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2019 | OriginalPaper | Chapter

1. Overview

Author : János Ladvánszky

Published in: Theory of Power Matching

Publisher: Springer International Publishing

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Abstract

In this chapter, a historical overview has been obtained from the appearance of the power matching problem to its various applications. We point out that this is a central problem in circuit theory. The detailed overview makes the placement of our work and its relation to other works easier.

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next chapter Linear, Time Invariant One Ports: A Derivative-Free Proof of the Global Optimum

[Arai79]

Y. Arai et al., High power GaAs FET amplifier for TWT replacement. Fujitsu Sci. Tech. J. 15(3), 63–82 (1979)

[Baranyi86]

A. Baranyi, Modelling of large-signal microwave devices, in Hungarian, Híradástechnika, 6/1986, pp. 273-280

[Belevitch48]

V. Belevitch, Transmission losses in 2n-terminal networks. J. Appl. Phys. 19(7), 636–638 (1948). in Circuit Theory: Foundations and Classical Contributions, ed. by M.E. Van Valkenburg (Dowden, Hutchinson and Ross, Inc., 1974)

[Baudrand70]

H. Baudrand, On the generalizations of the maximum power transfer theorem. Proc. IEEE 58, 1780–1781 (1970)CrossRef

[Boyd84]

S. Boyd, L.O. Chua, C.A. Desoer, Analytical foundations of Volterra series. IMA J. Math. Control Info. 1, 243–282 (1984)CrossRef

[Calvaer83]

A.J. Calvaer, On the maximum loading of active linear electric multiports. Proc. IEEE 71, 282–283 (1983)CrossRef

[Chaffin73]

R.J. Chaffin, W.H. Leighton, Large-signal S-parameter characterization of UHF power transistors, in IEEE MTT International Microwave Symposium, Dig. Tech. Papers, University of Colorado, Boulder, CO, (5 June 1973), pp. 155–157

[Chua79]

L.O. Chua, C.Y. Ng, Frequency domain analysis of nonlinear systems: general theory. Electron. Circuits Syst., 165–185 (1979). https://doi.org/10.1049/ij-ecs:19790030

[Curtice85]

W.R. Curtice, M. Ettenberg, A nonlinear GaAs FET model for use in the design of output circuits for power amplifiers. IEEE Trans. Microwave Theory Tech. 33(12), 1383–1394 (1985)CrossRef

[Cusack74]

J.M. Cusack et al., Automatic load contour mapping for microwave power transistors. IEEE Trans. Microwave Theory Tech. 22(12), 1146–1152 (1974)CrossRef

[Desoer73]

C. A. Desoer: „The maximum power transfer theorem for n-ports”, IEEE Trans. Circuit Theory, 1973, 20328–330

[Desoer83]

C.A. Desoer, A maximum power transfer problem. IEEE Trans. Circuits Syst. CAS-30(10), 757–758 (1983)MathSciNetCrossRef

[Flanders76]

H. Flanders, On the maximal power transfer theorem for n-ports. Circuit Theory Appl 4, 319–344 (1976)MathSciNetCrossRef

[Franz06]

M.O. Franz, B. Schölkopf, A unifying view of Wiener and Volterra theory and polynomial kernel regression. Neural Comput. 18(12), 3097–3118 (2006)MathSciNetCrossRef

[Gelb68]

A. Gelb, W.E. Vander Velde, Multiple-input describing functions and nonlinear system design (McGraw-Hill, New York, 1968)MATH

[Honjo81]

K. Honjo, Y. Takayama, A 25W 5GHz GaAs FET amplifier for a microwave landing system. IEEE Trans. Microwave Theory Tech. 29(6), 579–582 (1981)CrossRef

[Kuo77]

Y.L. Kuo, Frequency-domain analysis of weakly nonlinear networks. IEEE Trans. Circuits Syst.. CS-11(4) 1977; CS-11(5), 2–6 (1977)

[Lin72]

P.M. Lin, Determination of available power from resistive multiports. IEEE Trans. Circuit Theory 19, 385–386 (1972)CrossRef

[Lin85]

P.M. Lin, Competitive power extraction from linear n-ports. IEEE Trans. Circuits Syst. 32, 185–191 (1985)MathSciNetCrossRef

