Overview of Low-Voltage Low-Power Design Techniques and Design Low-Voltage Low-Power Low-Noise Operational Amplifier
الموضوعات : Majlesi Journal of Telecommunication DevicesSaber Izadpanah Tous 1 , Mahmoud Behroozi 2 , Hooman Nabovati 3 , Vahid Asadpour 4
1 - Sadjad Institute for Higher Education
2 - Sadjad Institute for Higher Education
3 - Sadjad Institute for Higher Education
4 - Sadjad Institute for Higher Education
الکلمات المفتاحية: en,
ملخص المقالة :
In this paper an overview of circuit techniques dedicated to design low-power low-voltage is presented. These techniques (a) dynamic threshold voltage MOSFET (DTMOS) (b) bulk-driven and (c) current-driven bulk (CDB) are applied to design low-power low-voltage and low-noise CMOS operational amplifier (op amp) using sub-threshold region of MOSFET for bio-medical instrumentation operating with a 0.6 V supply. The operational amplifier is designed and simulated using TSMC 0.18μm CMOS technology. With DTMOS technique, the open loop gain is 60.51 dB, the unity gain-bandwidth (UGBW) is 12.08 kHz, phase margin is 52.3 degree and power consumption is 53.21 nW. With bulk-driven technique, the open loop gain is 49.04 dB, the unity gain-bandwidth is 3.32 kHz, phase margin is 71.96 degree and power consumption is 53.3 nW. With CDB technique, the open loop gain is 53.54 dB, the unity gain-bandwidth is 19 kHz, phase margin is 50 degree and power consumption is 55.79 nW. DTMOS technique provides high open loop gain, CDB technique provides high unity gain-bandwidth and bulk-driven technique provides better phase margin. Also DTMOS technique has less input-referred noise than the other methods.
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