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Article

A Bibliography of the Work Done on Externally-Linear-Internally-Nonlinear Circuits during 1979-2014

1Department of Electronics and Communication Engineering, Institute of Engineering and Technology, Lucknow, India

2Division of Electronics and Communication Engineering, Netaji Subhas Institute of Technology, Sector 4, Dwarka, New Delhi, India


American Journal of Electrical and Electronic Engineering. 2015, 3(3), 64-71
doi: 10.12691/ajeee-3-3-1
Copyright © 2015 Science and Education Publishing

Cite this paper:
Manoj Kumar Jain, V. K. Singh, Raj Senani. A Bibliography of the Work Done on Externally-Linear-Internally-Nonlinear Circuits during 1979-2014. American Journal of Electrical and Electronic Engineering. 2015; 3(3):64-71. doi: 10.12691/ajeee-3-3-1.

Correspondence to: Raj  Senani, Division of Electronics and Communication Engineering, Netaji Subhas Institute of Technology, Sector 4, Dwarka, New Delhi, India. Email: senani@ieee.org

Abstract

There is a continued demand of analog circuits which are capable of operating at low supply voltages and have low-power consumption and large dynamic range. There are several techniques of designing circuits satisfying such requirements a majority of which fall into the general category of externally-linear-internally-nonlinear (ELIN) circuits. In this paper, we present a bibliography of ELIN circuits which covers log-domain, exponential state-space domain, square root domain and other related circuits, based upon the work done during 1979 to 2014. It is hoped that this compilation (with a brief overview) should be useful to research scholars, educators, students, practicing engineers and anybody who is interested in knowing about the current state-of-the- art of log domain, translinear and square root domain circuits.

Keywords

References

[1]  Adams, R.W., “Filtering in the Log-domain”, Preprint #1470 presented at the 63rd AES conference, New York, NY, 1979.
 
[2]  Gilbert, B., “Translinear circuits: A proposed classification”, Electronics Letters, 11 (1), 14-16, 1975.
 
[3]  Tsividis, Y.P., Gopinathan, V. and Tόth, L., “Companding in signal processing”, Electronics Letters, 26 (17), 1331-1332, 1990.
 
[4]  Seevinck, E., “Companding current-mode integrator: A new circuit principle for continuous-time monolithic filters”, Electronics Letters, 26 (24), 2046-2047, 1990.
 
[5]  Frey, D.R., “Log-domain filtering: An approach to current-mode filtering”, IEE Proceedings G Circuits, Devices and Systems, 140 (6), 406-416, 1993.
 
Show More References
[6]  Frey, D.R., “A general class of current mode filters”, IEEE International Symposium on Circuits and Systems (ISCAS’93), 2, 1435-1438, 1993.
 
[7]  Toumazou, C., Ngarmnil, J. and Lande, T.S., “Micropower log-domain filter for electronic cochlea”, Electronics Letters, 30 (22), 1839-1841, Oct. 1994.
 
[8]  Frey, D., “Current-mode class AB second order filter”, Electronics Letters, 30 (3), 205-206, 1994.
 
[9]  Frey, D., “A 3.3 volt electronically tunable active filter usable to beyond 1 GHz”, International Symposium on Circuits and Systems (ISCAS’94), 5, 493-496, 1994.
 
[10]  Pookaiyaudom, S. and Mahattanakul, J., “A 3.3 volt high-frequency capacitor-less electronically-tunable log-domain oscillator”, International Symposium on Circuits and Systems (ISCAS’95), 2, 829-832, 1995.
 
[11]  Ngarmnil, J., Toumazou, C. and Lande, T.S., “A fully tuneable micropower log-domain filter”, Twenty-first European Solid-State Circuit Conference (ESSCIRC’95), Lille, France, 86-89, 19-21 Sep., 1995.
 
[12]  Perry, D. and Roberts, G.W., “Log-domain filters based on LC ladder synthesis”, Proceeding of the IEEE International Symposium on Circuits and Systems (ISCAS '95), Scattle, WA, 1, 311-314, 30 Apr.-3May, 1995.
 
[13]  Thanachayanont, A., Pookaiyaudom, S. and Toumazou C., “State-space synthesis of log-domain oscillators”, IET Electronics Letters, 31 (21), 1797-1799, 1995.
 
[14]  Tsividis, Y., “General approach to signal processors employing companding”, Electronics Letters, 31 (18), 1549-1550, 1995.
 
[15]  Tsividis, Y., “On linear integrators and differentiators using instantaneous companding”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 42 (8), 561-564, 1995.
 
[16]  Punzenberger, M. and Enz, C., “A new 1.2 V BiCMOS log-domain integrator for companding current-mode filters”, IEEE International Symposium on Circuits and Systems (ISCAS '96) Connecting the World, Atlanta, GA, 1, 125-128, 12-15 May, 1996.
 
[17]  Fried, R., Python, D. and Enz, C.C., “Compact log-domain current mode integrator with high transconductance-to-bias current ratio”, Electronics Letters, 32 (11), 952-953, 1996.
 
[18]  Frey, D.R., “Explicit log domain root-mean-square detector”, United States Patent, 1996.
 
[19]  Frey, D.R., “Log domain filtering for RF applications”, IEEE Journal Solid-State Circuits, 31 (10), 1468-1475, 1996.
 
[20]  Ngarmnil, J. and Toumazou, C., “Micro power log-domain active inductor”, Electronics Letters, 32 (11), 953-955, 1996.
 
[21]  Liu, S.I. and Liao, Y.H., “Table-based log-domain linear transformation filter”, Electronics Letters, 32 (19), 1771-1772, 1996.
 
[22]  Perry, D. and Roberts, G.W., “The design of log-domain filters based on the operational simulation of LC ladders”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 43 (11), 763-774, 1996.
 
[23]  Frey, D., “Exponential state space filters: A generic current mode design strategy”, IEEE Transaction on Circuits and Systems I: Fundamental Theory and Applications, 43 (1), 34-42, 1996.
 
[24]  Mulder, J., van der Woerd, A.C., Serdijn, W.A. and van Roermund, A.H.M., “An RMS-DC converter based on the dynamic translinear principle”, Proceeding of the 22nd European Solid-State Circuits Conference (ESSCIRC`96), Neuchatel, Switzerland, 17-19 Sept., 1996.
 
[25]  Mulder, J., van der Woerd, A.C., Serdijn, W.A. and van Roermund, A.H.M., “Current-mode companding √x-domain integrator”, Electronics Letters, 32 (3), 198-199, 1996.
 
[26]  Mahattanakul, J., Toumazou, C. and Pookaiyaudom, S., “Low-distortion current-mode companding integrator operating at fT of BJT”, Electronics Letters, 32 (21), 2019-2021, 1996.
 
[27]  van der Woerd, A.C., Mulder, J., Serdijn, W.A. and van Roermund, A.H.M., “Recent trends in translinear circuits”, in Proc. Electronics-ET’96, Sozopol, Bulgaria, 1, 14-21, 1996.
 
[28]  Frey, D.R. and Steigerwald, L., “An adaptive analog notch filter using log filtering”, IEEE International Symposium on Circuits and Systems (ISCAS’96) Connecting the World, Atlanta, GA, 1, 297-300, 12-15 May, 1996.
 
[29]  Frey, D.R., “Log-filtering using gyrators”, Electronics Letters, 30 (1), 26-28, 1996.
 
[30]  Mulder, J., Serdijn, W.A., van der Woerd, A.C., and van Roermund, A.H.M., “Dynamic translinear RMS-DC converter”, Electronics Letters, 32 (22), 2067-2068, 1996.
 
[31]  Punzenberger, M. and Enz, C.C., “A 1.2-V low-power BiCMOS class AB log-domain filter”, IEEE Journal Solid-State Circuits, 32 (12), 1968-1978, 1997.
 
[32]  Thanachayanont, A., Payne, A. and Pookaiyaudom, S., “A current-mode phase-locked loop using a log-domain oscillator”, Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS '97), 1, 277-280, 9-12 Jun., 1997.
 
[33]  Drakakis, E.M., Payne, A.J. and Toumazou, C., “Bernoulli operator: a low-level approach to log-domain processing”, Electronics Letters, 33 (12), 1008-1009, 1997.
 
[34]  Leung, V.W., El-Gamal M. and Roberts, G.W., “Effects of transistor non-idealities on log-domain filters”, Proceedings of IEEE International Symposium on Circuits and Systems (ISCAS '97), 1, 109-112, 9-12 Jun., 1997.
 
[35]  Mahattanakul, J. and Toumazou, C., “Modular log-domain filters”, Electronics Letters, 33 (13), 1130-1131, 1997.
 
[36]  Frey, D.R. and Tsividis, Y.P., “Syllabically companding log domain filter using dynamic biasing”, Electronics Letters, 33 (18), 1506-1507, 1997.
 
[37]  Mulder, J., van der Woerd, A.C., Serdijn, W.A. and van Roermund, A. H. M., “General current-mode analysis method for translinear filters”, IEEE Transaction on Circuits and Systems I: Fundamental Theory and Applications, 44 (3), 193-197, 1997.
 
[38]  Serdijn, W.A., Broest, M., Mulder, J., van der Woerd, A.C. and van Roermund, A.H.M., “A low-voltage ultra-low-power translinear integrator for audio filter applications”, IEEE Journal of Solid-State Circuits, 32 (4), 577-581, 1997.
 
