High-Performance Multi-Stage CMOS OTA Design Using Differential Block As Compensation Network

This work presents an effective and straightforward frequency compensation scheme in CMOS three-stage amplifiers. Using a differential block in the compensation network, the proposed circuit shows independent and large first dominant pole regarding the DC gain path. The presented three-stage architecture is frequency-compensated just by a single Miller capacitor. Mathematical analysis is presented along with ample simulations that are performed using TSMC 0.18-[Formula: see text]m CMOS technology. According to the results, the proposed circuit shows DC gain equal to 118[Formula: see text]dB, GBW equal to 466[Formula: see text]MHz, PM equal to 74.3∘ and 1.2[Formula: see text]mW as power consumption, respectively. The high values of DC gain and GBW make the proposed amplifier appropriate for more speedy operations such as high-speed modulators and data converters.

0.5 V CMOS Inverter-Based Transconductance Amplifier with Quiescent Current Control

A two-stage CMOS transconductance amplifier based on the inverter topology, suitable for very low supply voltages and exhibiting rail-to-rail output capability is presented. The solution consists of the cascade of a noninverting and an inverting stage, both characterized by having only two complementary transistors between the supply rails. The amplifier provides class-AB operation with quiescent current control obtained through an auxiliary loop that utilizes the MOSFETs body terminals. Simulation results, referring to a commercial 28 nm bulk technology, show that the quiescent current of the amplifier can be controlled quite effectively, even adopting a supply voltage as low as 0.5 V. The designed solution consumes around 500 nA of quiescent current in typical conditions and provides a DC gain of around 51 dB, with a unity gain frequency of 1 MHz and phase margin of 70 degrees, for a parallel load of 1 pF and 1.5 MΩ. Settling time at 1% is 6.6 μs, and white noise is 125 nV/Hz.

Operational Amplifier Design Employing DTMOS Technique with Dual Supply Voltages

An operational amplifier (OPAMP) for portable devices with dual supply voltage is presented in this work. The design is realized with a 600[Formula: see text]mV supply for the core design and a 1.8[Formula: see text]V supply for the biasing circuit to improve input common mode range (ICMR), gain, and common mode rejection ratio (CMRR). The designed amplifier is implemented with dynamic threshold voltage MOSFET (DTMOS) transistors to decrease power consumption and increase the performance of the design. The power consumption of the core design is obtained as 2[Formula: see text][Formula: see text]W while the biasing circuitry consumes 7.38[Formula: see text][Formula: see text]W. The application of different supply voltages has greatly increased the gain of the circuit, where the circuit exhibits 100.2[Formula: see text]dB DC gain and 3.41[Formula: see text]MHz gain bandwidth product (GBW). CMRR of the designed circuit is 84.22[Formula: see text]dB. The simulations are performed in Cadence environment with 0.18[Formula: see text][Formula: see text]m CMOS technology.

Design Strategies and Architectures for Ultra-Low-Voltage Delta-Sigma ADCs

The design of ultra-low voltage analog CMOS integrated circuits requires ad hoc solutions to counteract the severe limitations introduced by the reduced voltage headroom. A popular approach is represented by inverter-based topologies, which however may suffer from reduced finite DC gain, thus limiting the accuracy and the resolutions of pivotal circuits like analog-to-digital converters. In this work, we discuss the effects of finite DC gain on ultra-low voltage ΔΣ modulators, focusing on the converter gain error. We propose an ultra-low voltage, ultra-low power, inverter-based ΔΣ modulator with reduced finite-DC-gain sensitivity. The modulator employs a two-stage, high DC-gain, switched-capacitor integrator that applies a correlated double sampling technique for offset cancellation and flicker noise reduction; it also makes use of an amplifier that implements a novel common-mode stabilization loop. The modulator was designed with the UMC 0.18 μm CMOS process to operate with a supply voltage of 0.3 V. It was validated by means of electrical simulations using the CadenceTM design environment. The achieved SNDR was 73 dB, with a bandwidth of 640 Hz, and a clock frequency of 164 kHz, consuming only 200.5 nW. It achieves a Schreier Figure of Merit of 168.1 dB. The proposed modulator is also able to work with lower supply voltages down to 0.15 V with the same resolution and a lower power consumption despite of a lower bandwidth. These characteristics make this design very appealing in sensor interfaces powered by energy harvesting sources.

Design of High Gain Folded Cascode OTA-Based Transconductance–Capacitance Loop Filter for PLL Applications

This paper deals with the designing of low-power transconductance–capacitance-based loop filter. The folded cascode-based operational transconductance amplifier (OTA) is designed in this paper with the help of quasi-floating bulk MOSFET that achieved the DC gain of 88.61[Formula: see text]dB, unity gain frequency of 97.86[Formula: see text]MHz and power consumption of 430.62[Formula: see text][Formula: see text]W. The proposed OTA is compared with the exiting OTA structure which showed 19.50% increase in DC gain and 15.11% reduction in power consumption. Further, the proposed OTA is used for the designing of transconductance–capacitance-based loop filter that has been operated at [Formula: see text]3[Formula: see text]dB cut-off frequency of 30.12[Formula: see text]MHz with the power consumption of 860.90[Formula: see text][Formula: see text]W at the supply voltage of [Formula: see text][Formula: see text]V. The transistor-level simulation has been done in 0.18[Formula: see text][Formula: see text]m CMOS process.

Integrated bioelectronic proton-gated logic elements utilizing nanoscale patterned Nafion

We report fully monolithic, nanoscale logic elements featuring n- and p-type nanowires as electronic channels that are proton-gated by electron-beam patterned Nafion giving DC gain exceeding 5 and frequency response up to 2 kHz.