Authors: H. Daoud Dammak, S. Bensalem, S. Zouari, M. Loulou

Abstract:

This paper presents an optimized methodology to folded cascode operational transconductance amplifier (OTA) design. The design is done in different regions of operation, weak inversion, strong inversion and moderate inversion using the gm/ID methodology in order to optimize MOS transistor sizing. Using 0.35μm CMOS process, the designed folded cascode OTA achieves a DC gain of 77.5dB and a unity-gain frequency of 430MHz in strong inversion mode. In moderate inversion mode, it has a 92dB DC gain and provides a gain bandwidth product of around 69MHz. The OTA circuit has a DC gain of 75.5dB and unity-gain frequency limited to 19.14MHZ in weak inversion region.

Keywords: CMOS IC design, Folded Cascode OTA, gm/ID methodology, optimization.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1333058

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References:

[1] M.G.R. Degrauwe et al.., "IDAC: An interactive design tool for analog CMOS circuits," IEEE J.Solid-State circuits, vol. sc-22, no. 6, dec.(1987), pp. 1106-1116.
[2] R.Harjani, R.A. Rutenbar and L.R. Carley, "OASYS: A framework for analog circuit synthesis," IEEE Trans. Computer-Aided Design, vol. 8, no. 12, Dec. (1989), pp. 1247-1266.
[3] H. Y. Koh, C.H Séquin and P.R. Gray, "OPASYN: A compiler for CMOS operational amplifiers," IEEE Trans. Computer-Aided Design, vol. 8, no. 12, Dec. (1990), pp. 113-125.
[4] J.P. Harvey, M.I. Elmasry and B. Leung, "STAIC: An interactive framework for synthesizing CMOS band BiCMOS analog circuits," IEEE Trans.Computer-Aided Design, vol. 11, no. 11, Nov. (1992), pp. 1402-1417.
[5] M. Fakhfakh, M. Loulou, and N. Masmoudi, "Optimizing performances of switched current memory cells through a heuristic," Journal of Analog Integrated Circuits and Signal Processing, Springer Editor, (2006).
[6] R.K. Brayton, G.D. Hachtel and A.L. Sangiovanni-Vincentelli, "A survey of optimization techniques for integrated-circuit design," Proc. IEEE, vol. 69, no. 10, Oct. 1981, pp. 1334-1364.
[7] W. Nye et al.., "DELIGHT.SPICE: An optimization-based system for the design of integrated circuits,"IEEE Trans.Computer-Aided Design, vol. 7, no. 4, Apr. (1988), pp. 501-519.
[8] S.W. Director and G.D. Hachtel, "The simplicial approximation approach to design centering,"IEEE Trans. Circuits Syst. I, vol. Cas-29, no. 2, Feb. (1982),pp. 88-96
[9] K.J.Antreich and R.K Koblitz, "Design centering by yield prediction," IEEE Trans. Circuits Syst. I, vol. Cas-29, no. 2, Feb. (1982), pp. 88-96.
[10] P. Feldmannand S. W. Director," Integrated circuit quality optimization using surface integrals ," IEEE Trans. Computer-Aided Design vol. 12, no. 12,Dec. 1993; pp. (1868-1879).
[11] K.J.Antreich, H.E. Hraeb and C.U. Wieser," Circuit analysis and optimization driven by worst-case distances," IEEE Trans. Computer- Aided Design vol. 13, no. 1, Jan. (1994), pp. 57-71.
[12] A. Dharchoudhury and S.M. Kang, "Worst-case analysis and optimization of VLSI circuit performances," IEEE Trans. Computer- Aided Design vol. 14, no. 4,Apr. (1995), pp. 481-492.
[13] A. Burmen et al.., "Automated robust design and optimization of integrated circuits by means of penalty functions," int. J. Electron. Comm.,57, no. 1, (2003), pp. 47-56.
