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[ABR 72] ABRAMOWITZ M., STEGUN I., Handbook of Mathematical Functions, Dover Publications, New York, 1972.

[ACK 90] ACKERMAN E., KASEMSET D., WANUGA S., HOGUE D., KOMIAK J., “A high-gain directly modulated L-band microwave optical link”, IEEE MTT-S Int. Microw. Symp. Dig., Dallas, TX, pp. 153-155, 1990.

[ACK 93a] ACKERMAN E., WANUGA S., MACDONALD J., PRINCE J., “Balanced receiver external modulation fiber-optic link architecture with reduced noise figure”, IEEE MTT-S Int. Microw. Symp. Dig., Atlanta, GA, pp. 723-726, 1993.

[ACK 93b] ACKERMAN E., WANUGA S., KASEMSET D., DARYOUSH A., SAMANT N., “Maximum dynamic range operation of a microwave external modulation fiber-optic link”, IEEE Trans. Microw. Theory Tech., vol. 41, n° 8, pp. 1299-1306, August 1993.

[ACK 97] ACKERMAN E., COX C., BETTS G., ROUSSEL H., RAY K., O’DONNEL F., “Input impedance conditions for minimizing the noise figure of an analog optical link”, IEEE MTT-S Int. Microw. Symp. Dig., Denver, CO, pp. 237-240, 1997.

[ACK 98] ACKERMAN E., COX C.H.III, BETTS G., ROUSSELL H., RAY K., O’DONNELL F., “Input impedance conditions for minimizing the noise figure of an analog optical link”, IEEE Trans. Microw. Theory Tech., vol. 46, n° 12, pp. 2025-2031, December 1998.

[ACK 99] ACKERMAN E., “Broadband linearization of a Mach-Zehnder electrooptic modulator”, IEEE Trans. Microw. Theory Tech., vol. 47, n° 12, pp. 2271-2279, December 1999.

[ACK 03a] ACKERMAN E., “The effect of a Mach-Zehnder modulator’s traveling-wave electrode loss on a photonic link’s noise figure”, International Topical Meeting on Microwave Photonics, pp. 321-324, September 2003.

[ACK 03b] ACKERMAN E., “The effective gains and noise figures of individual components in analog photonic links”, International Topical Meeting on Microwave Photonics, Budapest, pp. 369-372, September 2003.

[ACK 05] ACKERMAN E., BETTS G., BURNS W., PRINCE J., REGAN M., ROUSSELL H., COX C.H.III, “Low noise figure, wide bandwidth analog optical link”, IEEE Int. Microw. Photon. Top. Meeting, Seoul, pp. 325-328, 2005.

[ADS] ADVANCED DESIGN SYSTEM — AGILENT, Notice d’utilisation, http://eesof.tm.agilent.com/products/ads_main.html.

[AGR 86] AGRAWAL G.P., DUTTA N.K., Long-wavelength Semiconductor Lasers, Van Nostrand Reinhold, New York, 1986.

[AGR 92] AGRAWAL G.P., Fiber-optic Communication Systems, John Wiley and Sons, New York, 1992.

[ALG 05] ALGANI C., BELHADJ-TAHAR N.E., DESHOURS F., MONTMAGNON J.L., RODUIT P., ALQUIÉ G., FORTIN C., KAZMIERSKI C., “Optimization of the electrode dimensions of an electro-optic organic modulator based on polymers microwave dielectric characterization and electromagnetic simulations”, Proceedings of the European Microwave Conference, vol. 2, 2005.

[ALG 06] ALGANI C., Circuits Micro-ondes, Cours CNAM, Paris, 2006.

[ALG 10] ALGANI C, BILLABERT A.-L., DESHOURS F., CHETTAT H., RUMELHARD C., BLACHE F., ALQUIÉ G., “Main noise influence of the RIN laser diode of an EML transmitter used in an UWB RoF link”, EuMC 2010, 26 September 2010, Paris.

[ALO 09] ALOUINI M., Personal communication, May 2009.

[AO 00] AO J.-P., LIU W.-J., ZENG Q.-M., LI X.-J., ZHAO Y.-L., XU X.-C., LIANG C.-G., “10 Gb/s InAlAs/InGaAs HEMT transimpedance preamplifiers”, 2nd International Conference on Microwave and Millimeter Wave Technology Proceedings, pp. 156-159, 2000.

[ATL] Atlas User’s Manual, Silvaco International, http://www.silvaco.com/products/device_simulation/atlas.html

[AYA 81] AYASLI Y., VORHAUS J.L., MOZZI R., REYNOLDS L., PUCEL R.A., “Monolithic traveling-wave amplifier”, Electronics Letters, vol. 17, pp. 12, 1981.

[BAN 91] BANU M., JALALI B., NOTTENBURG K., HUMPHREY D.A., MONTGOMERY R.K., HAMM R.A., PANISH M.B., “10 Gbit/s bipolar laser driver”, Electronics Letters, vol. 27, n° 3, pp. 278-280, 1991.

[BAN 00] BANEY D.M., GALLION P., TUCKER R.S., “Theory and measurement techniques for the noise figure of optical amplifiers”, Optical Fibre Technology 6, 122-154, pp. 122-154, 2000.

[BAR 94] BARRON C.C., MAHON C.J., THIBEAULT B.J., WANG G., JIANG W., COLDREN L.A., BOWERS J.E., “Resonant-cavity-enhanced pin photodetector with 17 GHz bandwidth-efficiency product”, Electronics Letters, vol. 30, n° 21, pp. 1796-1797, 1994.

[BAR 97] DE BARROS JR L.E.M., PAOLELLA A., FRANKEL M.Y., ROMERO M.A., HERCZFELD R., MADJAR A., “Photoresponse of microwave transistors to high-frequency modulated lightwave carrier signal”, IEEE Trans. on Microw. Theory Tech., vol. 45, n° 8, pp. 1368-1374, 1997.

[BAR 04] BARTON J.S., The integration of Mach-Zehnder modulators with sampled grating DBR lasers, PhD thesis, University of California, 2004.

[BDE 06] Bdeoui A., Etude des éléments d’une liaison optique en micro-ondes, PhD thesis, CNAM, Paris, 2006.

[BDE 07] BDEOUI A., BILLABERT A.-L., POLLEUX J.L., ALGANI C., RUMELHARD C., “Definition of both opto-microwave s-parameters and noise figures for the elements of an IMDD microwave photonic link”, 12^th Microcoll, Budapest, 14-16 May 2007.

[BDE 08] BDEOUI A., BILLABERT A.-L., POLLEUX J.L., ALGANI C., RUMELHARD C., “A new definition of opto-microwave S-parameters and noise figures for a IM-DD microwave photonic link”, Proceedings of the European Microwave Association, vol. 4, 212-220, June 2008.

[BEL 99] BELANGER P.-A., Les fibres optiques: Supplément d’électromagnétisme appliqué, http://copl.gel.ulaval.ca/pab/fibre/fibre.html, 1999.

[BEN 09] BÉNZAZA M., MANDEREAU F., DESHOURS F., ALGANI C., ALQUIÉ G., BILLABERT A-L., “Millimetre-wave band architecture of UWB transmission systems with optical link”, EuMC’2009, 28 September-2 October 2009.

[BER 99] BERTOLOTTI M., The History of the Laser, Institute of Physics, 1999, in English, Taylor & Francis Group, CRC Press, 2004.

[BET 90] BETTS G., COX C.H.III, RAY K., “20 GHz optical analog link using an external modulator”, IEEE Photon. Technol. Lett., vol. 2, n° 12, pp. 923-925, 1990.

[BET 93] BETTS G., O’DONNELL F., “Improvements in passive, low-noise-figure optical links”, Proc. Photon. Syst. Antenna Applicat. Conf., Monterey, CA, pp. 41-43, 1993.

[BET 96] BETTS G., O’DONNELL F., “Microwave analog optical links using suboctave linearized modulators”, IEEE Photon. Technol. Lett., vol. 8, n° 9, pp. 1273-1275, 1996.

[BET 97] BETTS G., DONNELLY J.P., WALPOLE J.N., GROVES S.H., O’DONNEL S.J., MASSAGGIA L.J., BAILEY R.J., NAPOLEONE A., “Semiconductor laser sources for externally modulated microwave analog links”, IEEE Trans. Microw. Theory Tech., vol. 45, n° 8, pp. 1280-1287, 1997.

[BET 02] BETTS G., “LiNbO external modulators and their use in high performance analog links, RF Photonic Technology”, in W. CHANG, Optical Fiber Links, Cambridge University Press, Cambridge, 2002.

[BIA 03] BIAN Z., CHRISTOFFERSON J., SHAKOURI A., “High-power operation of electroabsorption modulators”, Appl. Phys. Lett., vol. 83, pp. 3605-3607, 2003.

[BIB 98] BIBEY M.-D., Transmission optique d’un signal hyperfréquence à haute pureté spectrale, PhD thesis, University of Science and Technology Lille, 1998.

