Design and Characteristics of CMOS Inverter based on Multisim and Cadence

Known as complementary symmetrical metal oxide semiconductor (cos-mos), complementary metal oxide semiconductor is a metal oxide semiconductor field effect transistor (MOSFET) manufacturing process, which uses complementary and symmetrical pairs of p-type and n-type MOSFETs to realize logic functions. CMOS technology is used to build integrated circuit (IC) chips, including microprocessors, microcontrollers, memory chips (including CMOS BIOS) and other digital logic circuits. CMOS technology is also used in analog circuits, such as image sensors (CMOS sensors), data converters, RF circuits (RF CMOS), and highly integrated transceivers for various types of communications. Based on multisim 14.0 and cadence, the characteristics and performance of CMOS inverter are studied by simulation.

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.

Delta-sigma ADC modulator for multibit data converters using passive adder entrenched second order noise shaping

This paper introduces a multi-bit data converters (MDC) modulator of the 2nd order delta-sigma analog-to-digital converter use the passive adder proposed. The noise shaping quantizer can provide feedback that has generated quantization noise and perform additional shaping noise first-order by coupling noise method.Thus, two Integrator's with ring amplifier and the MDC is shaped by noise coupling quantizer know the 2nd-order noise coupled with somewhat of a DAC modulator. At a summing point, the inputs are summed and then filtered with a low pass filter. A cyclic second order response is generated with a data weighted averaging (DWA) technique in which the DACs ' outputs are limited to one of two states in the noise shaping responses. Mainly as a result of the harmonic distortion in circuits of amplifier. Transistor rate is equipped for the fully differential switched condenser integrator used, a comparator and DWA. The modulator with proposed DWA design, almost quarterly improved timing margin. A simulated SNDR of 92dB is obtained at 20 MHz sampling frequency; while a sinusoidal output of 4.112 dBFS is tested at 90µs besides 20 MHz as the bandwidth. The power consumption is 0.33 mW while the voltage of the supply is 1.2V.

A Research Perspective on CMOS Current Mirror Circuits: Configurations and Techniques

Background: Immense growth in the field of VLSI technology is fuelled by its feasibility to realize analog circuits in µm and nm technology. Current mirror (CM) is a basic building block used to enhance performance characteristics by constructing the complex analog/mixed-signal circuits like amplifier, data converters and voltage level converters. In addition, the current mirror finds diverse of applications from biasing to current-mode signal processing. Methods: In this paper, the Complementary Metal Oxide Semiconductor (CMOS) technology based current mirror (CM) circuits are discussed with their advantages and disadvantages accompanied by the performance analysis of different parameters. It also briefs on the various techniques which are employed for improvising the current mirror performance like gain boosting and bandwidth extension. Besides, this paper lists the CMs that use different types of MOS devices like Floating Gate MOS, Bulk-driven MOS, and Quasi-Floating Gate MOS. As a result, the paper performs a detailed review on CMOS Current mirrors and its techniques. Results: Basic CM circuits that can act as building blocks in the VLSI circuits are simulated using 0.25 μm, BSIM and Level 1 technology. In addition, various devices based CMs are investigated and compared. Conclusion: The comprehensive discussion shows that the current mirror plays a significant role in analog/mixed-signal circuits design to realize complex systems for low-power biomedical and wireless applications.