[39]  Payne, A. and Thanachayanont, A., “Translinear circuit for phase detection”, Electronics Letters, 33 (18), 1507-1509, 1997.
 
[40]  Tsividis, Y., “Externally linear, time-invariant systems and their application to companding signal processors”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 44 (2), 65-85, 1997.
 
[41]  Mulder, J., van der Woerd, A.C., Serdijn, W.A. and van Roermund, A.H.M., “An RMS-DC converter based on the dynamic translinear principle”, IEEE Journal of Solid-State Circuits, 32 (7), 1146-1150, 1997.
 
[42]  Mulder, J., Serdijn, W.A., van der Woerd, A.C. and van Roermund, A. H. M., “A syllabic companding translinear filter”, Proceeding of IEEE International Symposium on Circuits and Systems (ISCAS’97), 1, 101-104, 9-12 Jun., 1997.
 
[43]  Mahattanakul, J. and Toumazou, C., “Instantaneous companding and expressing: A dual approach to linear integrator synthesis”, Electronics Letters, 33 (1), 4-5, 1997.
 
[44]  Ruymbeke, G. van, Enz, C., Krummenacher, F. and Declerq, M., “A BiCMOS programmable continuous-time filter using image-parameter method synthesis and voltage-companding technique”, IEEE Journal of Solid-State Circuits, 32 (3), 377-387, 1997.
 
[45]  Mulder, J., Kouwenhoven, M.H.L. and van Roermund, A.H.M., “Signal x noise intermodulation in translinear filters”, Electronics Letters, 33 (14), 1205-1207, 1997.
 
[46]  Punzenberger, M. and Enz, C.C., “A compact low-power BiCMOS log-domain filter”, IEEE Journal Solid-State Circuits, 33 (7), 1123-1129, 1998.
 
[47]  Germanovix, W., O'Neill, G., Toumazou, C., Drakakis, E.M., Kitney, R.I. and Lande, T.S., “Analogue micro powered log-domain tone controller for auditory prostheses”, Electronics Letters, 34 (11), 1051 - 1052, 1998.
 
[48]  Fox, R.M., “Design-oriented analysis of log-domain circuits”, IEEE Transactions Circuits and Systems II: Analog and Digital Signal Processing, 45 (7), 918-921, 1998.
 
[49]  Punzenberger, M. and Enz, C., “Log-domain filters for low-voltage low-power applications”, IEEE International Conference on Electronics, Circuits and Systems, Lisboa, 1, 41-44, 1998.
 
[50]  Frey, D.R., “State-space synthesis and analysis of log-domain filters”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 45 (9), 1205-1211, 1998.
 
[51]  Frey, D.R., “Synthesis of distortion compensated log-domain filters using state space techniques”, Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS '98), Monterey, CA, 1, 321-324, 31 May-3 Jun.,1998.
 
[52]  El-Gamal, M. and Roberts, G.W., “Very high-frequency log-domain band pass filters”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 45 (9), 1188-1198, 1998.
 
[53]  Wu, J. and El-Masry, E.I., “Log-domain synthesis of an nth-order filter”, International Journal of Electronics, 84 (4), 359-369, 1998.
 
[54]  Brandtner, T., Papathanasiou, K. and Hamilton, A., “Palmo cell using sampled data log-domain integrators”, Electronics Letters, 34 (8), 733-735, 1998.
 
[55]  Mulder, J., Kouwenhoven, M.H.L., Serdijn, W.A., van der Woerd, A.C. and van Roermund, A.H.M., “Noise considerations for translinear filters”, IEEE Transaction on Circuits and Systems II: Analog and Digital Signal Processing, 45 (9), 1199-1204, 1998.
 
[56]  Serdijn, W.A., Mulder, J., van der Woerd, A.C. and van Roermund, A.H.M., “A wide-tunable translinear second-order oscillator”, IEEE Journal of Solid-State Circuits, 33 (2), 195-201, 1998.
 
[57]  Mulder, J., Serdijn, W.A., van der Woerd, A.C. and van Roermund, A.H.M., “A 3.3 V current-controlled √-domain oscillator”, Analog Integrated Circuits and Signal Processing, 16 (1), 17-28, 1998.
 
[58]  Mulder, J., Serdijn, W.A., van der Woerd, A.C. and van Roermund, A.H.M., “An instantaneous and syllabic companding translinear filter”, IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, 45 (2), 150-154, 1998.
 
[59]  Tόth, L., Tsividis, Y.P. and Krishnapura, N., “On the analysis of noise and interference in instantaneously companding signal processors”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 45 (9), 1242-1249, 1998.
 
[60]  Payne, A., Thanachayanont, A. and Papavassilliou, C., “A 150-MHz translinear phase-locked loop”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 45 (9), 1220-1231, 1998.
 
[61]  Kouwenhoven, M.H.L., Mulder, J. and van Roermund A.H.M., “Noise analysis of dynamically nonlinear translinear circuits”, Electronics Letters, 34 (8), 705-706, 1998.
 
[62]  Surakampontorn, W. and Kumwachara, K., “A dual translinear based true RMS to DC convertor”, IEEE Transactions on Instrumentation and Measurement, 47 (2), 459-464, 1998.
 
[63]  Tsividis, Y.P., “Externally linear integrators,” IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 45 (9), 1181-1187, 1998.
 
[64]  Drakakis, E.M., Payne, A.J. and Toumazou, C., ““Log-domain state-space”: a systematic transistor-level approach for log-domain filtering”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 46 (3), 290-305, 1999.
 
[65]  El-Masry, E.I. and Wu, J., “CMOS micropower universal log-domain biquad”, IEEE Transactions Circuits and Systems I: Fundamental Theory and Applications, 46 (3), 389-392, 1999.
 
[66]  Frey, D., “Distortion compensation in log-domain filters using state-space techniques”, IEEE Transactions Circuits and Systems II: Analog and Digital Signal Processing, 46 (7), 860-869, 1999.
 
[67]  Ferrer, E. and Fox, R.M., “Limit-cycle oscillations in a log-domain-based filter”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 46 (6), 832-836, 1999.
 
[68]  Drakakis, E.M., Payne, A.J. and Toumazou, C., “Log-domain filtering and the Bernoulli cell”, IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, 46 (5), 559-571, 1999.
 
[69]  Enz, C., Punzenberger, M. and Python, D., “Low-voltage log-domain signal processing in CMOS and BiCMOS”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 46 (3), 279-289, 1999.
 
[70]  Mahattanakul, J. and Toumazou, C., “Modular log-domain filters based upon linear Gm-C filter synthesis”, IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, 46 (12), 1421-1430, 1999.
 
[71]  Fox, R.M. and Nagarajan, M., “Multiple operating points in a CMOS log-domain filter”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 46 (6), 705-710, 1999.
 
[72]  Poort, P.J., Serdijn, W.A., Mulder, J., van der Woerd, A.C. and van Roermund, A.H.M., “A 1-V Class-AB Translinear Integrator for Filter Applications”, Analog Integrated Circuits and Signal Processing, 21 (1), 79-90, 1999.
 
[73]  Abuelmáatti, M.T. and Abed, S.M., “A translinear circuit for analogue function synthesis based on a Taylor series”, International Journal Electronics, 86 (11), 1341-1348, 1999.
 
[74]  Serdijn, W.A., Kouwenhoven, M.H.L., Mulder, J. and van Roermund, A.H.M., “Design of high dynamic range fully integratable translinear filters”, Analog Integrated Circuits and Signal Processing, 19 (3), 223-239, 1999.
 
[75]  Mulder, J., Kouwenhoven, M.H.L., Serdijn, W.A. and van der Woerd, A.C., “Nonlinear analysis of noise in static and dynamic translinear circuits”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 46 (3), 266-278, 1999.
 
[76]  Seevinck, E., Vittoz, E.A., du Plessi, M. and Joubert, T.H., “CMOS translinear circuits for minimum supply voltage”, IEEE Transactions on Circuits and systems II: Analog and Digital Signal Processing, 47 (12), 1560-1564, 1999.
 
[77]  Frey, D.R. and Tola, A.T., “A state-space formulation for externally linear class AB dynamical circuits,” IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 46 (3), 306-314, 1999.
 
[78]  Leung, V.W. and Roberts, G.W., “Analysis and Compensation of Log-Domain Biquadratic Filter Response Deviations due to Transistor Non-idealities”, Analog Integrated Circuits and Signal Processing, 22 (2-3), 147-162, 2000.
 
[79]  Drakakis, E.M. and Payne, A.J., “A Bernoulli Cell-Based Investigation of the Non-Linear Dynamics in Log-Domain Structures”, Analog Integrated Circuits and Signal Processing, 22 (2-3), 127-146, 2000.
 
[80]  Fragnie`re, E., Vittoz, E. and van Schaik, A., “A Log-Domain CMOS Transcapacitor: Design, Analysis and Applications”, Analog Integrated Circuits and Signal Processing, 22 (2-3), 195-208, 2000.
 
[81]  Tola, A.T. and Frey, D.R., “A Study of Different Class AB Log Domain First Order Filters”, Analog Integrated Circuits and Signal Processing, 22 (2-3), 163-176, 2000.
 
[82]  Germanovix, W. and Toumazou, C., “Design of a micropower current-mode log-domain analog cochlear implant”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 47 (10), 1023-1046, 2000.
 