[BIB 99] BIBEY M.B., DEBORGIES F., KRAKOWSKI M., MONGARDIEN D., “Very low phase-noise optical links — experiments and theory”, IEEE Trans. Microw. Theory Tech., vol. 42, n° 12, pp. 2257-2262, 1999.

[BIL 07] BILLABERT A.-L., POLLEUX J.L., RUMELHARD C., ALGANI C., Liaisons photoniques en micro-ondes, Club Optique Micro-ondes de la Société Française d’Optique, Lannion, 2007.

[BIL 09] BILLABERT A.-L., RUMELHARD C., ALGANI C., CHTIOUI M., FEUILLET C., MARCEAUX A., MERLET T., ALOUINI M., Modèles optimisés en gain bruit et non linéarité d’une liaison opto-micro-onde, Club Optique Micro-ondes de la Société Française d’Optique, Besançon, 2009.

[BIL 10] BILLABERT A.-L., CHTIOUI M., RUMELHARD C., ALGANI C., ALOUINI M, LEVESQUE Q., FEUILLET C., MARCEAUX A., MERLET T., “Simulation of microwave optical links and proof of noise figure lower than electrical losses”, International Journal of Microwave and Wireless Technologies, pp. 1-7, Cambridge University Press and the European Microwave Association, 2010.

[BRU 02] BRUM G., FAREC J., “Du plastique à la lumière: les fibres optiques polymers et leurs applications”, Photoniques, SFO, n° 7, pp. 49-55, 2002.

[CAB 03a] CABON B., CHAZELAS J., DOLFI D., “Optoélectronique hyperfréquence: composants”, Techniques de l’Ingénieur, vol. E3-330, pp. 1-19, 2003.

[CAB 03b] CABON B., CHAZELAS J., DOLFI D., “Optoélectronique hyperfréquence: modulation, liaisons et commutation”, Techniques de l’Ingénieur, vol. E3-331, pp. 1-16, 2003.

[CAB 03c] CABON B., CHAZELAS J., DOLFI D., “Optoélectronique hyperfréquence: commande et traitement du signal”, Techniques de l’Ingénieur, vol. E3-332, pp. 1-16, 2003.

[CAB 03d] CABON B., CHAZELAS J., DOLFI D., “Optoélectronique hyperfréquence: composants et fonctions”, Techniques de l’Ingénieur, vol. E3-333, pp. 1-10, 2003.

[CAM 82] CAMPBELL J.C., OGAWA K., “Heterojunction phototransistror for long-wavelength optical receivers”, Journal of Applied Physics, vol. 53, pp. 1203-1208, 1982.

[CAM 05] CAMPBELL J.C., DEMIGUEL S., LI N., “High-speed photodetectors”, ECOC 2005 Proceedings, vol. 3, Paper We 3.6.3, pp. 493-496, 2005.

[CAR] CARENCO A., Effets électro-optiques, Ecole d’été systèmes optiques, disponible à l’adresse, http://www.bibsciences.org/bibsup/opt-coll/pub/3/pdf/l1t3p105_I.pdf.

[CAS 89] CASTAGNE R., DUCHEMIN J.P., GLOANEC M., RUMELHARD C., Circuits intégrés en arséniure de gallium, Masson, Paris, 1989.

[CAS 92] CASAO J.A., DORTA P., CACERES J.-L., SALAZAR-PALMA M., PÉREZ J., “An enhanced GaAs monolithic transimpedance amplifier for low noise and high speed optical communications”, IEEE MTT Digest, pp. 85-88, 1992.

[CHA 91] CHANDRASCKHAR S., HOPPE M.K., DENTAI A.G., JOYNER C.H., QUA G.J., “Demonstration of enhanced performance of an InP/InGaAs heterojunction phototransistor with a base terminal”, IEEE Electron Device Letters, vol. 13, n° 10, 1991.

[CHE 97] CHEN D., FETTERMAN H.R., CHEN A., STEIER W.H., DALTON L.R., WANG W., SHI Y., “Demonstration of 110 GHz electro-optic polymer modulators”, Appl. Phys. Lett. vol. 70, pp. 1474-1476, 1997.

[CHE 99] CHENNAFI N., Contrbution à l’étude physique et à l’optimisation des phototransistors bipolaires à hétérojonction à l’aide d’outils de simulation numérique. Application au dévéloppement d’un schéma équivalent grand signal du phototransistor, PhD thesis, CNAM, 1999.

[CHE 04] CHEN J., WU W., CHEN I., CHUBIN I., CLAWSON A., CHANG W., YU P., “High-power intrastep quantum well electroabsorption modulator using single-sided large optical cavity waveguide”, IEEE Photonics Technology Letters, vol. 16, n° 2, pp. 440-442, 2004.

[CHI 92] CHI M.K., “Effect of electroabsorption on electrorefractive intensity modulators”, IEEE Photonics Technology Letters, vol. 4, pp. 583-585, 1992.

[CHO 94] CHOA F.S., SHIH M.H., JAPRE R.M., TSANG W.T., LOGAN R.A., “Packaging relaxed semiconductor lasers with diluted waveguide structure”, Proceedings of 44^th Electronic Components and Technology Conference, pp. 335-337, 1-4 May 1994.

[CHO 03] CHOU H.F., CHIU Y.J., BOWERS E., “Standing-wave enhanced electroabsorption modulator for 40-GHz optical pulse generation”, IEEE Photonics Technology Letters, vol. 15, pp. 215-217, 2003.

[CHO 07] CHOU H.F., BOWERS E., “High-speed OTDM and WDM networks using traveling-wave electroabsorption modulators”, IEEE Journal of Selected Topics in Quantum Electronics, vol. 13, pp. 58-69, 2007.

[CHU 98] CHUNG H.Y.A., STAREEV G., JOOS J., MAEHNSS J., EBELING K., “Very low threshold current density 1.3 μm-InAsP/InGaAsP strained quantum well GRINSCH lasers grown by gas source MBE”, Indium Phosphide and Related Materials, 1998 International Conference, pp. 706-708, 11-15 May 1998.

[CHU 07] CHUNG H.S., CHANG S.H., PARK J.D., CHU M.-J., KIM K., “Transmission of multiple HD-TV signals over a wired/wireless line millimeter-wave link with 60 GHz”, Journal of Lightwave Technology, vol. 25, n° 11, pp. 3413-3418, November 2007.

[COM 03] COMSIS, Simulateur optique de IPSIS (France), Version 8.7.7, 2003.

[CON 02] CONNELY M.J., Semiconductor Optical Amplifiers, Springer, Boston, MA, 2002.

[COX 90a] COX C.H.III, BETTS G., JOHNSON L., “An analytic and experimental comparison of direct and external modulation in analog fiber-optic links”, IEEE Trans. Microw. Theory Tech., vol. 38, n° 5, pp. 501-509, 1990.

[COX 90b] COX C.H.III, BETTS G., YEE A., “Incrementally lossless, broad-bandwidth analog fiber-optic link”, Proc. IEEE LEOS Summer Top. Meeting, Monterey, CA, pp. 15-16, 1990.

[COX 96] COX C.H.III, ACKERMAN E., BETTS G., “Relationship between gain and noise figure of an optical analog link”, IEEE MTT-S Int. Microw. Symp. Dig., San Francisco, CA, pp. 1551-1554, 1996.

[COX 97] COX C.H.III, ACKERMAN E., HELKEY R., BETTS G., “Techniques and performance of intensity-modulation, direct-detection analog optical links”, IEEE Trans. Microw. Theory Tech., vol. 45, n° 8, pp. 1375-1383, 1997.

[COX 98] COX C.H.III, ROUSSELL H., RAM R., HELKEY R., “Broadband, directly modulated analog fiber optic link with positive intrinsic gain and reduced noise figure”, Proc. IEEE Int. Microw, Photon. Top. Meeting, Princeton, NJ, pp. 157-160, 1998.

[COX 99] COX C.H.III, ACKERMAN E., “Limits on the performance of analog optical links”, Chap. 10, in W.R. STONE, Review of Radio Science 1996-1999, Oxford University Press, Oxford, 1999.

[COX 03] COX C.H.III, “Analog Optical Links: Models, Measures and Limits of Performances”, in VILCOT A., CABON B., CHAZELAS J., Microwave Photonics: From Components to Applications and Systems, pp. 210-219, 2003, Springer/Kluwer Academic Publishers.

[COX 04] COX III C., Analog Optical Links, Cambridge University Press, Cambridge, 2004.

[COX 05] COX C.H.III, ACKERMAN E., BETTS G., “The role of photonic and electronic gain in the design of analog optical links”, Proc. IEEE Avion. Fiber-Opt. Photon. Conf., Minneapolis, MN, pp. 71-72, 2005.

[COX 06] COX C.H.III, ACKERMAN E.I., BETTS G.E., PRINCE J.L., “Limits on the performance of RF-over fiber links and their impact on device design”, IEEE Transactions on Microwave Theory and Techniques, vol. 54, n° 2, pp. 906-920, 2006.