[Mathis72]

B.A. Mathis, H.F. Mathis, Maximum power transfer from a multiple-terminal network to a single impedance. Proc. IEEE 60, 746 (1972)

[Mazumder77]

S.R. Mazumder, P.D. Van der Puije, An experimental method of characterizing nonlinear two-ports and its application to microwave class C transistor power amplifier design. IEEE J. Solid State Circuits 12(5), 576–580 (1977)CrossRef

[Mazumder78]

S.R. Mazumder, P.D. Van der Puije, Two-signal method of measuring the large signal S-parameters of transistors. IEEE Trans. Microwave Theory Tech. 26(6), 417–420 (1978)CrossRef

[Poulin80]

D. Poulin, Load-pull measurements help you meet your match. Microwaves 19, 61–65 (1980)

[Rauscher80]

C. Rauscher, H.A. Willing, Design of broad-band GaAs FET power amplifiers. IEEE Trans. Microwave Theory Tech. 28(10), 1054–1059 (1980)CrossRef

[Rohrer65]

R.A. Rohrer, The scattering matrix normalized to complex n-port load networks. IEEE Trans. Circuit Theory 12, 223–230 (1965)CrossRef

[Rohrer68]

R.A. Rohrer, Optimal matching: a new approach to the matching problem for real time-invariant one-port networks. IEEE Trans. Circuit Theory 15, 118–124 (1968)CrossRef

[Sandberg]

I.W. Sandberg, Multidimensional nonlinear myopic maps, Volterra series, and uniform neural-network approximations, in Intelligent Methods in Signal Processing and Communications, ed. by D. Docampo et al., (Birkhäuser, Boston, 1997)

[Soares77]

R.A. Soares, Novel large signal S-parameter measurement technique aids GaAs power amplifier design, in Proceedings of 6th EuMC, (September 1977), pp. 113–117

[Spinei72]

F. Spinei, On generalizations of the maximum power transfer problem. Proc. IEEE 60, 903–904 (1972)CrossRef

[Takayama76]

Y. Takayama. A new load-pull characterization method for microwave power transistors, in International Microwave Symposium, Dig. Tech. Papers, June 1976, pp. 218–220

[Tserng79]

H.Q. Tserng, Design and performance of microwave power GaAs FET amplifiers. Microw. J 22(6), 94–100 (1979)

[Tucker79]

R.S. Tucker, Third order intermodulation distortion and gain compression in GaAs FET’s. IEEE Trans. Microwave Theory Tech. 27(5), 400–408 (1979)CrossRef

[Tucker80]

R.S. Tucker, Optimum load admittance for a microwave power transistor. Proc. IEEE 68(3), 410–411 (1980)CrossRef

[Tucker81]

R.S. Tucker, RF characterization of microwave power FETs. IEEE Trans. Microwave Theory Tech. 29(8), 776–781 (1981)CrossRef

[Tucker84]

R.S. Tucker, P.D. Bradley, Computer-aided error correction of large-signal load-pull measurements. IEEE Trans. Microwave Theory Tech. 32(3), 296–300 (1984)CrossRef

[Vendelin78]

G.D. Vendelin, Power GaAs FET amplifier design with large signal tuning parameters, in IEEE 1978 Asilomar Conference on Circuits and Systems, Dig. Tech. Papers, Pacific Grove, CA (1978), pp. 139–141

[Vidyasagar74]

M. Vidyasagar, Maximum power transfer in n ports with passive loads. IEEE Trans. Circuits Syst. CAS-21(3), 327–330 (1974)MathSciNetCrossRef

[Volterra27]

V. Volterra, Theory of functionals and of integrals and integro-differential equations. Madrid 1927 (Spanish), translated version reprinted Dover Publications, New York (1959)

[Wyatt83]

J.L. Wyatt. Nonlinear dynamic maximum power theorem, with numerical method, Research Report, MIT, LIDS-P-1331, September 1983

[Wyatt83A]

J.L. Wyatt, Nonlinear dynamic maximum power theorem, with numerical method. Internal report, Massachusetts Institute of Technology, LIDS-P-1331 (1983)

