Compact CMOS constant-gm rail-to-rail input stage with gm-control by an electronic zener diode

A family of compact CMOS rail-to-rail input stages with constant-g _m is presented. To attain a constant-g_m over the whole common-mode input range, an electronic zener diode is inserted between the tails of the complementary input pairs. This zener keeps the sum of the gate-source voltages of the input pairs, and therefore the g _m of the rail-to-rail input stage, constant. Two possible implementations of the zener have been realized and inserted in a rail-to-rail input stage. These input stages are implemented in two two-stage compact amplifiers. Both amplifiers have been realized in a 1 μm BiCMOS process. They have a unity-gain frequency of 2-MHz, for a capacitive load of 20 pF     

Low-voltage constant-gm rail-to-rail CMOS operational amplifier input stage

This paper presents a rail-to-rail constant-g_m operational amplifier input stage. The proposed circuit changes the tail current of the input differential pairs dynamically for a constant-g_m by using dummy input differential pairs. The problem which causes total g_m variation is input pairs and dummy input pairs can not take effect at the same time with the common-mode input voltage changes, because the tail current transistor of the input pairs are in triode region when the input pairs are turned off, the dummy input pairs will enter subthreshold region from cut-off region before the input pairs when common-mode voltage changes. The effect of this problem is more obviously in low supply voltage design. To solve this problem, compensate current sources is added to the tail current transistors of each dummy input differential pairs for lower g_m variation. The g_m of this Op Amp’s input stage varies around ±2%.     

A rail-to-rail input/output CMOS power amplifier

A rail-to-rail amplifier that maintains a high common-mode rejection ratio (CMRR) over the whole common-mode range and has a low harmonic distortion despite the use of relatively small output devices is discussed. The circuit, which measures only 0.3 mm² in a 3-μm technology, has a quiescent current consumption of 600 μA and a CMRR larger than 55 dB. It handles up to 4 nF, and can, with a 5-V supply, drive 3.8 V_pp into 100 Ω (0.1% total harmonic distortion at 10 kHz)     

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     

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     

A rail-to-rail input stage with constant signal behavior in 0.12 μm CMOS

This paper introduces a new fully differential low-voltage rail-to-rail input stage structure, which possesses a constant small- and large-signal behavior over the entire input common-mode range, and is suitable for low supply voltage applications in deep-submicron technologies. The proposed input stage is fabricated with two different opamp architectures in pure digital 0.12 μm CMOS technology for experimental verification. At ±0.5 V supply, the small-signal behavior variation is 5.45% across the supply rail. The large-signal behavior is constant at different input common-mode levels. The maximum current needed for the signal behavior regulation is only 90 μA.     

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.     

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.     

一种改进输入级结构的轨至轨运算放大器设计

基于0.18μm CMOS标准工艺设计了一种改进输入级结构的轨至轨运算放大器电路。该电路由输入级电路、共源共栅放大电路、共源输出电路及偏置电路组成。通过引入正反馈的MOS耦合对管将输入级电路改进为预放大电路,然后对其进行了详细分析,利用Cadence软件对电路进行仿真。仿真结果表明本文结构的低频直流开环增益可以达到80 dB,比相同参数下的普通结构高20 dB左右。相位裕度达到73o,共模输入电压范围满足全幅摆动,共模抑制比低频时可以达到107 dB。     

一种基于恒定电流技术的具有低功耗和低失真的轨导轨输入输出放大器

本文提出了一种应用于音频信号处理的具有恒定的跨导Rail-to-Rail放大器,并且恒定跨导是通过一种恒定电流技术来实现。此技术是基于差分输入对工作在弱反型区。对于工作在弱反型区的MOSFET具有低失调和低功耗的优势。采用标准的0.35微米的CMOS工艺对电路进行流片,此芯片占有面积75×183 μm2。测试结果表明：在3.3V电源电压下,电路最大功耗为85.37mW;在2kHz时总谐波失真为1.2%。     

A low power and low distortion rail-to-rail input/output amplifier using constant current technique

A rail-to-rail amplifier with constant transconductance,intended for audio processing,is presented.The constant transconductance is obtained by a constant current technique based on the input differential pairs operating in the weak inversion region.MOSFETs working in the weak inversion region have the advantages of low power and low distortion.The proposed rail-to-rail amplifier,fabricated in a standard 0.35μm CMOS process,occupies a core die area of 75×183μm~2.Measured results show that the maximum power consumption is 85.37μW with a supply voltage of 3.3 V and the total harmonic distortion level is 1.2%at 2 kHz.     