[CRI 99] CRIPPS S.C., RF Power Amplifiers for Wireless Communications, Artech House, Norwood, MA, 1999.

[DAL 03] DALTON L.R., “Novel polymer-based, high speed electro-optic devices”, Proceedings of the 23rd European Conference on Optical Communications/14th International Conference on Integrated Optics and Optical Fibre Communication, vol. 2, pp. 246-249, 2003.

[DAR 90] DARCIE T., BODEEP G., “Lightwave subcarrier CATV transmission systems”, IEEE Trans. Microw. Theory Tech., vol. 38, n° 5, pp. 524-533, 1990.

[DAU 94] DAULASIM K., Caractérisation et modélisation des bruits blancs et en 1/f des diodes lasers à semiconducteurs, PhD thesis, University of Montpellier II, 1994.

[DEC 98] DECOSTER D., “Microwave optoelectronic systems”, 28th European Microwave Conference, Amsterdam, pp. 485-496, 1998.

[DEL 94] DELAGE S.L., BLANCK H., CHARTIER E., CASSETTE S., FLORIOT D., PERREAL Y., PONS D., ROUX P., BOURNE P., CHAUMAS P., “Le transistor bipolaire à hétérojonction GaInP/GaAs. Technologie et performances hyperfréquences”, Revue Technique Thomson-CSF, vol. 26, n° 2, pp. 367-402, 1994.

[DEM 01] DEMIGUEL S., Photodiodes rapides à adaptateur de mode intégré pour les liaisons optiques/radiofréquences à 60GHz et les transmissions numériques à 40Gb/s, PhD thesis, University of Rouen, 2001.

[DEM 03] DEMIGUEL S., LI N., LI X., ZHENG X., KIM J., CAMPBELL J.C., LU H., ANSELM A., “Very high-responsivity evanescently coupled photodiodes integrating a short planar multimode waveguide for high-speed applications”, IEEE Phonics Technology Letters, vol. 15, n° 12, 2003.

[DEN 90] DENTAN M., DE CRÉMOUX B., “Numerical simulation of the nonlinear response of a p-i-n photodiode under high illumination”, Journal of Lightwave Technology, vol. 8, pp. 1137-1144, 1990.

[DES 87] DESURVIRE E., SIMPSON J., BECKER P.C., “High-gain erbium-doped traveling-wave fiber amplifier”, Optics Letters, vol. 12, pp. 888-890, 1987.

[DES 07a] DESHOURS F., ALGANI C., BLACHE F., ALQUIE G., KAZMIERSKI C., JANY C., “Modélisation non-linéaire d’un modulateur à electro-absorption intégré à haut débit”, 19e Colloque International Optique Hertzienne et Diélectriques (OHD 2007), Valence, 2007.

[DES 07b] DESHOURS F., ALGANI C., EL ALAMA M., BLACHE F., ALQUIE G., KAZMIERSKI C., JANY C., “Simulation 3D d’une embase en technologie CPW pour un modulateur à électroabsorption”, 15es Journées Nationales Micro-ondes (JNM 2007), Toulouse, 2007.

[DES 09] DESHOURS F., BILLABERT A.-L., ALGANI C., BLACHE F., RUMELHARD C., ALQUIE G., “A 40 Gbps electroabsorption modulator integrated laser modelling method for optical transmitter in ultra-wide band radio-over-fiber systems”, International Journal of Microwaves and Wireless Technologies, 2009.

[DOL 92] DOLFI D.W., RANGANATH T.R., “50 GHz velocity-matched broad wavelength LiNbO/sub 3/modulator with multimode active section”, Electronics Letters, vol. 28, pp. 1197-1198, 1992.

[DUE 97] DUÊME P., SCHALLER M., MATHOORASING D., BOUCHOULE S., KAZMIERSKI C., MARICOT S., RUMELHARD C., “MMIC GaAs transimpedance amplifiers for optoelectronic applications”, IEEE MTTS Digest, pp. 13-16, 1997.

[DUP 03] DUPONT S., MAGNIN V., FENDLER E., GEORGE F., MARICOT S., VILCOT J.-P., HARARI J., DECOSTER D., “Status on long-wavelength InP waveguide heterojunction phototransistors”, Nefertiti Workshop on Microwave Phototransistors, Budapest University of Technology and Economics, 9 September 2003.

[EBE 93] EBELING K.J., Integrated Opto-electronics, Springer-Verlag, Berlin, 1993.

[EGE 05] EGELS M., DELACRESSONIÈRE B., SABAHUN Y., LECOY P., “Design of an optically frequency or phase-controlled oscillator for hybrid fiber-radio LAN at 5.2GHz”, Microwave and Optical Technology Letters, vol. 45, n° 2, pp. 104-107, 2005.

[ERS 06] ERSHOVA L.B., GROMOV G.G., Optimal Thermoelectric Cooling in Laser Diode Sub-assemblies, http://www.rmtltd.ru/articles/Optimal%20Cooling%20in%20Laser.pdf, 2006.

[FAN 50] FANO R., “Theoretical limitations on the broad-band matching of arbitrary impedances”, J. Franklin Inst., vol. 249, pp. 57-84, 139-154, 1950.

[FAR 93] FARWELL M., CHANG W., HUBER D., “Increased linear dynamic range by low biasing the Mach-Zehnder modulator”, IEEE Photon. Technol. Lett., vol. 5, n° 7, pp. 779-782, 1993.

[FRI 02] FRIGYES I., “Basic microwave properties of optical links: Insertion loss, noise figure, and modulation transfer”, in H. AL-RAWESHIDY and S. KOMAKI, Radio Over Fibre Technologies for Mobile Communications Networks, Artech House, Boston, MA, 2002.

[FUK 66] FUKUI H., “The noise performance of microwave transistors”, IEEE Trans. On Electron Devices, vol. ED-13, pp. 329-341, 1966.

[GEE 83] GEE C.M., THURMOND G.D., YEN H.W., “Traveling-wave electrooptic modulator”, Appl. Opt., vol. 22, pp. 2034-2037, 1983.

[GER 03] GERLACH P., DFB laser integrated electroabsorption modulators, Annual Report 2003 of Optoelectronics Department, University of Ulm, 2003.

[GET 03] GETTY J., JOHANSSON L., SKOGEN E., COLDREN L., “1.55-µm bipolar cascade segmented ridge lasers”, IEEE Journal of Selected Topics in Quantum Electron., vol. 9, n° 5, pp. 1138-1145, 2003.

[GIB 97] GIBONEY K.S., RODWELL M.J., BOWERS J.E., “Traveling-Wave Photodetector Theory”, IEEE Transactions. on Microwave Theory and Techniques, vol. 45, n° 8, pp. 1310-1319, 1997.

[GIR 09] GIRONDIN V., DESHOURS F., ALQUIE G., ALGANI C., BILLABERT A.-L., BLACHE F., “Simulation d’un modulateur à electro-absorption intégré à un laser DFB pour la transmission de signaux optiques ULB par voie optique”, 16es Journées Nationales Micro-ondes (JNM 2009), Grenoble, 2009.

[GOD 08] GODIN J., NODJIADJIM V., RIET M., BERDAGUER P., DRISSE O., DEROULIN E., KONCZYKOWSKA A., MOULU J., DUPUY J.-Y., JORGE F., GENTNER J.-L., SCAVENNEC A., JOHANSEN T., KOZER V., “Submicron InP DHBT technology for high-speed high-swing mixed-signal ICs”, Proceedings of Compound Semiconductor IC Symposium, Monterey, pp. 109-112, 12-15 October 2008.

[GOM 08] GOMES N.J., NKANSAH A., WAKE D., “Radio-Over-MMMF Techniques — Part I: RF to Microwave Frequency Systems”, Journal of Lightwave Technology, vol. 26, n° 15, pp. 2388-2395, 2008.

[GON 03] GONZALEZ C., “HBT phototransistor as an optic/millimetre-wave converter — part I: the device”, in VILCOT A., CABON B., CHAZELAS J., Microwave Photonics: From Components to Applications and Systems, Springer/Kluwer Academic Publisher, 2003.

[GOU 96] GOUTZOULIS A., ZOMP J., JOHNSON A., “An eight-element, optically powered, directly modulated receive UHF fiber-optic manifold”, Microw. J., vol. 39, pp. 74-86, 1996.

[GOU 04] GOURAUD H., Filtrage opto-micro-ondes par synthèse optique de réponse impulsionnelle, PhD thesis, University of Limoges, 2004.

[GOV 93] GOVINDARAJAN M., FORREST S.R., “Design considerations for wide-band p-i-n/HBT monolithic transimpedance optical receivers”, Journal of Lightwave Technology, vol. 11, n° 2, 1993.

[GOW 93] GOWAR J., Optical Communication Systems, 2nd edition, Prentice Hall, New York, 1993.

[GRA 09] GRAY P.R., HURST P.J., LEWIS S.H., MEYER R.M., Analysis and Design of Analog Integrated Circuits, International Student Version, 5th edition, John Wiley and Sons, New York, 2009.

