طراحي يك ناقل جريان تمام تفاضلي نسل دوم و كاربرد ان به عنوان تقويت كننده ابزار دقيق

A Novel Fully Differential Second Generation Current Conveyor and its application as a very High CMRR Instrumentation Amplifier

This paper aims to introduce a novel design of a Fully Differential second generation Current Conveyor (FDCCII) and its application to design a Low Power (LP), very high CMRR, wide band-width Current Mode Instrumentation Amplifier (CMIA). In the proposed circuit, CMRR as the most important property of IA has been greatly improved using a common mode feed forward (CMFF) and common mode feedback (CMFB) techniques verified by a perfect circuit analysis. The FDCCII has been designed using 0.18 um TSMC CMOS Technology with ±1.2 V supply voltages. The simulation of the proposed FDCCII and CMIA have been done in HSPICE LEVEL 49 that achieves for CMIA; a voltage CMRR of 216 dB, voltage CMRR bandwidth of 300 Hz , and differential voltage gain bandwidth of 18.1 MHz . Intrinsic resistance of X-terminals is only 45 Ω. The IA’s power dissipation is 383.4 μW.

This paper aims to introduce a novel design of a Fully Differential second generation Current Conveyor (FDCCII) and its application to design a Low Power (LP), very high CMRR, wide band-width Current Mode Instrumentation Amplifier (CMIA). In the proposed circuit, CMRR as the most important property of IA has been greatly improved using a common mode feed forward (CMFF) and common mode feedback (CMFB) techniques verified by a perfect circuit analysis. The FDCCII has been designed using 0.18 um TSMC CMOS Technology with ±1.2 V supply voltages. The simulation of the proposed FDCCII and CMIA have been done in HSPICE LEVEL 49 that achieves for CMIA; a voltage CMRR of 216 dB, voltage CMRR bandwidth of 300 Hz , and differential voltage gain bandwidth of 18.1 MHz . Intrinsic resistance of X-terminals is only 45 Ω. The IA’s power dissipation is 383.4 μW.