[14] M. del Mar Hershenson, S.P. Boyd and T.H. Lee, "GPCAD: A tool for CMOS op-amp synthesis," 1998 IEEE/ACM Int. Conf.Comput-Aided Design, New York, (1998), pp. 296-303.
[15] M. del Mar Hershenson, S.P. Boyd and T.H. Lee, "Optimal design of a CMOS op-amp via geometric programming," IEEE Trans. Computer- Aided Design vol. 20, no. 1, Jan. (2001), pp. 1-21.
[16] G. Gielen at al..,"An analogue module generator for mixed analogue/digital ASIC design," Int. J.Circuit theory and App.,vol. 23, no. 4, July-Aug. (1995),pp.269-283.
[17] G.G.E. Gielen, H.C.C. Walscharts and W.M.C. Sansen," Analog circuit design optimization based on symbolic simulation and simulated annealing," IEEE J. Solid-State circuits, vol. 25, no. 3 June (1990), pp. 707-713.
[18] E.S.Ochotta, R.A. Rutenbar and L.R. Carley, "Sunthesis of highperformances analog circuits in ASTRX/OBLX,"IEEE Trans. Computer-Aided Design vol. 15, no. 3, Mar. (1996), pp. 273-294.
[19] G. Debyser and G. Gielen, "Efficient analog circuit synthesis with simultaneous yield and robustness optimization," 1998 IEEE/ACM, Int. Conf. Computer-Aided Design, New York, (1998), pp. 308-311.
[20] R. Schwencker et al.., "Automating the sizing of analog CMOS circuits by consideration of structural constraints," DATE Conf. And Exhibition, 1999, Los Alamitos, (1999), pp. 323-327.
[21] R. Phelps et al., "Anaconda: simulation-based synthesis of analog circuitsvia stochastic pattern search," IEEE Trans. Computer-Aided Design vol. 19, no. 6, June (2000), pp. 703-717.
[22] T. Mukherjee, L.R. Carley and R.A Rutenbar, "Efficient handling of operating range and manufacturing line variations in analog cell synthesis," IEEE Trans. Computer-Aided Design vol. 19, no. 8, Aug. (2000), pp. 825-839.
[23] F. Schenkel et al., "Mismatch analysis and direct yield optimization by spec-wise linearization and feasibility-guided search," Proc. 38th DAC, New York, (2001), pp. 22-38.
[24] P. Mandal and V. Visvanthan, "CMOS op-amp sizing using a geometric programming formulation," IEEE Trans. Computer-Aided Design vol. 20, no. 1, Jan. (2001), pp. 22-38.
[25] Behzad Razavi, "Design of Analog CMOS Integrated Circuit", TheMcGraw-Hill Companies, Inc., United States, (2001), ISBN:0-07- 118815-0.
[26] M. Loulou, S. Ait Ali and N. Masmoudi, "Conception et Optimisation d-un Amplificateur Opérationnel Rail to Rail CMOS Faible Tension Faible Consommation" Journal Scientifique Libannais, le Conseil National de la Recherche Scientifique- Liban Vol. 4, N┬░.1, (2003), pp. 75-90.
[27] Silveira, D. Flandre et P.G.A. Jespers, "A gm/ID based methodology for the design of CMOS analog circuits and application to the synthesis of a SOI micropower OTA", IEEE J. of Solid State Circuits, vol. 31, n. 9, sept. (1996).
[28] M. Banu, J. M. Khoury, and Y. Tsividis, "Fully Differential Operational Amplifier with Accurate Output Balancing," IEEE Journal of Solid State circuits, Vol. 23, No. 6, pp. December (1990).
[29] Y. Libin, M. Steyaert, and W. Sansen, "A 1-V 140-╬╝W 88-dB Audio Sigma-Delta Modulator in 90-nm CMOS", IEEE Journal of Solid State circuit, Vol. 39, NO. 11, November (2004).
[30] Craig Brendan Keogh, "Low-Power Multi-Bit ΣΔ-Modulator Design for portable Audio Application", Stockholm, March (2005).