Low Voltage Low Power Single Ended Operational Transconductance Amplifier for Low Frequency Applications
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This paper presents the designing of a low voltage low power single ended operational transconductance amplifier (OTA) for low frequency application. The designed OTA combines three different schemes i.e. current splitting, current cancellation and source degeneration technique. Source degeneration method using resistor is one of the most simple and ubiquitous technique to linearize the transfer characteristics of OTA. Current splitting technique is utilized to reduce the transconductance of OTA and to improve the linearity. Current cancellation technique is used to further reduce the transconductance. The OTA circuit is operated in sub-threshold region due to the stringent power limitation requirement in integrated circuits. The transconductance of the OTA is 4.5 nA/V with a linear range of +/− 0.25 V. To test the applicability of the proposed OTA, a fifth order Butterworth OTA-C low pass filter is realized. The circuit is operated at a supply voltage of +/− 0.5 V and the power consumption of the filter is 487 nW. The DC gain of the filter is − 6.1 dB with a cutoff frequency of 250 Hz. THD of − 50.61 dB of the OTA-C filter is obtained for a 100 mVpp signal with 100 Hz frequency. The circuit shows the best THD performance with less pass band attenuation for single ended filter circuit. The circuit is simulated in cadence environment using 150 nm CMOS process technology.
KeywordsLow frequency Source degeneration Current splitting Sub-threshold Operational transconductance amplifier
- 1.Jihai, D., Weilin, X., & Baolin, W. (2015). An OTA-C filter for ECG acquisition systems with highly linear range and less pass-band attenuation. Journal of Semiconductor, 36(5), 055006-1–055006-6.Google Scholar
- 2.Kongpoon, M. (2013). A novel OTA-based voltage attenuation technique for very low frequency filtering using low-gm OTA filters. In International symposium on intelligent signal processing and communication systems, 12–15 November, https://doi.org/10.1109/ispacs.2013.6704635.
- 19.Chen, Y., Mak, P. I., D’Amico, S., Zhang, L., Qian, H., & Wang, Y. (2013). A single-branch third-order pole zero low-pass filter with 0.014-mm2 die size and 0.8-kHz (1.25-nW) to 0.94-GHz (3.99-mW) bandwidth-power scalability. IEEE transactions on circuits and systems II: Express briefs, 60(11), 761–765.CrossRefGoogle Scholar
- 21.Naik, S., Bale, S., Dessai, T. R., Kamat, G., &Vasantha, M. H. (2015). 0.5 V 225 nW, 100 Hz lowpass filter in 0.18 um CMOS process. In IEEE international advance computing conference (IACC) (pp. 165–169).Google Scholar