[GUP 81] GUPTA K.C., GARG R., CHADA R., Computer-Aided Design of Microwave Circuits, Artech House, Boston, MA, 1981.

[GUP 96] GUPTA K.C., GARG R., BAHL I., BHARTIA P., Microstrip Lines and Slotlines, Artech House, Boston, MA, 1996.

[HA 81] HA T.T., Solid-State Microwave Amplifier Design, John Wiley and Sons, New York, NY, 1981.

[HAF 05] HÄFELE M., BEILENOFF K., SCHUMACHER H., “GaAs distributed amplifiers with up to 350 GHz gain-bandwidth product for 40 Gb/s LiNbO₃ modulator drivers”, 35^th European Microwave Conference, Paris, pp. 125-128, 2005.

[HAL 82] HALME S.J., “Coherent or incoherent optical fiber communications”, European Microwave Conference, pp. 66-72, 1982.

[HAR 95] HARARI J., JOURNET F., RABII O., HIN G.H., VILCOT J.P., DECOSTER D., “Modeling of waveguide PIN photodetectors under very high optical power”, IEEE Transactions on Microwave Theory and Techniques, vol. 43, n° 9, pp. 2304-2310, 1995.

[HAR 96] HARARI J., HIN G.H., JOURNET F., VANDECASTEELE J., VILCOT J.P., DALLE, C., FRISCOURT M.R., DECOSTER D., “Modeling of microwave top illuminated PIN photodetector under very high optical power”, IEEE Transactions on Microwave Theory and Techniques, vol. 44, n° 8, pp. 1484-1487, 1996.

[HAX 03] HAXHA S., AZIZUR RAHMAN B.M., OBAYYA S.S.A., GRATTAN K.T.V., “Velocity matching of a GaAs electro-optic modulator”, Appl. Opt., vol. 42, pp. 7179-7187, 2003.

[HEL 96] HELKEY R., ROUSSEL H., COX C., AOKI M., SANO H., “Octave bandwidth analog link with a monolithic laser/electroabsorption modulator”, Proceedings of Integrated Photonics Research Conference, pp. 217-219, 1996.

[HEM 89] HEMENWAY B.R., SOLGAARD O., BLOOM D.M., “All-silicon integrated optical modulator for 1.3 μm fiber-optic interconnects”, Appl. Phys. Lett., vol. 55, pp. 349-350, 1989.

[HEN 96] HENRY C.H., KAZARINOV R.F., “Quantum noise in photonics”, Reviews of Modern Physics, vol. 68, n° 3, pp. 801-853, 1996.

[HEN 97] HENRY C.H., KAZARINOV R.F., “The origins of quantum noise in photonics”, LEOS Newsletter, vol. 18, pp. 3-5, 1997.

[HIG 01] HIGUMA K., OIKAWA S., HASHIMOTO Y., NAGATA H., IZUTSU M., “X-cut lithium niobate optical single-sideband modulator”, Electronics letters, vol. 37, n° 8, pp. 515-516, 2001.

[HIN 93] HINCELIN G., Optoélectronique, Cours B1, CNAM/MEDIAS, Conservatoire National des Arts et Métiers, 1993.

[HIN 06] HINCELIN G., Propagation, rayonnement, électromagnétisme, CNAM/MEDIAS, Conservatoire National des Arts et Métiers, 2006.

[HOJ 02] HOJFELDT S., MORK J., “Modelling of carrier dynamics in quantum-well electroabsorption modulators”, IEEE Journal of Selected Topics in Quantum Electronics, vol. 8, pp. 1265-1276, 2002.

[HOU 06] HOUTSMA V.E., LEVEN A., CHEN J., FRACKOVIAK J., TATE A., WEIMANN N.G., CHEN Y.K., “High gain-bandwidth InP waveguide phototransistor”, Indium Phosphide and Related Materials Conference, pp. 229-233, 7-11 May 2006.

[HUC 08] HUCHARD M., WEISS M., PIZZINAT A., MEYER S., GUIGNARD P., CHARBONNIER B., “Ultra-broadband wireless home network based on 60-GHz WPAN cells interconnected via RoF”, Journal of Lightwave Technology, vol. 26, n° 15, pp. 2364-2373, 2008.

[HUI 89] HUIGNARD J.P., Présentation de l’effet électro-optiques, Ecole d’étéoptoélectronique, http://www.bibsciences.org/bibsup/opt-oll/pub/1/pdf/p289.pdf, 1989.

[HUR 97] HURM V., BENZ W., BRONNER W., DAMMANN M., JAKOBUS T., KAUFEL G., KOHLER K., LAO Z., LUDWIG M., RAYNOR B., ROSENZWEIG J., SCHLECHTWEG M., “10 Gbit/s long-wavelength pin-HEMT photoreceiver grown on GaAs”, Electronics Letters, vol. 33, n° 19, pp. 1653-1654, 1997.

[HUR 07] HURTADO A., HENNING I.D., ADAMS M.J., “Two-wavelength switching with 1.55 µm VCSOA”, Electronics Letters, vol. 43, pp. 887-889, 2007.

[HWA 06] HWANG H.-Y., CHIEN J.-C., CHEN T.-Y., LU L.-H., “A CMOS tunable transimpedance amplifier”, IEEE Microwave and Wireless Components Letters, vol. 16, n° 12, pp. 693-695, 2008.

[ISH 00] ISHIBASHI T., FURUTA T., FUSHIMI H., KODAMA S., ITO H., NAGATSUMA T., SCHIMIZU N., MIYAMOTO Y., “InP/InGaAs uni-traveling-carrier photodiodes”, IEICE Trans. Electron., vol. ES3-C, n° 6, pp. 938-949, 2000.

[ITO 00] ITO H., FURUTA T., KODAMA S., ISHIBASHI T., “InP/InGaAs uni-travellingcarrier photodiode with 310 GHz bandwidth”, Electronics Letters, vol. 36, n° 21, pp. 1809-1810, 2000.

[IZU 81] IZUTSU M., SHIKAMA S., SUETA T., “Integrated optical SSB modulator/frequency shifter”, IEEE Journal of Quantum electronics, vol. QE-17, n° 11, pp. 2225-2227, 1981.

[JAC 85] JACKSON K.P., NEWTON S.A., MOSLEHI B., TUR M., CUTLER C.C., GOODMAN J.W., SHAW H.J., “Optical fiber delay-line signal processing”, IEEE Transactions on Microwave Theory and Techniques, vol. MTT-33, n° 3, 1985.

[JAN 02] JANG J.-H., CUEVA G., HOKE W., LEMONIAS P.J., FAY P., ADESIDA I., “Metamorphic graded bandgap InGaAs-InGaAlAs-InAlAs double heterojunction P-i-I-N photodiodes”, Journal of Lightwave Technology, vol. 20, n° 3, pp. 507-514, 2002.

[JOH 28] JOHNSON J.B., “Thermal agitation of electricity in conductors”, Phys. Rev., 32, 97-109, 1928.

[JOH 03] JOHANSSON L., GETTY J., AKULOVA Y., FISH G., COLDREN L., “Sampled-grating DBR laser-based analog optical transmitters”, J. Lightw. Technol., vol. 21, n° 12, pp. 2968-2976, 2003.

[JOI 96] JOINDOT I., JOINDOT M., Les Télécommunications par Fibres Optiques, Dunod, Paris, 1996.

[JUN 08] JUN-WAN L., “Trends in fiber optics: citation analysis of the fiber optic SCI papers (1974-2007)”, 4^th International Conference on Communications, Networking and Mobile Computing (WiCOM’08), pp. 1-4, 12-14 October 2008.

[KAM 94] KAMITSUNA H., YAMAUCHI Y., OGAWA H., “Photodetection characteristics of AlGaAs/GaAs HBTs with various photo-coupling electrode structures”, Asia Pacific Microwave Conference, pp. 1159-1162, 1994.

[KAM 95a] KAMITSUNA H., MATSUOKA Y., YAMAHATA S., KURISHIMA K., “A monolithically integrated photoreceiver realized by InP/InGaAs double-heterostructure bipolar transistor technologies for optical/microwave interaction systems”, GaAs IC Symposium, pp. 185-188, 1995.

[KAM 95b] KAMITSUNA H., “Ultra-Wideband monolithic photoreceivers using HBT-compatible HPT’s with novel base circuits, and simultaneously integrated with an HBT amplifier”, Journal of Lightwave Technology, vol. 13, n° 12, pp. 2301-2307, 1995.

[KAM 00] KAMITSUNA H., MATSUOKA Y., YAMAHATA S., SHIGEKAWA N., “A 82 GHz optical gain cutoff frequency InP/InGaAs double-heterostructure phototransistor (DHPT) and its application to a 40-GHz band OEMMIC photoreceiver”, 30^th European Microwave Conference, Paris, pp. 388-391, 2000.

