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Showing 2 results for Output Resistance

H. Faraji Baghtash, S. J. Azhari, Kh. Monfaredi,
Volume 7, Issue 4 (12-2011)
Abstract

In this paper a novel very high performance current mirror is presented. It favorably benefits from such excellent parameters as: Ultra high output resistance (36.9GΩ), extremely low input resistance (0.0058Ω), low output (~0.18V) and low input voltage (~0.18V) operation, very low power consumption (20μW), very low offset current (1pA), ultra wide current dynamic range (150dB), and ultra high accuracy (error = 0.003%). The circuit has a very simple compact architecture and uses a single 1V power supply. The qualitative performance of the circuit is validated with HSPICE simulations using HSPICE TSMC 0.18μm CMOS technology.
N. Raj,
Volume 17, Issue 3 (9-2021)
Abstract

The performance of any system is decided by the circuit configurations used in its implementation. Current mirror is one of those circuit configurations which are widely used in analog system designs. The performance of current mirror is decided by its parameters which include large operating range, wide bandwidth along with very low input and very high output resistances. In this paper, a low voltage flipped voltage follower based current mirror is presented. The structure flipped voltage follower is initially modified using a feedback path which results in the low impedance node which when considered as input in the proposed current mirror results in an extremely low value of input resistance. Compared to conventional flipped voltage follower based current mirror design the proposed design works well with minimum error in microamperes range with extended bandwidth without affecting its output resistance. The input resistance gets scaled down to 17 ohms from 840 ohms whereas bandwidth gets almost doubled approximately to 4.5GHz from 2.4GHz. The power dissipation ranges in microwatts. The simulations are supported with mathematical analysis. The complete analysis is done in HSpice using MOS models of 0.18-micron technology at a dual supply voltage, ±0.5V.


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