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 rail-to-rail amplifier input stage with /spl plusmn/0.35%g/sub m/ fluctuation

A new scheme for achieving rail-to-rail input to an amplifier is introduced. Constant g/sub m/ is obtained by using tunable level shifters and a single differential pair. Feedback circuitry controls the level shifters in a manner that fixes the common-mode input of the differential pair, resulting in consistent and stable operation for rail-to-rail inputs. As the new technique avoids using complimentary input differential pairs, this method overcomes problems such as common-mode rejection ratio and gain-bandwidth product degradation that exist in many other designs. The circuit was fabricated in 0.5-/spl mu/m process. The resulting differential pair had a constant transconductance that varied by only /spl plusmn/0.35% for rail-to-rail input common-mode levels. The input common-mode range extended well past the supply levels of /spl plusmn/1.5V, resulting in only /spl plusmn/1% fluctuation in g/sub m/ for input common modes from -2 to 2 V.     

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.     

Rail-to-rail amplifier input stage with constant g/sub m/ and commonmode elimination

A new scheme for achieving rail-to-rail input to an amplifier is introduced. Constant g/sub m/ and common mode removal is obtained by using a single input differential pair and tunable DC level shifters via multiple input floating gate transistors. The feedback circuitry basically fixes the common mode of the amplifier, resulting in consistent and stable operation for rail-to-rail inputs and a high common mode rejection ratio.     

Current mode instrumentation amplifier with rail-to-rail input and output

This paper presents the results from an investigation on the implementation of Current Mode Instrumentation Amplifiers (CMIAs) with rail-to-rail operational amplifiers (op amp) with a gm control circuit. The objective of employing rail-to-rail op amps in the implementation of a CMIA is the improvement of the common-mode operation range. The enhancement of the input common mode range (ICMR) is obtained using op amps with a rail-to-rail input stage followed by a cascode-based output stage. A prototype of the CMIA was implemented in standard 0.6 μm XFAB CMOS technology. Test results showed that the CMIA common mode range was extended but with moderated CMRR. To minimize this issue the amplifier was re-designed and sent to fabrication. Simulations with the components variations included were performed and showed the enhancement of the CMRR can be expected.     

Low-voltage operational amplifier with rail-to-rail input and output ranges

An operational amplifier is described which can perform precision signal operations in nearly the full supply voltage range, event when this range is as low as 1.5 V totally. The untrimmed input offset voltage is typically 0.3 mV in an input common-mode (CM) voltage range which extends beyond both supply voltages for about 200 mV. The output voltage can reach each supply rail within 150 mV. A nested-loop frequency-compensation scheme yields a stable unity-gain bandwidth of 0.6 MHz while the low-frequency open-loop voltage gain is 110 dB. The op amp is integrated in a standard low-cost bipolar process and the chip measures 1.5/spl times/1.7 mm/SUP 2/.     

1-V operational amplifier with rail-to-rail input and output ranges

A bipolar operational amplifier (OA) with rail-to-rail input and output ranges which can operate at supply voltages down to 1 V is presented. At this supply voltage, the input offset voltage is typically 1.0 mV in an input common-mode voltage range that extends beyond both supply rails for about 300 mV, with a common-mode rejection ratio (CMRR) between 38 and 100 dB, depending on conditions. The output voltage can reach both supply rails within 100 mV, the output current is limited to ±10 mA, the voltage gain is 100 dB, and the bandwidth is 450 kHz. The die is 2.5×5.5 mm². Qualities such as offset, input-bias current, and CMRR are improved when the supply voltage is increased and the dynamic level shift is autonomically turned off. The OA has been protected against unintentional reversal of the output signal when the inputs are substantially overdriven. The output stage of the circuit consists of two full complementary composite transistors, whose HF characteristics have been improved by internal Miller compensation and linearization of the transconductance     

基于gm/Id参数的CMOS运算放大器设计重用方法

模拟电路的设计重用是提高模拟与混合信号集成电路设计效率的重要途径.本文提出了一种基于g_m/I_d参数的不同工艺之间同一结构电路的设计移植方法.方法的基本思想是保持移植前后电路中部分关键MOS管的g_m/I_d参数,从而使移植后电路的性能也基本保持不变.介绍了基于BSIM等模型的g_m/I_d匹配及移植电路参数确定方法.给出了一个Miller补偿两级运放及一个折叠共源共栅运放从0.35μm工艺到0.18μm、0.13μm、90nm工艺的移植仿真结果.与现有方法相比,本文方法可以更小的计算代价,得到性能基本相同、但功耗与面积缩减的电路.