[Wyatt83B]

J.L. Wyatt, L.O. Chua, Nonlinear resistive maximum power theorem, with solar cell application. IEEE Trans. Circuit Syst. 30, 824–828 (1983)CrossRef

[Wyatt88]

J.L. Wyatt, Nonlinear dynamic maximum power theorem. IEEE Trans. Circuits and Syst. 35(5), 563–566 (1988)MathSciNetCrossRef

[Youla59]

D.C. Youla, L.J. Castriota, H.J. Carlin, Bounded Real scattering matrices and the foundation of linear passive network theory. IRE Trans. Circuit Theory CT-6(1), 102–124 (1959)CrossRef

[Zemack80]

D. Zemack, A new load-pull measurement technique eases GaAs characterization. Microw. J. 23(11), 63–67 (1980)

[Ladvanszky85a]

J. Ladvánszky, A. Baranyi, On power matching of nonlinear resistive sources. Proceedings of the European Conference on Circuit Theory and Design. ECCTD’85, Prague, Czechoslovakia, 2–6 September 1985, pp. 186–188

[Ladvanszky85b]

J. Ladvánszky, Nemlineáris rezisztív áramkörök teljesítmény-illesztése (power matching of nonlinear resistive circuits, in Hungarian), a TKI Közleményei, Budapest, 1985/3–4, 53–70. old

[Ladvanszky86a]

J. Ladvánszky, On the extension of the nonlinear resistive maximum power theorem I. Proceedings of the International Symposium on Circuits and Systems, ISCAS’86, San José, California, USA, May 5–7, pp. 257–259, (1986)

[Ladvanszky86b]

J. Ladvánszky, On the extension of the nonlinear resistive maximum power theorem II. Proceedings of the International Colloquium on Microwave Communications, Budapest, Hungary, Aug. 25–29, pp. 251–252 (1986)

[Ladvanszky87a]

J. Ladvánszky, Maximum power theorem - a describing function approach. Proceedings of the European Conference on Circuit Theory and Design, ECCTD’87, Paris, France, September 1–4, pp. 35–40 (1987)

[Ladvanszky87b]

J. Ladvánszky, Teljesítmény-maximalizálás a leírófüggvény-módszer alkalmazásával (Power maximization applying describing function approach, in Hungarian). a TKI Közleményei, Budapest, 1987/2., 61–80. old

[Ladvanszky88a]

J. Ladvánszky, Nemlineáris, mikrohullámú áramkörök tervezésének problémái: teljesítményillesztés, a reflexiós mátrix mérési hibáinak korrekciója (Some problems of nonlinear, microwave circuit design, in Hungarian). kandidátusi értekezés, Magyar Tudományos Akadémia (1988) március 7

[Ladvanszky88b]

J. Ladvánszky, Nemlineáris, mikrohullámú áramkörök hasznos teljesítményének maximalizálása (Maximizing effective power in nonlinear, microwave circuits, in Hungarian). a Bognár Géza Emlékülés kiadványa (Proceedings of the memorial session in honor of Géza Bognár), Budapest (1988). április 20–21., 125–130. old

[Ladvanszky88c]

J. Ladvánszky, Maximum power transfer in weakly nonlinear circuits. Proceedings of the International Symposium on Circuits and Systems, ISCAS’88, Helsinki, Finland, June 7–9, pp. 2723–2726 (1988)

[Ladvanszky89]

J. Ladvánszky, Nemlineáris, mikrohullámú áramkörök teljesítményillesztése (Power matching in nonlinear, microwave circuits, in Hungarian). Híradástechnika, 1989/3., 89–95. old

[Ladvanszky99]

J. Ladvánszky, Maximális teljesítmény-átvitel kis nemlinearitású áramkörökben (Maximum power transfer in weakly nonlinear circuits, in Hungarian). Híradástechnika, 1999/6. 8–12. old

Title: Overview
Author: János Ladvánszky
Publisher: Springer International Publishing
Book: Theory of Power Matching
Print ISBN: 978-3-030-16630-4

Electronic ISBN: 978-3-030-16631-1

Copyright Year: 2019
DOI: https://doi.org/10.1007/978-3-030-16631-1_1