NONLINEAR DISTORTION AND NOISE ANALYSIS OF GENERAL GM-C FILTERS

S. Koziel, S. Szczepanski
Faculty of Electronics, Telecommunications and Inf., Gdansk University of Technology, Gdansk, Poland

E. Sanchez-Sinencio
Department of Electrical Engineering Texas A&M University, College Station, USA

DOI: 10.36724/2664-066X-2021-7-6-2-7

SYNCHROINFO JOURNAL. Volume 7, Number 6 (2021). P. 2-7.

Abstract

Systems such as Gm-C filters are ideally designed to exhibit linear characteristics. However, their components – especially transconductors – are intrinsically nonlinear. Although there exist many approaches that aim at reducing nonlinear effects while dealing with practical design problems, nonlinear distortion cannot be canceled out completely. Thus, it is important to estimate a degradation of filter performance caused by nonlinearities. In this paper we propose a simple and general method to perform a transient analysis of any Gm-C filter structure based on a matrix description and macro-modeling of transconductors. An analytical description of general Gm-C filters with nonlinear transconductors is introduced. A differential system that determines dynamics of a general structure of Gm-C filter is formulated. This allows us to carry out an effective and fast transient analysis of any Gm-C filter using standard numerical methods. The approach can be applied to investigate any non-linear effects in filters. The noise analysis of Gm-C filters in general setting is also presented. The accuracy of the proposed methods is confirmed by comparison with SPICE simulation. Example of application for performance optimization of 4th order Chebyshev filter is given.

Keywords:  Gm-C filters, nonlinear effects, noise analysis.

References

[1] R.L. Geiger, E. Sánchez-Sinencio, ”Active filter design using operational transconductance amplifiers: A tutorial,” IEEE Circuit and Devices Mag., Vol.1, pp.20-32, 1985.
[2] T. Deliyannis, Y. Sun, and J. K. Fidler, Continuous-time active filter design, CRC Press, USA, 1999.
[3] B. Nauta, Analog CMOS filters for very high frequencies, Kluwer Academic Publishers, 1993.
[4] J. Silva-Martinez, M. Steyaert, W. Sansen, High-Performance CMOS Continuous-Time Filters, Kluwer Academic Publishers, Boston/Dordrecht/London, 1993.
[5] Y. Sun (Editor), Design of high frequency integrated analogue filters, The Institution of Electrical Engineers, London, 2002.
[6] Y. P. Tsividis, ”Integrated continuous-time filter design An overview,” IEEE J. Solid-State Circuits, vol. 29, pp. 166-176, Mar. 1994.
[7] E. Sánchez-Sinencio and J. Silva-Martinez, ”CMOS transconductance amplifiers, architectures and active filters: a tutorial,” IEE Proc.-Circuits Dev. Syst., vol. 147, No. 1, pp. 3-12, Feb. 2000.
[8] P. Wambacq, W. Sansen, Distortion Analysis of Analog Integrated Circuits, Kluwer Academic Publishers, 1998.
[9] Y. Palaskas, Y. Tsividis, „Dynamic Range Optimization of Weakly Nonlinear, Fully Balanced, Gm-C Filters With Power Dissipation Constraints”, IEEE Trans. Circuits Syst.-II, Vol.50, No.10, pp.714 -727, Oct.2003.
[10] J. Mahattanakul, C. Bunyakate, „Harmonic injection method: a novel method for harmonic distortion analysis” in Proc. Int. Symp. Circuits Syst. ISCAS, Vol.3, pp.85-88, 2001.
[11] S. Koziel, S. Szczepanski, R. Schaumann, ”General Approach to Continuous-Time Gm-C Filters,” Int. J. Circuit Theory Appl., Vol.31, pp.361-383, July/Aug. 2003.
[12] A. Brambilla, G. Espinosa, F. Montecchi, E. Sánchez-Sinecio, ”Noise optimization in operational transconductance amplifier filters,” in Proc. Int. Symp. Circuits Syst. ISCAS, Vol.1, pp. 118 -121, 1989. [13] Z. Fortuna, B. Macukow, J. Wasowski, Metody Numeryczne, Wydawnictwa Naukowo Techniczne, Warszawa, 1993.
[13] Z. Fortuna, B. Macukow, J. Wasowski, Metody Numeryczne, Wydawnictwa Naukowo Techniczne, Warszawa, 1993.