[KAO 66] KAO K.C., HOCKAM G.A., “Dielectric-fibre surface waveguides for optical frequencies”, Proceedings of IEE, 133, pp. 1151-1158, 1966.

[KAT 92] KATO K., HATA S., KOZEN A., OKU S., MATSUMOTO S., YOSHIDA J., “22 GHz photodiode monolithically integrated with optical waveguide on semi-insulating InP using novel butt-joint structure”, Electronics letters, vol. 28, n° 12, 1992.

[KAT 96] KATO K., “Long-wavelength photodetectors for ultrawide-band systems”, IEICE Transactions on Electronics, vol. E79-C, n° 1, pp. 14-20, 1996.

[KAT 99] KATO K., “Ultrawide-band/high-frequency photodetectors”, IEEE Trans. Microw. Theory Tech., vol. 47, n° 7, pp. 1265-1281, 1999.

[KIM 95] KIMURA S., IMAI Y., MIYAMOTO Y., “Novel distributed baseband amplifying techniques for 40-Gbit/s optical communications”, IEEE GaAs IC Symposium, pp. 193-196, 1995.

[KIM 96a] KIMURA S., IMAI Y., UMEDA Y., ENOKI T., “Loss-compensated distributed baseband amplifier IC’s for optical transmission systems”, IEEE Transaction on Microwave Theory and Techniques, vol. 44, n° 10, pp. 1689-1693, 1996.

[KIM 96b] KIMURA S., IMAI Y., “0-40 GHz GaAs MESFET distributed baseband amplifier IC’s for high-speed optical transmission”, IEEE Transaction on Microwave Theory and Techniques, vol. 44, n° 11, pp. 2076-2082, 1996.

[KIM 01] KIM H., CHANDRASEKHAR S., BURRUS C., BAUMAN J., “A Si BiCMOS transimpedance amplifier for 10 Gb/s SONET receiver”, IEEE Journal of Solid State Circuits, vol. 36, n° 5, pp. 769-776, 2001.

[KIM 04] KIM A., JOO Y.H., KIM Y., “60 GHz wireless communication systems with radio-over-fiber links for indoor wireless LAN”, IEEE Trans. on Consumer Electronics, vol. 50, pp. 517-520, 2004.

[KIR 75] KIREEV P., La Physique des Semi-conducteurs, Mir, Moscow, 1975.

[KIS 91] KISHINO K., UNLÜ S., CHYI J.-I., REED J., ARSENAULT L., MORKOÇ H., “Resonant cavity-Enhanced (REC) Photodetectors”, IEEE Journal of Quantum Electronics, vol. 27, n° 8, pp. 2025-2034, 1991.

[KNO 03] KNODL T., GOLLING M., STRAUB A., JAGER R., MICHALZIK R., EBELING K., “Multistage bipolar cascade vertical-cavity surface-emitting lasers: Theory and experiment”, IEEE J. Sel. Topics Quantum Electron., vol. 9, n° 5, pp. 1406-1414, 2003.

[KOI 06] KOIKE Y., ISHIGURE T., “High-bandwidth plastic optical fiber for fiber to the display”, Journal of Lightwave Technology, vol. 24, n° 12, pp. 4541-4553, 2006.

[KOI 09] KOIKE K., KOIKE Y., “Design of low-loss graded-index plastic optical fiber based on partially fluorinated methacrylate polymer”, Journal of Lightwave Technology, vol. 27, n° 1, pp. 41-46, 2009.

[KOO 08] KOONEN A.M.J., LARRODÉ M.G., “Radio-over-MMMF techniques — part II: microwave to millimeter-wave systems”, Journal of Lightwave Technology, vol. 26, n° 15, pp. 2396-2408, 2008.

[KOP 98] KOPF R.F., HAMM R.A., RYAN R.W., BURM J., TATE A., CHEN Y.-K., GEORGIU G., LANG D.V., REN F., “Evaluation of encapsulation and passivation of InGaAs/InP DHBT devices for long-term reliability”, Journal of Electronic Materials, vol. 27, n° 8, pp. 954-960, 1998.

[KOP 00] KOPF R.F., HAMM R.A., WANG Y.-C., RYAN R.W., TATE A., MELENDES M.A., PULLELA R., CHEN Y.-K., THEVIN J., “Dry-etch fabrication of reduced area InGaAs/InP DHBT devices for high speed circuit applications”, Journal of Electronic Materials, vol. 29, n° 2, pp. 222-224, 2000.

[KUB 80] KUBOTA K., NODA J., MIKAMI O., “Traveling wave optical modulator using a directional coupler LiNbO waveguide”, IEEE J. Quantum Electron., vol. QE-16, pp. 754-760, 1980.

[KUR 99] KURI T., KITAYAMA K.-I., STÖHR A., OGAWA Y., “Fiber-optic millimeter-wave downlink system using 60 GHz-band external modulation”, Journal of Lightwave Technology, vol. 17, n° 5, pp. 799-806, 1999.

[LAB 02] LABBE P., DONVAL A., HIERLE R., TOUSSAERE E., ZYSS J., “Electro-optic polymer based devices and technology for optical telecommunication”, Comptes Rendus Physique 3 de l’Académie des Sciences, pp. 543-554, 2002.

[LAM 06] LAMMARI A., Déphaseur optique à structure MEMS en technologie microphotonique pour la réalisation d’un modulateur Mach-Zehnder dans une liaison photonique micro-onde, PhD thesis, CNAM, 2006.

[LAN 84] LANCE A.L., SEAL W.D., LABAAR F., “Phase noise and AM noise measurements in the frequency domain”, Infrared and Millimeter Waves, vol. 11, pp. 239-289, 1984.

[LEC 06] LECOY P., DELACRESSONNIÈRE B., “Design and realization of an optically controlled oscillator for radio over fiber at 5.2 GHz”, MWP’06, Grenoble, 2006.

[LEC 07] LECOY P., Télécoms sur Fibres Optiques, 3^rd edition, Hermès, Paris, 2007.

[LEE 00] LEE S., GARNER S.M., CHUYANOV V., ZHANG H., STEIER W.H., WANG F., DALTON L.R., UDUPA A.H., FETTERMAN H.R, “Optical intensity modulator based on a novel electro-optic polymer incorporating a high μβ chromophore”, IEEE J. of Quantum Electron., vol. 36, pp. 527-532, 2000.

[LEE 02] LEE M. et al., “Broadband modulation of light by using an electro-optic polymer”, Science, vol. 298, pp. 1401-1403, 2002.

[LEE 04] LEE S.S., CHO H.W., LIM S.K., KO J.S., “16×42.8 Gb/s unrepeated transmission over 200 km of standard single-mode fiber by using an electroabsorption modulator”, Optical Engineering, vol. 44, pp. 215-217, 2004.

[LEN 99] LENOX C., NIE H., KINSEY G., HOMLES A.L. JR, STREETMAN B.G., CAMPBELL J.C., “Resonant-cavity InGaAs-InAlAs avalanche photodiodes with gain-bandwidth product of 290 GHz”, IEEE Photonics Technology Letters, vol. 11, n° 9, pp. 1162-1164, 1999.

[LEG 09] LE GUENNEC Y., PIZZINAT A., MEYER S., CHARBONNIER B., LOMBART P., LOURDIANE M., CABON B., ALGANI C., BILLABERT A.-L., TERRE M., RUMELHARD C., POLLEUX J.L., JAQUINOT H., BORIES S., SILLANS C., “Low-cost transparent radio-over-fiber system for in-building distribution of UWB signals”, Journal of Lightwave Technology, vol. 27, n° 14, pp. 2649-2657, 2009.

[LEV 03] LEVEN A., HOUTSMA R., KOPF R., BAEYENS Y., CHEN Y.K., “InP-based double-hétérostructure phototransistor with a optical-gain cutoff frequency of 135GHz”, Nefertiti Workshop on Microwave Phototransistors, Budapest University of Technology and Economics, 9 September 2003.

[LEV 04] LEVEN A., HOUTSMA R., KOPF R., BAEYENS Y., CHEN Y.K., “InP-based double-heterostructure phototransistors with 135 GHz optical-gain cutoff frequency”, Electronics Letters, vol. 40, n° 13, pp. 833-834, 2004.

[LI 99] LI B., JIANG Z., ZHANG X., WANG X., WAN J., LI G., LIU E., “SiGe/Si Mach-Zehnder interferometer modulator based on the plasma dispersion effect”, Appl. Phys. Lett., vol. 74, pp. 2108-2109, 1999.

[LI 03a] LI X., LI N., ZHENG X., DEMIGUEL S., CAMPBELL J.C., TULCHINSKY D.A., WILLIAMS K., “High-saturation-current InP-InGaAs photodiode with partially depleted absorber”, IEEE Photonics Technology Letters, vol. 15, n° 9, pp. 1276-1278, 2003.

[LI 03b] LI X., DEMIGUEL S., LI NN, CAMPBELL J.C., TULCHINSKY D.A., WILLIAMS K., “Backside illuminated high saturation current partially depleted absorber photodetectors”, Electronics letters, vol. 39, n° 20, pp. 1466-1467, 2003.