[83]  Leung, V.W. and Roberts, G.W., “Effects of transistor nonidealities on high-order log-domain ladder filter frequency responses”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 47 (5), 373-387, 2000.
 
[84]  El-Masry, E.I. and Wu, J., “Fully Differential Class-AB Log-Domain Integrator”, Analog Integrated Circuits and Signal Processing, 25 (1), 35-46, 2000.
 
[85]  Frey, D., “Future implications of the log domain paradigm”, IEE Proceedings - Circuits, Devices and Systems, 147 (1), 65-72, 2000.
 
[86]  El-Masry, E.I. and Wu, J., “Low Voltage Micropower Log-Domain Filters”, Analog Integrated Circuits and Signal Processing, 22 (2-3), 209-220, 2000.
 
[87]  Krishnapura, N., Tsividis, Y. and Frey, D.R., “Simplified technique for syllabic companding in log-domain filters”, Electronics Letters, 36 (15), 1257-1259, 2000.
 
[88]  Edwards R.T. and Cauwenberghs, G., “Synthesis of Log-Domain Filters from First-Order Building Blocks”, Analog Integrated Circuits and Signal Processing, 22 (2-3), 177-186, 2000.
 
[89]  Masmoudi, D., Serdijn, W.A., Mulder, J., van der Woerd, A.C., Tomas, J. and Dom, J.P., “A new current-mode synthesis method for dynamic translinear filters and its applications in hearing instruments”, Analog Integrated Circuits and Signal Processing, 22, 221-229, 2000.
 
[90]  Mulder, J., Serdijn, W.A., van der Woerd, A.C. and van Roermund, A.H.M., “Dynamic Translinear Circuits-An Overview”, Research Perspectives on Dynamic Translinear and Log-Domain Circuits, Analog Integrated Circuits and Signal Processing, 22 (2-3), 5-20, 2000.
 
[91]  El-Gamal, N.M., Baki, R.A. and Bar-Dor, A., “30-100-MHz NPN-only variable-gain class-AB instantaneous comapanding filters for 1.2-V applications”, IEEE Journal of Solid-State Circuits, 35 (12), 1853-1864, 2000.
 
[92]  Mahattanakul, J. and Toumazou, C., “Instantaneous companding current-mode oscillator based on class-AB transconductor”, Analog Integrated Circuits and Signal Processing, 23 (1), 57-64, 2000.
 
[93]  Tόth, L., Efthivoulidis, G. and Tsividis, Y.P., “Noise analysis of externally linear systems”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 47 (12), 1365-1377, 2000.
 
[94]  Python, D. and Enz, C.C., “A micropower class-AB CMOS log-domain filter for DECT applications”, IEEE Journal of Solid-State Circuits, 36 (7), 1067-1075, 2001.
 
[95]  Krishnapura, N. and Tsividis, Y., “A micropower log-domain filter using enhanced lateral PNPs in a 0.25 μm CMOS process”, IEEE Symposium on VLSI Circuits, Digest of Technical Papers, Kyoto, Japan, 179-182, 14-15 Jun., 2001.
 
[96]  Ng, A.E.J., Sewell, J.I., Drakakis, E.M., Payne and A.J., Toumazou, C., “A unified matrix method for systematic synthesis of log-domain ladder filters”, Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS 2000)Sydney, NSW, 1, 149-152, 6-9 May, 2001.
 
[97]  Li S., Wang Y. and Wu, J., “Design of low-voltage and low-power fully integrated filter based on log-domain current-mode integrator”, Journal of Electronics (China), 18 (4), 346-350, 2001.
 
[98]  Fox, R.M., Ko, H.J. and Eisenstadt, W.R., “Dynamic Current Requirements in Single-Ended Log-Domain Filters”, Analog Integrated Circuits and Signal Processing, 28 (1), 73-81, 2001.
 
[99]  Minch, B.A., “Multiple-input translinear element log-domain filters”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 48 (1), 29-36, 2001.
 
[100]  Mahon, A. and Feely, O., “Nonlinear dynamics of log-domain circuit”, Electronics Letters, 37 (15), 929-930, 2001.
 
[101]  Özoğuz, S., “Simple log-domain chaotic oscillator”, Electronics Letters, 37 (23), 1378-1379, 2001.
 
[102]  Frey, D., Tsividis, Y.P., Efthivoulidis, G. and Krishnapura, N., “Syllabic-companding log domain filters”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 48 (4), 329-339, 2001.
 
[103]  Mulder, J., Serdijn, W.A., van der Woerd, A.C. and van Roermund, A.H.M., “A generalized class of dynamic translinear circuits”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 48 (5), 501-504, 2001.
 
[104]  Diepstraten, F.M., Kuijstermans, F.C.M., Serdijn, W.A., van der Kloet P., van Staveren, A., Neerhoff, F.L., Verhoeven, C.J.M. and van Roermund, A.H.M., “Dynamic Behavior of Dynamic Translinear Circuits: the Linear Time-Varying Approximation”, IEEE Transaction on Circuits and Systems I: Fundamental Theory and Applications, 48 (11), 1333-1337, 2001.
 
[105]  Lόpez-Martin, A.J. and Carlosena, A., “Systematic Design of Companding Systems by Component Substitution”, Analog Integrated Circuits and Signal Processing, 28 (1), 91-106, 2001.
 
[106]  Efthivoulidis, G., Tόth, L. and Tsividis, Y., “Noise in externally linear filters”, Analog Integrated Circuits and Signal Processing, 28 (1), 63-72, 2001.
 
[107]  El-Gamal, M.N. and Roberts, G.W., “A 1.2-V n-p-n-only integrator for log-domain filtering”, IEEE Transactions Circuits and Systems II: Analog and Digital Signal Processing, 49 (4), 257-265, 2002.
 
[108]  Vlassis S. and Psychalinos. C., “A Novel Log-Domain Differentiator”, Analog Integrated Circuits and Signal Processing, 32 (3), 285-287, 2002.
 
[109]  Ng, A.E.J. and Sewell, J.I., “Direct noise analysis of log-domain filters”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 49 (2), 101-109, 2002.
 
[110]  Psychalinos, C. and Vlassis, S., “On the exact realization of LOG-domain elliptic filters using the signal flow graph approach”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 49 (12), 770-774, 2002.
 
[111]  McDonald, E.J. and Minch, B.A., “Synthesis of a translinear analog adaptive filter”, Proceeding of the IEEE International Symposium on Circuits and Systems (ISCAS 2002), Phoenix-Scottsdale, AZ, 3, III-321-III-324, 26-29 May, 2002.
 
[112]  Lόpez-Martin, A.J. and Carlosena, A., “1.5 V CMOS companding filter”, Electronics Letters, 38 (22), 1346-1348, 2002.
 
[113]  Haddad, S.A.P., Houben, R. and Serdijn, W.A., “First derivative Gaussian wavelet function employing dynamic translinear circuits for cardiac signal characterization”, Proceedings of the ProRISC Workshop on Circuits, Systems and Signal Processing, Veldhoven, the Netherlands, 288-291, 28-29 Nov., 2002.
 
[114]  Serra-Graells, F. and Huertas, J.L., “1 V CMOS Subthreshold Log Domain PDM”, Analog Integrated Circuits and Signal Processing, 34 (3), 183-187, 2003.
 
[115]  Baki, R.A. and El-Gamal, M.N., “A low-power 5-70-MHz seventh-order log-domain filter with programmable boost, group delay, and gain for hard disk drive applications”, IEEE Journal of Solid-State Circuits, 38 (2), 205-215, 2003.
 
[116]  Baki, R.A., Beainy, C. and El-Gamal, M.N., “Distortion analysis of high-frequency log-domain filters using Volterra series”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 50 (1), 1-11, 2003.
 
[117]  Serrano-Gotarredona, T. and Linares-Barranco, B., “Log-domain implementation of complex dynamics reaction-diffusion neural networks”, IEEE Transactions on Neural Networks, 14 (5), 1337-1355, 2003.
 
[118]  Grech, I., Micallef, J. and Vladimirova, T., “Low-Power Log-Domain CMOS Filter Bank for 2-D Sound Source Localization”, Analog Integrated Circuits and Signal Processing, 36 (1-2), 99-117, 2003.
 
[119]  Özoğuz, S. and Sengör, N.S., “On the realization of NPN-only log-domain chaotic oscillators”, IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, 50 (2), 291-294, 2003.
 
[120]  Drakakis, E.M. and Burdett, A.J., “Operational DC constraints for a class-A, third-order, observer canonical-form log-domain filter”, IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, 50 (10), 1337-1342, 2003.
 
[121]  Drakakis, E.M. and Burdett, A.J., “Spectral impact of the modulation index upon internal log-domain currents”, IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, 50 (10), 1343-1347, 2003.
 
[122]  Serra-Graells, F., “1 V all-MOS ΣΔ A/D converters in the log-domain”, Analog Integrated Circuits and Signal Processing, 35, 47-57, 2003.
 
[123]  Minch, B.A., “Construction and transformation of multiple-input translinear element networks”, IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, 50 (12), 1530-1537, 2003.
 
[124]  De La Cruz-Blas, C.A., Lopez-Martin, A. and Carlosena, A., “1.5-V MOS translinear loops with improved dynamic range and their applications to current-mode signal processing”, IEEE Transactions on Circuits and Systems II: Analog and Digital Signal Processing, 50 (12), 918-927, 2003.
 
