times/57/spl mu/m/sup 2/.     

用于低功耗三级放大器的嵌套式密勒有源电容频率补偿技术

提出了一种新的用于低功耗,节省面积的三级放大器频率补偿技术.该技术将有源电容进行嵌套连接从而克服了传统的嵌套式密勒补偿与反嵌套式密勒补偿的缺点.当将这一技术用标准的0.35μm工艺设计成电路并负载150pF电容时,放大器实现了105dB直流增益,3.3M的增益带宽积,68°相位裕度以及2.56V/μs的平均转换速率.而这一切的实现是在2V电源电压仅消耗40μW的功耗以及使用了很小的补偿电容.     

Amplifier techniques for combining low noise, precision, and high-speed performance

A monolithic operational amplifier is presented which optimizes voltage noise both in the audio frequency band, and in the low frequency instrumentation range. In addition, the design demonstrates that the requirements for low noise do not necessitate compromising the specifications in other respects. Techniques are set forth for combining low noise with high-speed and precision performance for the first time in a monolithic amplifier. Achieved results are: 3 nV//spl radic/Hz white noise, 80 nV/SUB p-p/ noise from 0.1 to 10 Hz, 17 V//spl mu/s slew rate, 63 MHz gain-bandwidth product, 10 /spl mu/V offset voltage, 0.2 /spl mu/V//spl deg/C drift with temperature, 0.2 /spl mu/V/month drift with time, and a voltage gain of two million.     

A 3.125 Gb/s limit amplifier in CMOS with 42 dB gain and 1 /spl mu/s offset compensation

A fast offset compensation method for high-gain amplifiers is presented that leverages a novel peak detector design and a dynamic, multi-tap feedback system to achieve roughly three orders of magnitude improvement in settling time over traditional compensation methods. Design tradeoffs between gain, bandwidth, power dissipation, and noise performance of the limit amplifier are discussed. Measured results of a custom 3.125 Gb/s limit amplifier in 0.18 /spl mu/m CMOS employing the proposed compensation technique demonstrate a sub-1-ms settling time while still achieving less than 4 ps rms output jitter with a 2.5 mV peak-to-peak input at 2.5 Gb/s.     

Micropower CMOS S&H circuit for ambient intelligence applications

A novel sample and hold (S&H) circuit is presented based on the use of a class AB CMOS operational transconductance amplifier with very high slew rate and very low static power consumption. The circuit has been fabricated in a 0.5 /spl mu/m double-poly CMOS technology. The quiescent power consumption is only 80 /spl mu/W using a dual supply voltage of /spl plusmn/1.35 V. The S&H occupies 0.075 mm/sup 2/ of silicon area.     

A micropower fourth-order elliptical switched-capacitor low-pass filter

A micropower fourth-order elliptical switched-capacitor (SC) low-pass filter for biomedical applications has been designed and measured. The charge transfer error of an SC integrator using a transconductance amplifier is discussed. Also first-order noise and PSRR calculations are performed and compared with the results of simulations and measurements. The measurements show that by careful optimization of the gain bandwidth, slew rate, and gain of the amplifiers, high-performance low-power SC filters can be constructed. The cutoff frequency of the filter is 5 kHz, the ripple in the passband is 0.27 dB, and stopband rejection is 49 dB. The power consumption of the filter is 190 /spl mu/W with /spl plusmn/2.5-V power supplies. The dynamic range of the filter is 75 dB, and the total harmonic distortion over the whole passband range is below 0.25% for a 2-V/SUB pp/ input signal. The PSRR of the filter is above 40 dB at frequencies below 3 kHz.     

High slew-rate CMOS operational amplifier

A 0.8 /spl mu/m CMOS operational amplifier configuration with a slew rate in excess of 2 V/ns and a unity gain bandwidth of 55 MHz with a load capacitance of 15 pF is proposed. This employs a dynamic technique that turns on a large current source when the rate of change of input is larger than a pre-decided value.     

Design procedure for optimizing CMOS low noise operational amplifiers

This paper presents and experimentally verifies an optimized design procedure for a CMOS low noise operational amplifier.The design procedure focuses on the noise performance,which is the key requirement for low noise operational amplifiers.Based on the noise level and other specifications such as bandwidth,signal swing,slew rate,and power consumption,the device sizes and the biasing conditions are derived.In order to verify the proposed design procedure,a three-stage operational amplifier has been designed.The device parameters obtained from the proposed design procedure closely agree with the simulated results obtained by using HSPICE.     

Rail-to-rail super class AB CMOS operational amplifiers

Novel class AB single-stage operational amplifiers are presented. They feature rail-to-rail operation owing to the use of floating-gate input transistors. Initial charge of the floating gates is removed during fabrication, without any post-processing. The amplifiers are fast, simple, and able to operate at low supply voltages. They are highly power efficient owing to the enhanced (super) class AB operation based on adaptive biasing and local common-mode feedback. A 0.5 /spl mu/m CMOS implementation shows rail-to-rail operation with slew rates of about 40 V//spl mu/s for a load of 80 pF and 144 /spl mu/W of quiescent power consumption.     

A slew-rate controlled output driver using PLL as compensation circuit

A slew-rate controlled output driver adopting the delay compensation method has been implemented using 0.18-/spl mu/m CMOS process for storage device interface. A phase-locked loop (PLL) is used to generate compensation current and constant delay time. The compensation current reduces the slew-rate variation over process, voltage, and temperature variation of the output driver. The constant delay time, which is generated by the replica of the voltage-controlled oscillator in the PLL, reduces the slew-rate variation over load capacitance variation. Such an output driver has 25% less variation at slew rate than that of the conventional output driver. The proposed output driver is able to meet UDMA100 interface that specifies load capacitance ranging from 15 to 40 pF and slew rate from 0.4 to 1.0 V/ns.