[LI 04] LI N., LI X., DEMIGUEL S., ZHENG X., CAMPBELL J.C., TULCHINSKY D.A., WILLIAMS K.J., ISSHIKI T.D., KINSEY G.S., SUDHARSANSAN R., “Highsaturation-current charge-compensated InGaAs-InP uni-traveling-carrier photodiode”, IEEE Photonics Technology Letters, vol. 16, n° 3, pp. 864-866, 2004.

[LIM 08] LIM C.G., “Electro-absorption modulator integrated lasers with enhanced signal injection efficiency”, IEEE Journal of Lightwave Technology, vol. 26, pp. 685-691, 2008.

[LIN 96] LIN L.Y., WU M.C., ITOH T., VANG T.A. MULLER D.L., SIVCO D.L., CHO A.Y., “Velocity-matched distributed photodetectors with high-saturation power and large bandwidth”, IEEE Photonics Technology Letters, vol. 8, n° 10, pp. 1376-1378, 1996.

[LIN 97] LIN L.Y., WU M.C., ITOH T., VANG T.A., MULLER D.L., SIVCO D.L., CHO A.Y., “High-power high-speed photodetectors — design, analysis, and experimental demonstration”, IEEE Transactions on Microwave Theory and Techniques, vol. 45, n° 8, pp. 1320-1331, 1997.

[LIU 03a] LIU C.W., “The Si/SiGe heterojunction phototransistors with high bandwidth and multi-functionality”, Nefertiti Workshop on Microwave Phototransistors, Budapest, September 2003.

[LIU 03b] LIU B., SHIM J., CHIU Y., KEATING A., PIPREK J., BOWERS J., “Analog characterization of low-voltage MQW traveling-wave electroabsorption modulators”, Journal Lightwave Technology, vol. 21, n° 12, pp. 3011-3019, 2003.

[MAA 88] MAAS S.A., Nonlinear Microwave Circuits, Artech House, Norwood, MA, 1988.

[MAA 95] MAAS S.A., “Third-order intermodulation distortion in cascaded stages”, IEEE Microwave and Guided Wave Letters, vol. 5, n° 6, pp. 189-191, 1995.

[MAR 80] MARFAING Y., Photoconductivity, photoelectric effects, Chapter 7, in M. BALKANSKI, Handbook of Semiconductors, vol. 2, North-Holland Publishing Company, Amsterdam, 1980.

[MAN 09] MANDEREAU F., BENZAZA M., BILLABERT A.-L., ALGANI C., “Simulation de la génération d’un signal micro-ondes par la technique de battement hétérodyne de deux lasers”, 16es Journées Nationales Micro-ondes (JNM’2009), Grenoble, May 2009.

[MEA 87] MEARS R.J., REEKIE L., JAUNCEY I.M., PAYNE D.N., “Low-noise erbium-doped fibre amplifier at 1.54 pm”, Electronics Letters, vol. 23, pp. 1026-1028, 1987.

[MEN 88] MENDOZA-ALVAREZ J.G. et al., “Analysis of depletion edge translation lightwave modulators”, Journal of Lightwave Technology, vol. 6, pp. 793-808, 1988.

[MON 91] MONTGOMERY R.K., REN F., ABERNATHY C.R., FULLOWAN T.R., KOPF R.F., SMITH P.R., PEARTON S.J., WISK P., LOTHIAN J., NOTTENBURG R.N., “10 Gbit/s AlGaAs/GaAs HBT driver IC for lasers or lightwave modulators”, Electronics Letters, vol. 27, n° 20, pp. 1827-1829, 1991.

[MOU 05] MOUTIER F., POLLEUX J.L., RUMELHARD C., “Comportement UTC d’un phototransistor bipolaire à hétérojonction SiGe/Si”, 14es Journées Nationales Micro-ondes, Nantes, May 2005.

[MOU 06] MOUTIER F., Modélisation et évaluation des performances des phototransistors bipolaires à hétérojonction SiGe/Si pour les applications Optiques-micro-ondes courtes distances, PhD thesis, University of Marne la Vallée, 2006.

[NAG 94] NAGANO N., SUZAKI T., SODA M., KASAHARA K., TAKEHUSHI T., HONJO K., “Monolithic ultra-broadband transimpedance amplifiers using AlGaAs/GaAs heterojunction bipolar transistors”, IEEE Transaction on Microwave Theory and Techniques, vol. 42, n° 1, pp. 2-10, 1994.

[NAG 09] NAGATSUMA T., “Generating millimeter and terahertz waves”, IEEE Microwave Magazine, pp. 64-74, 2009.

[NOG 98] NOGUCHI K., MITOMI O., MIYAZAWA H., “Millimeter-wave Ti: LiNbO₃ optical modulators”, Journal of Lightwave Technology, vol. 16, pp. 615-19, 1998.

[NYQ 28] NYQUIST H., “Thermal agitation of electric charge in conductors”, Phys. Rev., 32, 110-13, 1928.

[OGA 93] OGAWA H., BANBA S., SUEMATSU E., KAMITSUNA H., POLIFKO D., “A comparison of noise performance between a PIN diode and MMIC HEMT and HBT optical receivers”, IEEE MTT-S Digest, pp. 225-228, 1993.

[OHI 01] OHISO Y., OKAMOTO H., IGA R., KISHI K., TATENO K., AMANO C., “1.55 pm buried-heterostructure VCSELs with InGaAsP/InP-GaAs/AlAs DBRs on a GaAs substrate, IEEE Journal of Quantum Electronics, vol. 37, n° 9, pp. 738-740, 2001.

[OHI 02] OHISO Y., OKAMOTO H., IGA R., KISHI K., AMANO C., “Single transverse mode operation of 1.55pm buried heterostructure vertical-cavity surface-emitting lasers”, IEEE Photonics Technology Letters, vol. 14, n° 6, pp. 1194-1202, 2002.

[ONA 98] ONAT B.M., GÖKKAVAS M., OZBAY E., ATA E.P., TOWE E., UNLÜ S., “100-GHz resonant cavity enhanced Schottky photodiodes”, IEEE Photonics Technology Letters, vol. 10, n° 5, pp. 707-709, 1998.

[PAN 99] PAN J.-W., CHEN M.-H., CHYI J.-I., SHIH T.-T., “Strain-compensated 1.3pm AlGaInAs quantum-well lasers with multiquantum barriers at the cladding layers”, IEEE Photonics Technology Letters, vol. 11, n° 1, pp. 9-11, 1999.

[PAQ 04] PAQUELET S., MOY C., AUBERT L.M., “RF front end considerations for SDR ultra-wideband communications systems”, RF Design, July 2004.

[PAS 02] PASZKIEWICZ L., Modélisation et caractérisation de liaisons optiques mixtes fibre optique-radio et conception d’un récepteur optoélectronique, PhD thesis, University of Marne La Vallée, January 2001.

[PED 93] PEDROTTI K.D., PIERSON JR R.L., FARLEY C.W., CHANG M.F., “Monolithic optical integrated receivers using GaAs heterojunction bipolar transistors”, Microwave Journal, 254-261, 1993.

[PEI 02] PEI Z., LIANG C.S., LAI L.S., TSENG Y.T., HSU Y.M., CHEN P.S., LU S.C., LIU C.M., TSAI M.-J., LIU C.W., “High efficient 850 nm and 1,310 nm multiple quantum-well SiGe/Si heterojunction phototransistors with 1.25 plus GHz bandwidth (850nm)”, International Electron Devices and Material Symposium, pp. 297-300, 2002.

[PEI 04] PEI Z., SHI J.W., HSU Y.M., YUAN F., LIANG C.S., LU S.C., HSIEH W.Y., TSAI M.-J. LIU C.W., “Bandwidth enhancement in an integretable SiGe phototransistor by removal of excess carriers”, IEEE Electron Device Letters, vol. 25, n° 5, 286-288, 2004.

[POL 06] POLISHUK P., “Plastic optical fibers branch out”, IEEE Communications Magazine, pp. 140-148, 2006.

[POL 99] POLLEUX J.L., SALSET J., CHENNAFI N., PASZKIEWICZ L., RUMELHARD C., GONZALEZ C., “Le phototransistor InP/GaInAs en millimétrique: recherche du gain maximum”, 11es Journées Nationales Micro-ondes, Arcachon, May 1999.

[POL 01] POLLEUX J.L., Contribution à l’étude et à la modélisation de phototransistors bipolaires à hétérojonction SiGe/Si pour les applications optomicro-ondes, PhD thesis, Conservatoire National des Arts et Métiers, 2001.

[POL 02] POLLEUX J.L., BILLABERT A.-L., HINCELIN G., RUMELHARD C., “Characterisation of phototransistors by beating of lasers”, Workshop on Advances in Photonics Technologies for Microwave Applications at European Microwave Week, Milan, Italy, September 2002.