[125]  López-Martín, A.J., Fernández, R., de la Cruz Blas, C.A. and Carlosena, A. “A 1 V Micropower FGMOS Class AB Log-Domain Filter”, Analog Integrated Circuits and Signal Processing, 41 (2-3), 137-145, 2004.
 
[126]  Rodriguez-Villegas, E., Yufera, A. and Rueda, A., “A 1-V micropower log-domain integrator based on FGMOS transistors operating in weak inversion”, IEEE Journal of Solid-State Circuits, 39 (1), 256-259, 2004.
 
[127]  Gerosa, A., Maniero, A. and Neviani, A., “A fully integrated dual-channel log-domain programmable preamplifier and filter for an implantable cardiac pacemaker”, IEEE Transactions on Circuits and Systems I: Regular Papers, 51 (10), 1916-1925, 2004.
 
[128]  Serra-Graells, F., Gόmez, L. and Huertas, J.L., “A true-1-V 300-μW CMOS-subthreshold log-domain hearing-aid-on-chip”, IEEE Journal of Solid-State Circuits, 39 (8), 1271-1281, 2004.
 
[129]  Abshire, P.A., Wong, E.L., Yiming, Z. and Cohen, M.H., “Adaptive log domain filters using floating gate transistors”, Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS '04), 1, I-29 - I-32, 23-26 May, 2004.
 
[130]  Fox, R.M., Ko, H.J. and Eisenstadt, W.R., “Differential log-domain filters with high-gain common-mode feedback”, IEEE Transactions on Circuits and Systems I: Regular Papers, 51 (2), 254-263, 2004.
 
[131]  Psychalinos, C., Fragoulis, N. and Haritantis, I., “Log-domain wave filters”, IEEE Transactions on Circuits and Systems II: Express Briefs, 51 (6), 299-306, 2004.
 
[132]  Fragoulis, N., Psychalinos, C. and Haritantis, I., “Modular log-domain filters realized using wave port terminators”, IEEE Transactions Circuits and Systems I: Regular Papers, 55 (11), 2235-2244, 2004.
 
[133]  Ng, A.E.J., Teplechuk, M.A. and Sewell, J.I., “Unified matrix method for systematic synthesis of log-domain ladder filters”, IEE Proceedings - Circuits, Devices and Systems, 151 (4), 285-293, 2004.
 
[134]  De La Cruz-Blas, C.A., Lopez-Martin, A.J. and Carlosena, A., “Low-voltage CMOS nonlinear transconductors and their application to companding current-mode filters”, Analog Integrated Circuits and Signal Processing, 38 (2-3), 137-147, 2004.
 
[135]  Minch, B.A., “Synthesis of static and dynamic multiple-input translinear element networks”, IEEE Transactions on Circuits and Systems I: Regular Paper, 51 (2), 409-421, 2004.
 
[136]  Serra-Graells, F., Rueda, A. and Huertas, J.L., “Low-voltage CMOS log-companding techniques for audio applications”, Analog Integrated Circuits and Signal Processing, 38 (2-3), 121-135, 2004.
 
[137]  Lόpez-Martín, A.J., De La Cruz-Blas, C.A. and Carlosena, A., “1.2-V 5-μW class-AB CMOS log-domain integrator with multidecade tuning”, IEEE Transactions on Circuits and Systems II: Express Briefs, 52 (10), 665-668, 2005.
 
[138]  Halvorsrød, T., Luzi, W. and Lande, T.S., “A log-domain μbeamformer for medical ultrasound imaging systems”, IEEE Transactions on Circuits and Systems I: Regular Papers, 52 (12), 2563-2575, 2005.
 
[139]  Shoemaker, P., “A Methodology for Long Time Constant Log-Domain Filters in CMOS”, Analog Integrated Circuits and Signal Processing, 42 (2), 161-178, 2005.
 
[140]  Zaghloul, K.A. and Boahen, K.A., “An ON-OFF log domain circuit that recreates adaptive filtering in the retina”, IEEE Transactions on Circuits and Systems I: Regular Papers, 52 (1), 99-107, 2005.
 
[141]  Tola, A.T., Arslanalp, R. and Yilmaz, S.S., “Design of current mode, low voltage and electronically tunable class AB differential type KHN filter in the log domain”, Proceedings of the IEEE 13th Signal Processing and Communications Applications Conference, 131-134, 16-18 May, 2005.
 
[142]  Kontogiannopoulos, N. and Psychalinos, C., “Log-domain filtering by simulating the topology of passive prototypes”, IEEE Transactions on Circuits and Systems I: Regular Papers, 52 (10), 2043-2054, 2005.
 
[143]  Haddad, S.A.P., Bagga, S. and Serdijn, W.A., “Log-domain wavelet bases”, IEEE Transactions on Circuits and Systems I: Regular Papers, 52 (10), 2023-2032, 2005.
 
[144]  Serra-Graells, F. and Huertas, J.L., “Low-Voltage CMOS subthreshold log-domain filtering”, IEEE Transactions on Circuits and Systems I: Regular Papers, 52 (10), 2090-2100, 2005.
 
[145]  Ascoli, A., Mahon, A. and Feely, O., “Nonlinear dynamics of first- and second-order log-domain circuits”, IEEE Transactions on Circuits and Systems I: Regular Papers, 52 (7), 1372-1381, 2005.
 
[146]  Tola, A.T., Arslanalp, R. and Yilmaz, S.S., “A design of differantial type class AB Tow-Thomas filter in the log domain”, International conference on electrical and electronics engineering, Bursa, Turkey, 105-109, 7-11 Dec., 2005.
 
[147]  Qizhang, Y., Eisenstadt, W.R., Fox, R.M. and Tao, Z., “A translinear RMS detector for embedded test of RF ICs”, IEEE Transaction on Instrument and Measurement, 54 (5), 1708-1714, 2005.
 
[148]  Kircay, A. and Cam, U., “A novel first-order log-domain allpass filter”, AEU - International Journal of Electronics and Communications, 60 (6), 471-474, 2006.
 
[149]  Hamilton, T.J., Jin, C. and van Schaik, A., “An analysis of matching in the Tau cell log-domain filter”, Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS 2006), Island of Kos, 421-424, 21-24 May, 2006.
 
[150]  Teplechuk, M.A. and Sewell, J.I., “Approximation of arbitrary complex filter responses and their realisation in log domain”, IEE Proceedings Circuits, Devices and Systems, 153 (6), 583-590, 2006.
 
[151]  Arslanalp, R. and Tola, A.T., “By Using Darlington Topology Improvement of In-Band Gain for the Log Domain Filters,” IEEE 14th Signal Processing and Communications Applications, Antalya, 1-4, 17-19 Apr., 2006.
 
[152]  Psychalinos, C., “Improved building blocks for log-domain linear transformation filters”, Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS 2006), Island of Kos, 1535-1538, 21-24 May, 2006.
 
[153]  Kircay, A., Cam U. and Tola, A.T., “Novel first-order differential class-AB log-domain allpass filters”, AEU - International Journal of Electronics and Communications, 60 (10), 705-712, 2006.
 
[154]  Ascoli, A., Feely O. and Curran, P., “On the Chaotic Behavior of a Third-Order Log-Domain Filter”, Nonlinear Dynamics, 44 (1-4), 45-54, 2006.
 
[155]  Teplechuk, M.A. and Sewell, J.I., “Realisation of asymmetrical complex filters in log-domain”, Proceedings of the IEEE International Symposium on Circuits and Systems (ISCAS 2006), Island of Kos, 4, 21-24 May, 2006.
 
[156]  Kircay, A. and Cam, U., “State-Space Synthesis of Current-Mode First-Order Log-Domain Filters”, Turk J Elec Engin, 14 (3), 399-416, 2006.
 
[157]  Drakakis, E.M., “Systematic derivation of explicit design formulae for log-domain: A 3rd-order lowpass example”, Microelectronics Journal, 37 (7), 646-656, 2006.
 
[158]  Psychalinos, C., “On the transposition of Gm–C filters to DC stabilized log-domain filters”, International Journal of Circuits Theory and Applications, 34, 217-236, 2006.
 
[159]  Psychalinos, C., “Realization of log-domain high-order transfer functions using first-order building blocks and complementary operators”, International Journal of Circuits Theory and Applications, 35, 17-32, 2006.
 
[160]  Kircay, A. and Cam, U., “A Novel Log-Domain First-Order Multifunction Filter”, Electronics and Telecommunications Research Institute (ETRI) Journal, 28 (3), 401-404, 2006.
 
[161]  Groza, R., Festila, L. and Fazakas, A., “A Log-Domain summing-amplifier for serial signal flows”, Inter-Ing 2007, IV-4-2-4, 2007.
 
[162]  Groza, R., Festila, L. and Szopos, E., “Bessel Filter implementation in Log-Domain”, Inter-Ing 2007, IV-3-1-6, 2007.
 
[163]  Feştilă, L., Groza, R., Cirlugea, M. and Fazakas, A., “Modular analysis and design of log-domain circuits based on LIN↔ELIN transformations”, Analog Integrated Circuits and Signal Processing, 50 (3), 231-249, 2007.
 
