Tag: common-mode rejection ratio
A Novel Current-Mode Instrumentation Amplifier Based on Operational Floating Current Conveyor,
This paper presents a novel current-mode instrumentation amplifier (CMIA) that utilizes an operational floating current conveyor (OFCC) as a basic building block. The OFCC, as a current-mode device, shows flexible properties with respect to other current- or voltage-mode circuits. The advantages of the proposed CMIA are threefold. First, it offers a higher differential gain and a bandwidth that is independent of gain, unlike a traditional voltage-mode instrumentation amplifier. Second, it maintains a high common-mode rejection ratio (CMRR) without requiring matched resistors, and finally, the proposed CMIA circuit offers a significant improvement in accuracy compared to other current-mode instrumentation amplifiers based on the current conveyor. The proposed CMIA has been analyzed, simulated, and experimentally tested. The experimental results verify that the proposed CMIA outperforms existing CMIAs in terms of the number of basic building blocks used, differential gain, and CMRR.
Published in:
Instrumentation and Measurement, IEEE Transactions on (Volume:54 , Issue: 5 )
- Page(s):
- 1941 – 1949
- ISSN :
- 0018-9456
- INSPEC Accession Number:
- 8601828
- DOI:
- 10.1109/TIM.2005.854254
- Date of Publication :
- Oct. 2005
- Date of Current Version :
- 03 October 2005
- Issue Date :
- Oct. 2005
- Sponsored by :
- IEEE Instrumentation and Measurement Society
- Publisher:
- IEEE
Yehya H. Ghallab, and Wael Badawy, Karan V.I.S. Kaler and Brent J. Maundy, “A Novel Current-Mode Instrumentation Amplifier Based on Operational Floating Current Conveyor,” IEEE Transaction on Instrumentation and Measurement, Volume 4, October 2005, pp. 1941 – 1949.
A Novel Current-Mode Instrumentation Amplifier Based on Operational Floating Current Conveyor,
This paper presents a novel current-mode instrumentation amplifier (CMIA) that utilizes an operational floating current conveyor (OFCC) as a basic building block. The OFCC, as a current-mode device, shows flexible properties with respect to other current- or voltage-mode circuits. The advantages of the proposed CMIA are threefold. First, it offers a higher differential gain and a bandwidth that is independent of gain, unlike a traditional voltage-mode instrumentation amplifier. Second, it maintains a high common-mode rejection ratio (CMRR) without requiring matched resistors, and finally, the proposed CMIA circuit offers a significant improvement in accuracy compared to other current-mode instrumentation amplifiers based on the current conveyor. The proposed CMIA has been analyzed, simulated, and experimentally tested. The experimental results verify that the proposed CMIA outperforms existing CMIAs in terms of the number of basic building blocks used, differential gain, and CMRR.
Published in:
Instrumentation and Measurement, IEEE Transactions on (Volume:54 , Issue: 5 )
- Page(s):
- 1941 – 1949
- ISSN :
- 0018-9456
- INSPEC Accession Number:
- 8601828
- DOI:
- 10.1109/TIM.2005.854254
- Date of Publication :
- Oct. 2005
- Date of Current Version :
- 03 October 2005
- Issue Date :
- Oct. 2005
- Sponsored by :
- IEEE Instrumentation and Measurement Society
- Publisher:
- IEEE
Yehya H. Ghallab, and Wael Badawy, Karan V.I.S. Kaler and Brent J. Maundy, “A Novel Current-Mode Instrumentation Amplifier Based on Operational Floating Current Conveyor,” IEEE Transaction on Instrumentation and Measurement, Volume 4, October 2005, pp. 1941 – 1949.