[POL 03a] POLLEUX J.L., MOUTIER F., BILLABERT A.-L., RUMELHARD C., SÖNMEZ E., SCHUMACHER H., “A strained SiGe layer heterojunction bipolar phototransistor for short-range opto-microwave applications”, IEEE International Topical Meeting on Microwave Photonics (MWP2003), Budapest, Hungary, September 2003.

[POL 03b] POLLEUX J.L., MOUTIER F., BILLABERT A.-L., RUMELHARD C., SÖNMEZ E., SCHUMACHER H., “A heterojunction SiGe/Si phototransistor for optomicrowave applications: modelling and first experimental results”, GAAS Conference of the European Microwave Week, Munich, pp. 231-234, October 2003.

[POL 04] POLLEUX J.L., PASZKIEWICZ L., BILLABERT A.-L., SALSET J., RUMELHARD C., “Optimization of InP-InGaAs HPT gain: Design of an opto-microwave monolithic amplifier”, IEEE Trans. On Microwave Theory and Techniques, vol. 52, n° 3, pp. 871-881, 2004.

[RAM 82] RAMER O.G., “Integrated optic electrooptic modulator electrode analysis”, IEEE Quantum Electronics, vol. QE-18, pp. 386-392, 1982.

[RIS 03] RISSONS A., Caractérisation et modélisation optoélectronique de diode laser à cavité verticale émettant par la surface (VCSEL), PhD thesis, Ecole nationale supérieure de l’aéronautique et de l’espace, 2003.

[RIS 04] RISSONS A., MOLLIER J.-C., “Le VCSEL, émetteur opto-électronique polyvalent Modélisation et caractérisation”, RSTD, pp. 61-69, March 2004.

[ROS 98] ROSENCHER E., VINTER B., Optoélectronique, Masson, Paris, 1998.

[ROU 97] ROUSSEL H., HELKEY R., BETTS G., COX C., “Effect of optical feedback on high dynamic-range Fabry-Perot optical links”, IEEE Photonics Technology Letters, vol. 9, n° 1, pp. 106-108, 1997.

[RUM 01] RUMELHARD C., PASZKIEWICZ L., POLLEUX J.L., GERMOND A.-L., SALSET J., “Simulation of optical links in microwaves”, Proceedings of the 8th International Symposium on Microwave and Optical Technology (ISMOT 2001), Montréal, Canada, pp. 595-599, 19-23 June 2001.

[RUM 03] RUMELHARD C., POLLEUX J.L., “Models and definitions for the analysis of HPTs: application to InP and SiGe phototransistors”, Nefertiti Workshop on Microwave Phototransistors, Budapest, September 2003.

[RUM 04a] RUMELHARD C., “Les circuits intégrés monolithiques micro-ondes: évolution et technologie”, Fascicule E1425, Les techniques de l’Ingénieur, www.techniques-ingenieur.fr, 2004.

[RUM 04b] RUMELHARD C., “Composants pour circuits intégrés monolithiques micro-ondes”, Fascicule E1426, Les techniques de l’Ingénieur, www.techniquesingenieur.fr, 2004.

[RUM 04c] RUMELHARD C., “Déphaseurs et amplificateurs monolithiques”, Fascicule E1427, Les techniques de l’Ingénieur, www.techniques-ingenieur.fr, 2004.

[RUM 04d] RUMELHARD C., “Circuits et sous ensembles monolithiques de génération, modulation, démodulation ou conversion de fréquence”, Fascicule E1428, Les techniques de l’Ingénieur, www.techniques-ingenieur.fr, 2004.

[SAI 92] SAITO S. et al., “In-line amplifier transmission experiments over 4500km at 2.5Gb/s”, Journal of Lightwave Technology, vol. 10, pp. 1117-1126, 1992.

[SAM 96] SAMELIS A., PAVLIDIS D., CHANDRASEKHAR S., LUNARDI L.M., RIOS J., “Large-signal charactristics of InP-based heterojunction bipolar transistors and optoelectronic cascode transimpedance amplifiers”, IEEE Transactions on Electron Devices, vol. 43, n° 12, 1996.

[SAP 90] SAPOVAL B., HERMANN C., Physique des semi-conducteurs, Ellipses, Paris, 1990.

[SCA 09] SCAVENNEC A., SOKOLICH M., BAEYENS Y., “Semiconductor technologies for higher frequencies”, IEEE Microwave Magazine, pp. 77-87, 2009.

[SCH 09] SCHIELLEIN J., ROSALES M., POLLEUX J.L., DUPORT F., ALGANI C., RUMELHARD C., MERLET T., ZEROUNIAN N., RIET M., GODIN J., SCAVENNEC A., “Experimental influence of the base load effect on SiGe/Si and InGaAs/InP HPTs”, IEEE International Topical Meeting on Microwaves Photonics (MWP2009), Valence, 14-16 October 2009.

[SCH 97] SCHMID R., MEISTER T.F., NEUHÄUSER M., FELDER A., BOGNER W., REST RUPETER J., REIN H.-M., “20 Gbit/s transimpédance preamplifier and modulator driver in SiGe bipolar technology”, Electronics Letters, vol. 33, n° 13, pp. 1136-1137, 1997.

[SCH 18] SCHOTTKY W., “Uber Spontane Schtromschwankungen in verschiedenen, Elektrizitatsleitern”, Ann. Phys., 57, pp. 541-67, 1918.

[SCH 99] SCHÖLL E., “Modelling of devices for optoelectronic applications: the quantum confined Starck effect and self-electronic effect devices”, Journal of Physics, 23, pp. 635-648, 1999.

[SCO 01] SCOTT P., LANGROCK C., KOLNER B.H., “High-dynamic-range laser amplitude and phase noise measurement techniques”, IEEE Journal of Selected Topics in Quantum Electronics, vol. 7, n° 4, pp. 641-655, 2001.

[SEE 96a] SEEDS A., COX C., “Workshop on Microwave Photonic Systems”, IEEE MTT-S, International Microwave Symposium, San Francisco, June 1996.

[SEE 96b] SEEDS A., “Optical transmission of microwaves”, Chapter 14, in W.R. STONE, Review of Radio Science 1993-1996, Oxford University Press, Oxford, 1996.

[SEE 02] SEEDS A.J., “Microwave photonics”, IEEE Trans. Microw. Theory Tech., vol. 50, n° 3, pp. 877-887, 2002.

[SEM 06] SEMENYUK V., “Miniature thermoelectric modules with increased cooling power”, International Conference on Thermoelectrics, pp. 322-326, 2006.

[SHI 00] SHIGEMATSU H., SATO M., SUZUKI T., TAKAHASHI T., IMANISHI K., HARA N. OHNISHI H., WATANABE Y., “A 49-GHz preamplifier with a transimpedance gain of 52 dBΩ using InP HEMTs”, IEEE GaAs IC Digest, pp. 197-200, 2000.

[SHI 01a] SHIGEMATSU H., SATO M., SUZUKI T., TAKAHASHI T., IMANISHI K., HARA N., OHNISHI H., WATANABE Y., “A 49-GHz preamplifier with a transimpedance gain of 52 dBÙ using InP HEMTs”, IEEE Journal of Solid-State circuits, vol. 36, n° 9, pp. 1309-1313, 2001.

[SHI 01b] SHIMOTSU S., OIKAWA S., SAITOU T., MITSUGI N., KUBODERA K., KAWANISHI T., IZUTSU M., “Single side-band modulation performance of a LiNbO₃ integrated modulator consisting of four-phase modulator waveguide”, IEEE Photonics Technology Letters, vol. 13, n° 4, pp. 364-366, 2001.

[SIM 90] SIMMONS R., Optical Control of Microwave Devices, Artech House, Boston, MA, 1990.

[SMI 97] SMITH G.H., NOVAK D., AHMED Z., “Technique for optical SSB generation to overcome dispersion penalties in fibre-radio systems”, Electronics letters, vol. 33, n° 1, pp. 74-75, 1997.

[SPI 95] SPICKERMANN R., DAGLI N., PETERS M.G., “GaAs/AlGaAs electro-optic modulator with bandwidth >40 GHz”, Electronics Letters, vol. 31, pp. 915-916, 1995.

[SRI 08] SCRICHAM P., RANGSEE P., WORASUCHEEP R.R, “A 2.5 Gb/s electroabsorption modulator integrated laser optical transmitter in long-haul dense wavelength division multiplexing transmission”, Proceedings of ECTI-CON, vol. 1, pp. 253-256, 2008.

[SUE 93] SUEMATSU E., OGAWA H., “Frequency response of HBTs as photodetectors”, IEEE Microwave and Guided Wave Letters, vol. 3, n° 7, pp. 217-218, 1993.

[SUG 02] SUGIYAMA M. et al, “Driver-less 40 Gb/s LiNbO/sub 3/ modulator with sub-1 V drive voltage”, Optical Fiber Communications Conference (OFC), Opt Soc. America, vol. 2, pp. FB6-1, 2002.

[SZE 81] SZE S.M., Physics of Semiconductor Devices, 2^nd edition, John Wiley and Sons, New York, 1981.