[164]  Teplechuk, M.A. and Sewell, J.I., “Wave realisations of filters and equalisers in log-domain”, IET Circuits, Devices & Systems, 1 (6), 433-443, 2007.
 
[165]  Zhai, Y. and Abshire, P.A., “Adaptive log domain filters for system identification using floating gate transistors”, Analog Integrated Circuits and Signal Processing, 56 (1-2), 23-36, 2007.
 
[166]  Ascoli, A., Curran, P. and Feely, O., “Modelling the dynamics of log-domain circuits”, International Journal 0f Circuits Theory and Applications, 35 (1), 33-70, 2007.
 
[167]  Tongkulboriboon, S., Pawarangkoon, P. and Kiranon, W., “Externally linear current amplifiers”, International Journal of Electronics, 94 (6), 587-596, 2007.
 
[168]  Shah N.A. and Khanday, F.A., “A DC stabilized log-domain nth-order multifunction filter based on the decomposition of nth-order HP filter function to FLF topology”, International Journal of Circuit Theory and Applications, 37 (10), 1075-1091. 2008.
 
[169]  Psychalinos, C. and Souliotis, G., “A log-domain multiphase sinusoidal oscillator”, AEU - International Journal of Electronics and Communications, 62 (8), 622-626, 2008.
 
[170]  Hongmin, L., Yigang, H. and Sun, Y., “Detection of Cardiac Signal Characteristic Point Using Log-Domain Wavelet Transform Circuits”, Circuits, Systems, and Signal Processing, 27 (5), 683-698, 2008.
 
[171]  Kircay, A. and Cam, U., “Differential Type Class-AB Second-Order Log-Domain Notch Filter”, IEEE Transactions on Circuits and Systems I: Regular Papers, 55 (5), 1203-1212, 2008.
 
[172]  Groza, R., Festila, L., Hintea, S. and Cirlugea, M., “Log-Domain Binary SVM Image Classifier”, Knowledge-Based Intelligent Information and Engineering Systems (Lecture Notes in Computer Science), 5179, 368-375, 2008.
 
[173]  Psychalinos, C., “Low-Voltage Log-Domain Complex Filters”, IEEE Transactions Circuits and Systems I: Regular Papers, 55 (11), 3404-3412, 2008.
 
[174]  Shah, N.A., Iqbal, S.Z. and Parveen, N., “Log-Domain low pass high pass first-order filter”, Indian Journal Pure & Applied Physics, 46 (9), 667 -670, 2008.
 
[175]  Psychalinos, C., “Log-domain linear transformation filters revised: Improved building blocks and comparison results”, International Journal of Circuit Theory and Applications, 36 (2), 119-133, 2008.
 
[176]  Vercauteren, T., Pennec, X., Perchant, A. and Ayache, N., “Symmetric Log-Domain Diffeomorphic Registration: A Demons-based Approach”, Medical Image Computing and Computer-Assisted Intervention-MICCAI-2008, Lecture Notes in Computer Science, 5241, 754-761, 2008.
 
[177]  Farshidi, E. and Sayedi, S.M., “A 1.2 V current-mode true RMS-DC converter based on the floating gate MOS translinear principle”, Microelectronics Journal, 39 (2), 293-298, 2008.
 
[178]  Loizos, D.N., Sotiriadis, P.P. and Cauwenberghs, G., “A translinear SiGe BiCMOS current-controlled oscillator with 80Hz-800MHz tuning range”, Analog Integrated Circuits and Signal Processing, 57 (1-2), 107-115, 2008.
 
[179]  Ip, H.M.D., Drakakis, E.M. and Bharath, A.A., “A 19 nW analogue CMOS log-domain 6th-order Bessel filter without E-minus cells”, Microelectronics Journal, 40 (8), 1170-1174, 2009.
 
[180]  Katsiamis, A.G., Drakakis, E.M. and Lyon, R.F., “A Biomimetic, 4.5 µW, 120+ dB, Log-Domain Cochlea Channel with AGC”, IEEE Journal of Solid-State Circuits, 44 (3), 1006-1022, 2009.
 
[181]  Kircay, A. and Cam, U., “A new 5th-order differential type class-AB log-domain elliptic lowpass filter for video frequency applications”, Analog Integrated Circuits and Signal Processing, 60 (3), 221-229, 2009.
 
[182]  Fragoulis, N., Psychalinos, C. and Haritantis, I., “Analysis and compensation of transistor non-idealities in log-domain wave active filters”, AEU - International Journal of Electronics and Communications, 63 (2), 132-138, 2009.
 
[183]  Georgiou, P. and Toumazou, C., “Chemical log-domain filter”, Electronics Letters, 45 (8), 391-392, 2009.
 
[184]  Tola, A.T., Arslanalp, R. and Yilmaz, S.S., “Current mode high-frequency KHN filter employing differential class AB log domain integrator”, International Journal of Electronics and Communications (AEÜ), 63 (7), 600-608, 2009.
 
[185]  Shah, N.A. and Khanday, F.A., “Log-domain synthesis of nth order universal filter”, Analog Integrated Circuits and Signal Processing, 59 (3), 309-315, 2009.
 
[186]  Frey, D.R. and Drakakis, E.M., “Unifying perspective on log-domain filter synthesis”, Electronics Letters, 45 (17), 861-863, 2009.
 
[187]  Tola, A.T., Arslanalp, R. and Yilmaz, S.S., “Current mode Tow-Thomas biquadratic differential class AB log domain filter”, International Review of Electrical Engineering, 4 (6), 1426-1432, 2009.
 
[188]  Arslanalp, R. and Tola, A.T., “State space representation for log domain filtering synthesis”, Indian Journal of Pure and Applied Physics, 47, 745-752, 2009.
 
[189]  Prommee, P., Sra-ium, N. and Dejhan, K., “High-frequency log-domain current-mode multiphase sinusoidal oscillator”, IET Circuits, Devices & Systems, 4 (5), pp. 440-448, 2010.
 
[190]  Psychalinos, C. and Vlassis, S., “Low-voltage log-domain differentiators”, Analog Integrated Circuits and Signal Processing, 63 (2), 299-306, 2010.
 
[191]  Farshidi, E., “Synthesis of class-AB log-domain filters based on nonlinear transconductance”, Microelectronics Journal, 41 (5), 266-276, 2010.
 
[192]  Fragoulis, N., “Universal log-domain biquad”, Electronics Letters, 46 (7), 487-488, 2010.
 
[193]  Tola, A.T., Yilmaz, S.S. and Arslanalp, R., “Current Mode Log Domain Notch Filter Design Based on Adding Filtering Blocks”, Electronics World, 116 (1896), 42, 2010.
 
[194]  Shah, N.A., Iqbal, S.Z. and Parveen, N., “Log-domain all pass filter based on integrators”, Analog Integrated Circuits and Signal Processing, 67 (1), 85-88, 2011.
 
[195]  Manetti S. and Piccirilli, M.C., “Log-Domain Filter Design Based on Impedance Scaling of LC Ladder Structures”, Circuits, Systems, and Signal Processing, 30 (2), 371-389, 2011.
 
[196]  Psychalinos, C., “Log-domain SIMO and MISO low-voltage universal biquads”, Analog Integrated Circuits and Signal Processing, 67 (2), 201-211, 2011.
 
[197]  Prommee, P., Prapakorn, N. and Swamy, M.N.S., “Log-Domain Current-mode Quadrature Sinusoidal Oscillator”, Radioengineering, 20 (3), 600-607, 2011.
 
[198]  Shah, N.A. and Khanday, F.A., “A Generic Current Mode Design for Multifunction Grounded Capacitor Filters Employing Log-Domain Technique”, Active and Passive Electronic Components, 1-10, 2011.
 
[199]  Farshidi, E., “Generalized Noise Analysis of Log Domain Static Translinear Circuits”, International Scholarly and Scientific & Innovation, World Academy of Science, Engineering and Technology, 5 (4), 177-180, 2011.
 
[200]  Fernández, D., Martínez-Alvarado, L. and Madrenas, J., “A Translinear, Log-Domain FPAA on Standard CMOS Technology”, IEEE Journal of Solid-State Circuits, 47 (2), 490-503, 2012.
 
[201]  Kasimis, C., Souliotis, G. and Psychalinos, C., “Novel log-domain frequency-adaptive filter”, International Journal of Electronics, 99 (2), 197-209, 2012.
 
[202]  Duduk, N. and Tola, A.T., “A Study about Effects of Transistors’ Nonideal Characteristics on Log Domain Filters,” International Conference on Applied Electronics (AE), Pilsen, 69-74, 5-7 Sept., 2012.
 
[203]  Fragoulis, N., “Wave log-domain filters using lattice sections”, International Journal of Circuit Theory and Applications, 40 (4), 385-394, 2012.
 
[204]  Farshidi, E. and Asiaban, H., “A new true RMS-to-DC converter using up-down translinear loop in CMOS technology”, Analog Integrated Circuits and Signal Processing, 70 (3), 385-390, 2012.
 
[205]  Prommee, P. and Wongprommoon, N., “Log-domain All-pass Filter-based Multiphase Sinusoidal Oscillators”, Radioengineering, 22 (1), 14-23, 2013.
 
[206]  Prommee, P. and Dejhan, K., “Single-input Multiple-output Tunable Log-domain Current-mode Universal Filter”, Radioengineering, 22 (2), 474 - 484, 2013.
 
