Slew rate and settling time are the important parameters in opamps with feedback. In this paper, the slew rate and settling time of the fully differential two stages folded cascade architecture amplifier with cascade compensation is analyzed. An important characteristic More
Slew rate and settling time are the important parameters in opamps with feedback. In this paper, the slew rate and settling time of the fully differential two stages folded cascade architecture amplifier with cascade compensation is analyzed. An important characteristic of the proposed analytical model is that the behavior of the transistors is examined in detail after applying the step in the input, and it is shown that the settling time as well as slew rate would depend on the size of the input step. The performed analysis can be beneficial for design and manual calculations in integrated circuits. Moreover, circuit level simulation is used to validate the analytical results with particular emphasis on slew rate and settling time. Simulations results show excellent conformance between the analytical equations and the simulation results.
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The need for low power and high-speed ADC pushes for dynamic comparators to reduce power consumption and maximize speed. This paper presents an analysis of delay, speed, and comparator considerations, and analytical expressions are derived. Using the equation expression More
The need for low power and high-speed ADC pushes for dynamic comparators to reduce power consumption and maximize speed. This paper presents an analysis of delay, speed, and comparator considerations, and analytical expressions are derived. Using the equation expressions, we can understand the design of comparators and make trade-offs. Based on the presented analysis, a new dynamic comparator is proposed by modifying the circuit of the conventional tail comparator for high speed and low power at small supply voltages without complicating the circuit design, resulting in a remarkable reduction in delay time and incremental speed. Simulation results in a 180 nm CMOS technology confirm the analysis results. It is shown that the proposed conventional tail comparator reduces power consumption and increases speed. The simulation results show that the proposed comparator operates up to 2.5GHz with a delay of 69ps and consumes only 329 μW at a supply voltage of 1.2 V and an offset standard deviation of 7.8 mW.
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