[207]  Giagkoulovits, C. and Psychalinos, C., “0.5V Cardiac Sense Amplifier Realization Using Log-Domain Filtering”, ISRN Biomedical Engineering, 2013, 11 pages, 2013.
 
[208]  Vargas-Bernal, R. and De La Cruz-Blas, C.A., “A survey on the static and dynamic translinear paradigm”, Integrated Circuits for Analog Signal Processing, 289-306, 2013.
 
[209]  Tsirimokou, G., Laoudias, C. and Psychalinos, C., “0.5-V fractional-order companding filters”, International Journal of Circuit Theory and Applications, 2014.
 
[210]  Shaheem, M.A., Savaria, Y. and Hamoui, A.A., “Design and modeling of high-resolution multibit log-domain ΔΣ modulators”, Analog Integrated Circuits and Signal Processing”, 79 (3), 569-582, 2014.
 
[211]  Papadimitriou, K.I. and Drakakis, E.M., “CMOS weak-inversion log-domain glycolytic oscillators: A cytomimetic circuit example”, International Journal of Circuit Theory and Applications, 42 (2), 173-194, 2014.
 
[212]  Eskiyerli, M.H., Payne, A.J. and Toumazou, C., “State space synthesis of integrators based on the MOSFET square law,” Electronics Letters, 32 (6), 505-506, 1996.
 
[213]  Eskiyerli, M. and Payne, A., “Square Root Domain'' Filter Design and Performance,” Analog Integrated Circuits and Signal Processing, 22(2-3), 231-243, 2000.
 
[214]  Psychalinos, C. and Vlassis, S., “A Systematic Design Procedure for Square-Root-Domain Circuits Based on the Signal Flow Graph Approach,” IEEE Transactions on Circuits and Systems-I: Fundamental Theory and Applications, 49(12), 1702-1712, 2002.
 
[215]  Psychalinos, C. and Vlassis, S., “A High Performance Square-Root Domain Integrator,” Analog Integrated Circuits and Signal Processing, 32(1), 97-101, 2002.
 
[216]  De La Cruz-Blas, C.A., Lόpez-Martín, A.J. and Carlosena, A., “1.5 V tunable Square-Root Domain filter,” Electronics Letters, 40(4), 213-214, 2004.
 
[217]  Mohammed, K.O. and Soliman, A.M., “Realization of Square Root Domain Filters from Passive Filters,” Frequenz, 58(11-12), 272-276, 2004.
 
[218]  Vlassis, S. and Psychalinos, C., “A Square-Root Domain Differentiator Circuit,” Analog Integrated Circuits and Signal Processing, 40(1), 53–59, 2004.
 
[219]  De La Cruz-Blas, C.A., López-Martín, A.J. and Carlosena, A., “1.5-V Square-Root Domain Second-Order Filter With On-Chip Tuning,” IEEE Transactions on Circuits and Systems-I: Regular Papers, 52(10), 1996-2006, 2005.
 
[220]  Yu, G.J., Huang, C.Y., Liu, B.D. and Chen, J.J., “Design of Square-Root Domain Filters,” Analog Integrated Circuits and Signal Processing, 43(1), 49-59, 2005.
 
[221]  Mohammed, K.O. and Soliman, A.M., “A Tunable Square Root Domain Oscillator,” Analog Integrated Circuits and Signal Processing, 43(1), 91-95, 2005.
 
[222]  Yu, G.J., Huang, C.Y., Chen, J.J. and Liu, B.D., “Design of Current-Mode Square-Root Domain Band-Pass Filter with Reduced Voltage,” Analog Integrated Circuits and Signal Processing, 44(3), 239–250, 2005.
 
[223]  Al-Gahtani, M.A., “Class-AB Square Root Domain Filter,” WSEAS Transaction on Circuits and Systems, 5(8), 1381-1387, 2006.
 
[224]  Ozoguz, S., Abdelrahman, T.M. and Elwakil, A.S., “Novel Approximate Square-Root Domain All-Pass Filter with Application to Multiphase Oscillators,” Analog Integrated Circuits and Signal Processing, 46(3), 297-301, 2006.
 
[225]  Farshidi, E. and Sayedi, S.M., “Class-AB Square root Domain Filters Based on the Floating Gate MOS Translinear Principle,” Iranian Journal of Electrical & Electronic Engineering, 2(2), 62-70, 2006.
 
[226]  Ragheb, T.S.A. and Soliman, A.M., “New Square-Root Domain Oscillators,” Analog Integrated Circuits and Signal Processing, 47(2), 165-168, 2006.
 
[227]  Kontogiannopoulos, N. and Psychalinos, C., “Switched-current filters revisited: Square-root domain sampled-data filters,” IEEE Transactions on Circuits and Systems Ii-Express Briefs, 53(12), 1373-1377, 2006.
 
[228]  Psychalinos, C., “Square-root domain wave filters,” Int. J. Circuit Theory and Applications, 35(2), 131-148, 2007.
 
[229]  Psychalinos, C., “Square-Root Domain Operational Simulation of LC Ladder Elliptic Filters,” Circuits, Systems & Signal Processing, 26(2), 263-280, 2007.
 
[230]  Menekay, S., Tarcan, R.C. and Kuntman, H., “The Second Order Low Pass Filter Design with A Novel Higher Precision Square-Root Circuit,” IU-Journal of Electrical & Electronics Engineering, 7(1), 323-329, 2007.
 
[231]  De La Cruz-Blas, C.A., Lόpez-Martín, A., Carlosena, A. and Sarmiento, A., “Multiple operating points in a square-root domain first-order filter,” Int. J. Circ. Theor. Appl., 35(1), 71-91, 2007.
 
[232]  Psychalinos, C., “Design of square-root domain filters by substituting the passive elements of the prototype filter by their equivalents,” Int. J. Circuit Theory and Applications, 36(2), 185-204, 2008.
 
[233]  Stoumpou, E., Khanday, F.A., Psychalinos, C. and Shah, N.A., “A low-voltage square-root domain n-th order multifunction FLF filter topology,” Analog Integrated Circuits and Signal Processing, 61(3), 315-322, 2009.
 
[234]  Yu, G.J., Tsao, Y.J. and Lin, Y.S., “1V Square-Root Domain Low-Pass Filter using Translinear Loop Technology in Biomedical Engineering,” Life Science Journal, 6(4), 92-96, 2009.
 
[235]  Keserlioglu, M.S. and Kircay, A., “The Design of Current-Mode Electronically Tunable First-Order Square-Root-Domain Filters Using State-Space Synthesis Method,” International Review on Modelling and Simulations, 2(2), 124-128, 2009.
 
[236]  Ölmez, S. and Çam, U., “A novel square-root domain realization of first order all-pass filter,” Turk J Elec Eng & Comp Sci, 18(1), 141-146, 2010.
 
[237]  Yu, G.J., “A Systematic Synthesis for High-Order Square-Root Domain Filters with Reduced Voltage,” Life Science Journal, 7(1), 15-29, 2010.
 
[238]  Yu, G.J. and Lin, Y.S. “Low Voltage Tunable Square-Root Domain Band-Pass Filter with Translinear Loop Technique in Biomedical Engineering,” Life Science Journal, 7(1), 30-33, 2010.
 
[239]  Asiaban, H. and Farshidi E., “A New True RMS-to-DC Converter in CMOS Technology,” World Academy of Science, Engineering and Technology, 4(11), 234-237, 2010.
 
[240]  Jelodarian, P. and Farshidi, E., “A Current-mode Continuous-time Sigma-delta Modulator based on Translinear Loop Principle,” World Academy of Science, Engineering and Technology, 4(6), 422-425, 2010.
 
[241]  De La Cruz-Blas, C.A. and Feely, O., “Limit cycle behavior in a class-AB second-order square root domain filter,” Analog Integrated Circuits and Signal Processing, 68(2), 175-181, 2011.
 
[242]  Yilmaz, S.S. and Tola, A.T., “Fifth Order Butterworth Low Pass Square-Root Domain Filter Design,” Elektronika Ir Elektrotechnika, 115(9), 55-58, 2011.
 
[243]  Stoumpou, E. and Psychalinos, C., “Square-root domain linear transformation filters,” International Journal of Circuit Theory and Applications, 39(7), 719-731, 2011.
 
[244]  Yilmaz, S.S., Tola, A.T. and Arslanalp, R., “A Novel Second-Order All-Pass Filter Using Square-Root Domain Blocks,” Radioengineering, 22(1), 179-185, 2013.
 
[245]  Laoudias, C., Psychalinos, C. and Stoumpou, E., “1.5V square-root domain universal biquad filters,” Int. J. Circ. Theor. Appl., 41(3), 307-318, 2013.
 
[246]  Khanday, F.A., Psychalinos, C. and Shah, N.A., “Square-Root-Domain Realization of Single-Cell Architecture of Complex TDCNN,” Circuits Systems and Signal Processing, 32(3), 959-978, 2013.
 
[247]  Shah, N.A. and Khanday, F.A., “Synthesis of High-order all pass filters using Novel Low Voltage Current-Mode Square-Root-Domain low-order all pass Filters”, Maejo International Journal of Science and Technology, 7(03), 385-395, 2013.
 
[248]  Farshidi, E. and Manoochehri, S., “A New Approach for Current-Mode SRD Filters,” International Journal of Electronics Communications and Electrical Engineering, 3(12), 1-10, 2013.
 
[249]  >Kircay, A., Keserlioglu, M.S. and Çam, U., “A new current-mode square-root-domain general notch filter,” Journal of Circuits, Systems, and Computers, 22(1), 1250072-1-1250072-10, 2013.
 
[250]  Khanday, F.A. and Shah, N. A., “Realization of low-voltage square-root-domain all-pass filters,” Maejo Int. J. Sci. Technol., 7(3), 422-432, 2013.
 
[251]  Kircay, A., “Electronically tunable current-mode square-root-domain first-order multifunction filter,” Int. J. Electronics, 101(2), 212-219, 2014.
 
[252]  Khanday, F.A., Psychalinos, C. and Shah, N.A., “Universal filters of arbitrary order and type employing square-root-domain technique”. Int. J. Electronics, 101(7), 894-918, 2014.
 
[253]  Shaterian, M., Twigg, C.M. and Azhari, J., “MTL-based implementation of current-mode CMOS RMS-to-DC converters,” Int. J. Circ. Theor. Appl., 2014.
 
Show Less References

Article

Novel Single-CFOA-based Sinusoidal Oscillator Capable of Absorbing All Parasitic Impedances

1Department of Electronics and Communication Engineering, Institute of Engineering and Technology, Lucknow, India

2Division of Electronics and Communication Engineering, Netaji Subhas Institute of Technology, Sector 4, Dwarka, New Delhi, India


American Journal of Electrical and Electronic Engineering. 2015, 3(3), 71-74
doi: 10.12691/ajeee-3-3-2
Copyright © 2015 Science and Education Publishing

Cite this paper:
D. K. Srivastava, V. K. Singh, R. Senani. Novel Single-CFOA-based Sinusoidal Oscillator Capable of Absorbing All Parasitic Impedances. American Journal of Electrical and Electronic Engineering. 2015; 3(3):71-74. doi: 10.12691/ajeee-3-3-2.

Correspondence to: R.  Senani, Division of Electronics and Communication Engineering, Netaji Subhas Institute of Technology, Sector 4, Dwarka, New Delhi, India. Email: senani@ieee.org

Abstract

Although a large number of single current feedback op-amp (CFOA)-based sinusoidal oscillator circuits have been proposed in the literature, to the best knowledge of the authors, no single-CFOA oscillator configuration has been reported earlier which can absorb all the parasitic impedances of the CFOA in the various external passive elements employed. The major intention of this paper is to report such a circuit. The workability of the proposed circuit has been confirmed by experimental results employing an AD844-type CFOA.

Keywords

References

[1]  Celma, Pedro A. Martinez and Alfonso Carlosena, ‘Current Feedback amplifiers based sinusoidal oscillators’, IEEE Trans. Circuit Syst I, vol.41, no.12, pp. 906-908, 1994.
 
[2]  M.T. Abuelma’atti, A.A. Farooqi and S. M. Al-Shahrani, ‘Novel RC oscillators using the current-feedback operational amplifier’ IEEE Trans. Circuit Syst I, vol.43, no.2, pp.155-157, 1996.
 
[3]  P.A. Martinez, S. Celma and J. Sabadell, ‘Designing sinusoidal oscillator using current feedback Amplifier’, Int.J. Electronics, vol.80, no.5, pp.637-646, 1996.
 
[4]  M.T. Abuelma’atti, A. A. Farooqi and S.M. Al-Shahrani, ‘A Novel low-component-count single-element-controlled sinusoidal oscillator using the CFOA pole’, Int. J. Electronics, vol.80, no.6, pp.747-752, 1996.
 
[5]  M. T. Abuelma’atti and M. H. Khan, ‘Partially active-R grounded –Capacitor CFOA based sinusoidal Oscillators’, Active and Passive Elec. Components, vol.19, pp. 105-109, 1996.
 
Show More References
[6]  M. T. Abuelma’atti and S. M. Al-Shahrani, ‘New CFOA based grounded capacitor single Element controlled Sinusoidal oscillator’, Active and Passive Elec. Components, vol. 20, pp. 119-124, 1997.
 
[7]  M. T. Abuelma’atti and S. M. Al-Shahrani, ‘A minimum component grounded capacitor CFOA based RC Oscillator’, Active and Passive Elec. Components, vol. 19, pp. 247-251, 1997.
 
[8]  M. T. Abuelma’atti and S. M. Al-Shahrani, ‘New CFOA-based sinusoidal oscillator’, Int. J. Electronics, vol.82, no.1, pp.27-32, 1997.
 
[9]  Raj Senani, ‘Realization of a class of Analog signal processing/signal generation circuits: Novel configurations using current feedback op-amps’ Frequenz, vol. 52, pp.196-206, 1998.
 
[10]  M. T. Abuelma’atti and Sa’ad Muhammad Al-Shahrani, ‘Novel CFOA based sinusoidal oscillators’, Int. J. Electronics, vol. 85, no. 4, pp. 437-441, 1998.
 
[11]  A. M. Soliman, ‘Three oscillator families using the current feedback op-amp’, Frequenz, vol. 54, pp. 126-131, 2000.
 
[12]  A. M. Soliman, ‘Current feedback operational amplifier based oscillators' Analog Integrated Circuits & signal processing’, vol.23, pp. 45-55, 2000.
 
[13]  Abdhesh K. Singh and Raj Senani, ‘Active-R Design Using CFOA-Poles: New Resonators, Filters, and Oscillators’, IEEE Trans. Circuits and Sys.- II: Analog and digital signal processing, vol. 48, no. 5, pp. 504-511, 2001
 
[14]  E. O. Günes and Ali Toker, ‘On the realization of oscillators using state equations’, Int. J. Electron. Communication, vol. 56, no.5, pp. 317-326, 2002.
 
[15]  Ali Toker, Oguzhan Cicekoglu, Hakan Kuntman, ‘On the oscillator implementations using a single Current feedback op-amp’, Computers and Electrical Engineering, vol. 28, pp. 375-389, 2002.
 
[16]  D. R. Bhaskar, ‘Realization of second-order sinusoidal oscillator/ Filter with non-interacting controls using CFAs’, Frequenz, vol. 57, no. 1/2, pp. 1-3, 2003.
 
[17]  A. U. Keskin, ‘Single resistance controlled oscillators employing single commercially available current feedback amplifiers without external compensation’ Proceedings of International Conference on Signal processing , vol. 1, no. 2, pp. 23-25, 2003.
 
[18]  Mashhour Bani Amer and Mohammad Ibbini, ‘A Novel Single-Element- Controlled CFOA-Based Square Wave Oscillator’, Third International Conference on Systems, Signals and Devices, Volume IV, 2005.
 
[19]  V. K. Singh, R. K. Sharma, A. K. Singh, D. R. Bhaskar and R. Senani, ‘Two new canonic single-CFOA oscillators with resistor controls’, IEEE Trans. on CAS II: Express Brief, vol.52, no. 860-864, 2005.
 
[20]  R. Senani and R. K. Sharma, ‘Explicit current output sinusoidal oscillator employing only a single CFOA’, IEICE Electronics Express, vol.2, no.1, pp.14-18, 2005.
 
[21]  R. Nandi, T.K. Bandyopadhyay, S.K. Sanyal, Soumik Das, ‘Selective Filters and Sinusoidal Oscillators Using CFA Trans-impedance pole’, Circuits Systems and Signal Processing, vol. 28, pp.349-359, 2009.
 
[22]  R. Nandi, S. K. Sanyal and T. K. Bandyopadhyay, ‘Single CFA-Based Integrator, Differentiator, Filters and Sinusoid Oscillator’, IEEE Trans. on Instrumentation and Measurements, vol. 58, no. 8, pp. 2557-2564, 2009.
 
[23]  D.R. Bhaskar, Raj Senani, A. K. Singh, S. S. Gupta ‘Two Simple Analog Multiplier Based Linear VCOs using a single Current Feedback Op-Amp’, Circuits and Systems, vol. 1, pp. 1-4, 2010.
 
[24]  Dharmesh Kumar Srivastava and V. K. Singh, ‘Single-Capacitor-Controlled Oscillators using a Single CFOA’ International Conference on Circuits, Systems and Simulation IPCSIT vol.7, 2011.
 
[25]  D.K. Srivastava, V. K. Singh and R. Senani, ‘New very low frequency oscillator using only a single CFOA’, American Jour. of Electrical and Electronics Engineering (USA), vol.3, No.2 pp.1-3, 2015.
 
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Article

Design of Robust PID Power System Stabilizer for Multimachine Power System Using HS Algorithm

1Department of Electrical Engineering, Rajasthan Technical University, Kota, India

2Department of Electrical Engineering, Indian Institute of Technology Roorkee, Roorkee, India


American Journal of Electrical and Electronic Engineering. 2015, 3(3), 75-82
doi: 10.12691/ajeee-3-3-3
Copyright © 2015 Science and Education Publishing

Cite this paper:
D. K. Sambariya, R. Prasad. Design of Robust PID Power System Stabilizer for Multimachine Power System Using HS Algorithm. American Journal of Electrical and Electronic Engineering. 2015; 3(3):75-82. doi: 10.12691/ajeee-3-3-3.

Correspondence to: D.  K. Sambariya, Department of Electrical Engineering, Rajasthan Technical University, Kota, India. Email: dksambariya_2003@yahoo.com

Abstract

In this paper, the design of a proportional, derivative and integral (PID) based power system stabilizer (PSS) is carried out using a new Meta heuristic harmony search algorithm (HSA) to optimize the parameters. The design of proposed PID controller is considered with an objective function based on eigenvalue shifting to guarantee the stability of nonlinear plant for a wide range of conditions using HSA. The HSA optimized PIDPSS (HSPIDPSS) controller is applied to the standard IEEE ten-machine thirty nine-bus test power system model in decentralized manner and the performance is compared with a robust fuzzy controller. The robustness is tested by considering four plant conditions with change of active power, active load and faults at different buses of the power system to establish, the superior performance with HSPIDPSS over the FPSS.

Keywords

References

[1]  M. Soliman, A. L. Elshafei, F. Bendary, and W. Mansour, “Robust decentralized PID-based power system stabilizer design using an ILMI approach,” Electric Power Systems Research, vol. 80, pp. 1488-1497, 2010.
 
[2]  J. Pahasa and I. Ngamroo, “Adaptive Power System Stabilizer Design Using Optimal Support Vector Machines Based on Harmony Search Algorithm,” Electric Power Components and Systems, vol. 42, pp. 439-452, 2014/04/04 2014.
 
[3]  P. Kundur, M. Klein, G. J. Rogers, and M. S. Zywno, “Application of power system stabilizers for enhancement of overall system stability,” IEEE Transactions on Power Systems, vol. 4, pp. 614-626, 1989.
 
[4]  A. Bagis, “Tabu search algorithm based PID controller tuning for desired system specifications,” Journal of the Franklin Institute, vol. 348, pp. 2795-2812, 2011.
 
[5]  S. Panda, “Multi-objective evolutionary algorithm for SSSC-based controller design,” Electric Power Systems Research, vol. 79, pp. 937-944, 2009.
 
Show More References
[6]  S. Panda, “Differential evolution algorithm for SSSC-based damping controller design considering time delay,” Journal of the Franklin Institute, vol. 348, pp. 1903-1926, 2011.
 
[7]  J. Zhang, J. Zhuang, H. Du, and S. Wang, “Self-organizing genetic algorithm based tuning of PID controllers,” Information Sciences, vol. 179, pp. 1007-1018, 2009.
 
[8]  D. K. Sambariya and R. Prasad, “Optimal Tuning of Fuzzy Logic Power System Stabilizer Using Harmony Search Algorithm,” International Journal of Fuzzy Systems, pp. 1-14, 2015/06/17 2015.
 
[9]  D. K. Sambariya, R. Gupta, and A. K. Sharma, “Fuzzy Applications to Single Machine Power System Stabilizers,” Journal of Theoretical and Applied Information Technology, vol. 5, pp. 317-324, 2009.
 
[10]  R. Gupta, D. K. Sambariya, and R. Gunjan, “Fuzzy Logic based Robust Power System Stabilizer for Multi-Machine Power System,” in IEEE International Conference on Industrial Technology, ICIT 2006., 2006, pp. 1037-1042.
 
[11]  D. K. Sambariya, “Power system stabilizer design using compressed rule base of fuzzy logic controller,” Journal of Electrical and Electronic Engineering, vol. 3, pp. 52-64, July 1, 2015 2015.
 
[12]  D. K. Sambariya and R. Prasad, “Evaluation of interval type-2 fuzzy membership function & robust design of power system stabilizer for SMIB power system,” Sylwan Journal, vol. 158, pp. 289-307, April 2014 2014.
 
[13]  D. K. Sambariya and R. Prasad, “Power System Stabilizer design for Multimachine Power System using Interval Type-2 Fuzzy Logic Controller,” International Review of Electrical Engineering (IREE), vol. 8, pp. 1556-1565, October 2013 2013.
 
[14]  H. Gozde and M. C. Taplamacioglu, “Comparative performance analysis of artificial bee colony algorithm for automatic voltage regulator (AVR) system,” Journal of the Franklin Institute, vol. 348, pp. 1927-1946, 2011.
 
[15]  W.-D. Chang and S.-P. Shih, “PID controller design of nonlinear systems using an improved particle swarm optimization approach,” Communications in Nonlinear Science and Numerical Simulation, vol. 15, pp. 3632-3639, 2010.
 
[16]  H. Bevrani, T. Hiyama, and H. Bevrani, “Robust PID based power system stabiliser: Design and real-time implementation,” International Journal of Electrical Power & Energy Systems, vol. 33, pp. 179-188, 2011.
 
[17]  Zong Woo Geem, Joong Hoon Kim, and G. V. Loganathan, “A New Heuristic Optimization Algorithm: Harmony Search,” Simulation, vol. 76, pp. 60-68, February 1, 2001 2001.
 
[18]  Z. W. Geem, “Harmony Search Applications in Industry,” in Studies in Fuzziness and Soft Computing, Volume 226, Soft Computing Applications in Industry. vol. 226, B. Prasad, Ed., ed: Springer-Verlag Berlin Heidelberg, 2008, pp. 117-134.
 
[19]  D. K. Sambariya and R. Prasad, “Design of Harmony Search Algorithm based tuned Fuzzy logic Power System Stabilizer,” International Review of Electrical Engineering (IREE), vol. 8, pp. 1594-1607, October 2013 2013.
 
[20]  S. M. Abd-Elazim and E. S. Ali, “A hybrid Particle Swarm Optimization and Bacterial Foraging for optimal Power System Stabilizers design,” International Journal of Electrical Power & Energy Systems, vol. 46, pp. 334-341, 2013.
 
[21]  H. Alkhatib and J. Duveau, “Dynamic genetic algorithms for robust design of multimachine power system stabilizers,” International Journal of Electrical Power & Energy Systems, vol. 45, pp. 242-251, 2013.
 
[22]  L. Wang, R. Yang, Y. Xu, Q. Niu, P. M. Pardalos, and M. Fei, “An improved adaptive binary Harmony Search algorithm,” Information Sciences, vol. 232, pp. 58-87, 2013.
 
[23]  J. Yu and P. Guo, “Improved PSO Algorithm with Harmony Search for Complicated Function Optimization Problems,” in Advances in Neural Networks – ISNN 2012. vol. 7367, J. Wang, G. Yen, and M. Polycarpou, Eds., ed Shenyang, China: Springer-Verlag Berlin Heidelberg, 2012, pp. 624-632.
 
[24]  M. A. Abido, “Robust Design of Power System Stabilizers for Multimachine Power Systems Using Differential Evolution,” in Computational Intelligence in Power Engineering. vol. 302, B. Panigrahi, A. Abraham, and S. Das, Eds., ed: Springer Berlin Heidelberg, 2010, pp. 1-18.
 
[25]  D. K. Sambariya and R. Prasad, “Robust tuning of power system stabilizer for small signal stability enhancement using metaheuristic bat algorithm,” International Journal of Electrical Power & Energy Systems, vol. 61, pp. 229-238, 2014.
 
[26]  A. Khodabakhshian and R. Hemmati, “Multi-machine power system stabilizer design by using cultural algorithms,” International Journal of Electrical Power & Energy Systems, vol. 44, pp. 571-580, 2013.
 
[27]  K. R. Padiyar, Power System Dynamics Stability and Control. Hyderabad, India: BS Publications, 2008.
 
[28]  D. K. Sambariya and R. Prasad, “Robust Power System Stabilizer Design for Single Machine Infinite Bus System with Different Membership Functions for Fuzzy Logic Controller,” Proceedings of 7th International Conference on Intelligent Systems and Control (ISCO 2013) , at Korpagam College of Engineering, Coimbatore, Tamilnadu, India, vol. IEEE Catalog number (Print): CFP1387T-PRT, ISBN (Print): 978-1-4673-4601-6, pp. 13-19, January 4-5, 2013 2013.
 
[29]  D. K. Sambariya and R. Prasad, “Design of PSS for SMIB System Using Robust Fast Output Sampling Feedback Technique,” Proceedings of 7th International Conference on Intelligent Systems and Control (ISCO 2013) at Karpagam College of Engineering, Coimbatore, Tamilnadu, India, vol. IEEE Catalog number (Print): CFP1387T-PRT, ISBN (Print): 978-1-4673-4601-6, pp. 166-171, January 4-5, 2013 2013.
 
[30]  P. Yadav, R. Kumar, S. K. Panda, and C. S. Chang, “An Intelligent Tuned Harmony Search algorithm for optimisation,” Information Sciences, vol. 196, pp. 47-72, 2012.
 
[31]  D. Manjarres, I. Landa-Torres, S. Gil-Lopez, J. Del Ser, M. N. Bilbao, S. Salcedo-Sanz, et al., “A survey on applications of the harmony search algorithm,” Engineering Applications of Artificial Intelligence, vol. 26, pp. 1818-1831, 2013.
 
[32]  J. Fourie, S. Mills, and R. Green, “Harmony filter: A robust visual tracking system using the improved harmony search algorithm,” Image and Vision Computing, vol. 28, pp. 1702-1716, 2010.
 
[33]  J. Fourie, R. Green, and Z. W. Geem, “Generalised Adaptive Harmony Search: A Comparative Analysis of Modern Harmony Search,” Journal of Applied Mathematics, vol. 2013, pp. 1-13, 2013.
 
Show Less References