[SZE 91] SZE S.M., Semiconductor Devices: Pioneering Papers, World Scientific, Singapore, 1991.

[TAY 00] TAYLOR N., LASER: The Inventor, the Nobel Laureate, and the Thirty-year Patent War, Simon and Schuster, New York, 2000; An Authors Guild Backinprint.com Edition, 2007.

[TEL 06] TELLUREX CORPORATION, An Introduction to Thermoelectrics, www.tellurex.com/cthermo.html, 2006.

[TEP 00] TEPPO T., SÖNMEZ E., SCHAD K.B., ABELE P., SCUMACHER H., “Si/SiGe IC’s with low cost in the 15-20 GHz range”, 8^th IEEE International Symposium on High Performance Electron Devices for Microwave and Optoelectronic Applications (EDMO 2000), Glasgow, Scotland, pp. 26-31, November 2000.

[THU 99] THURET J., GONZALEZ C., BENCHIMOL J.L., RIET M., BERDAGUER P., “High-speed InP/InGaAs heterojunction phototransistor for millimetre-wave fibre radio communications”, 11^th International Conference on Indium Phosphide and Related Materials, Davos, Switzerland, 16-20 May 1999.

[TRA 07] TRAVERSO S., Transposition de fréquence et compensation de déséquilibre IQ pour des systèmes multiporteuses sur canal sélectif en fréquence, PhD thesis, University of Cergy-Pontoise, Ecole nationale supérieure de l’électronique et de ses applications, 2007.

[TRE 91] TREYZ G.V., MAI P.G., HALBOUT J.-M., “Silicon optical modulators at 1.3 μm based on free-carrier absorption”, IEEE Electron Device Lett., vol. 12, pp. 276-278, 1991.

[TSA 84] TSANG W.T., “Heterostructure semiconductor lasers prepared by molecular beam epitaxy”, IEEE Journal of Quantum Electronics, vol. QE-20, n° 10, pp. 1119-1131, 1984.

[TSU 03] TSUZUKI K. et al., “40 Gbit/s n-i-n InP Mach-Zehnder modulator with a pivoltage of 2.2 V”, Electronics Letters, vol. 39, n° 20, pp. 1464-6, 2003.

[TUC 83] TUCKER R.S., POPE D.J., “Microwave circuit models of semiconductor injection lasers”, IEEE transactions on Microwave Theory and Techniques, vol. MTT-31, n° 3, 1983.

[TUC 84] TUCKER R.S., KAMINOV I.P., “High frequency characteristics of directly modulated InGaAsP ridge waveguide and buried heterostructure lasers”, Journal of Lightwave Technology, vol. LT-2, n° 4, 1984.

[UDV 08] UDVARY E., BERCELI T., “Semiconductor optical amplifier for detection function in radio over fiber systems”, Journal of Lightwave Technology, vol. 26, pp. 2563-2570, 2008.

[UNL 90] ÜNLÜ M.S., KISHINO K., CHYI J.-I., ARSENAULT L., REED J., NOOR MOHAMMAD S., “Resonant cavity enhanced AlGaAs/GaAs layer in the collector”, Appl. Phys. Lett, vol. 57, n°8, pp. 750-752, 1990.

[VAH 89] VAHALA K., NEWKIRK M., CHEN T., “The optical gain lever: a novel gain mechanism in the direct modulation of quantum well semiconductor lasers”, Appl. Phys. Lett., vol. 54, pp. 2506-2508, 1989.

[VAN 93] VANISRI T., TOUMAZOU C., “Integrated high frequency low noise current-mode optical transimpedance preamplifiers: theory and practice”, IEEE Journal of Solid-State Circuits, vol. 30, n° 6, pp. 677-685, 1995.

[VAP 90] VAPAILLE A., CASTAGNE R., Dispositifs et Circuits Intégrés Semiconducteurs, Dunod, Paris, 1990.

[VIL 03] VILCOT A., CABON B., CHAZELAS J., Microwave Photonics: from Components to Applications and Systems, Kluwer Academic Publisher/Springer, 2003.

[WAL 91a] WALKER G.R., WALKER N.G., STEELE R.C., CREANER M.J., BRAIN M.C., “Erbium-doped fiber amplifier cascade for multichannel coherent optical transmission”, Journal of Lightwave Technology, vol. 9, n° 2, 1991.

[WAL 91b] WALKER R.G., “High-speed III-V semiconductor intensity modulators”, IEEE J. of Quantum Electronics, vol. 27, pp. 654-667, 1991.

[WAN 91] WANUGA S., ACKERMAN E., KASEMSET D., KOMIAK J., PETERS D., SCOTTI R., MACDONALD W., GATES J., “Integrated microwave optoelectronic transceivers for lightweight fiber optic harnesses and remote microwave signal transmission”, Proc. Gov. Microelectron. Applicat. Conf., Las Vegas, NV, pp. 79-81, 1991.

[WEI 08] WEISS M., HUCHARD M., STÖHR A., CHARBONNIER B., FEDDERWTZ S., JÄGER S., “60-GHz photonic millimeter-wave link for short-to medium-range wireless transmission up to 12.5 Gb/s”, Journal of Lightwave Technology, vol. 26, n° 15, pp. 2424-2429, 2008.

[WEL 96] WESTLAND R., PAPPERT S., SUN C., ZHU J., LIU Y., YU P., “Dual-function electroabsorption waveguide modulator/detector for optoelectronic transceiver applications”, IEEE Photon. Technol. Lett., vol. 8, n° 11, pp. 1540-1542, 1996.

[WEL 99] WESTLAND R.B. et al., “Confined Franz-Keldysh and quantum-confined stark effect waveguide modulator for analog signal transmission”, IEEE Journal of Lightwave Technology, vol. 17, pp. 497-502, 1999.

[WIK 09] WIKIPEDIA, Les fibres optiques, http://fr.wikipedia.org/wiki/Fibre_optique, 2009.

[WIL 96] WILLIAMS K., ESMAN D., DANGENAIS M., “Nonlinearities in p-i-n microwave photodetectors”, Journal of Lightwave Technology, vol. 14, n°1, pp. 84-96, 1996.

[WIL 97] WILLIAMS K., NICHOLS L., ESMAN R., “Externally-modulated 3 GHz fiber-optic link utilizing high current and balanced detection”, Electron. Lett., vol. 33, pp. 1327-1328, 1997.

[WIL 99] WILLIAMS K., ESMAN R., “Design considerations for high-current photodetectors”, Journal of Lightwave Technology, vol. 17, n° 8, pp. 1443-1454, 1999.

[WOO 00] WOOTEN ED L. et al., “A review of lithium niobate modulators for fiber-optic communications systems”, IEEE J. of Selected Topics in Quantum Electron., vol. 6, pp. 69-82, 2000.

[WU 03] WU C.Q., SOVERO E.A., MASSEY B., “40 GHz transimpedance amplifier with differential ouput using InP/InGaAs heterojunction bipolar transistor”, IEEE Journal of Solid-State Circuits, vol. 38, n° 9, pp. 1518-1523, 2003.

[YAM 83a] YAMAMOTO Y., “AM and FM quantum noise in semiconductor lasers — part I: theoretical analysis”, IEEE Journal of Quantum Electronics, vol. QE-19, n° 1, pp. 34-46, 1983.

[YAM 83b] YAMAMOTO Y., SAITO S., MUKAI T., “AM and FM quantum noise in semiconductor lasers — part II: comparison of theoretical and experimental results for AlGaAs lasers”, IEEE Journal of Quantum Electronics, vol. QE-19, n° 1, pp. 47-58, 1983.

[YAM 05] YAMANAKA T., FUKANO H., SAITOH T., “Lightwave-microwave unified analysis of electroabsorption modulators integrated with RF coplanar waveguides”, IEEE Photonics Technology Letters, vol. 17, pp. 2562-2564, 2005.

[YAM 94] YAMAUCHI Y., NAGATA K., MAKIMURA T., NAKAJIMA O., ITO H., ISHIBASHI T., “10 Gb/s monolithic optical modulator driver with high output voltage of 5 V using InGaP/GaAs HBTs”, GaAsIC Symposium, pp. 207-210, 1994.

[YAO 09] YAO J., “Photonics for ultrawideband communications”, IEEE Microwave Magazine, June 2009.

[YIN 06] YIN T., PAPPU A.M., APSEL A.B., “Low-cost, high-efficiency, and highspeed SiGe phototransistors in commercial BICMOS”, IEEE Photonics Technology Letters, vol. 18, n° 1, pp. 55-57, 2006.

[YU 05] YU Y. et al., “Temperature-dependant effects in in highspeed travelling-wave electroabsorption modulators”, Electronics Letter, vol. 41, pp. 209-211, 2005.

[ZAP 95] ZAPPE H.P., Introduction to Semiconductor Iintegrated Optics, Artech House, Boston, MA, 1995.

[ZHA 95] ZHAO C.Z., LI G.Z., LIU E.K., GAO Y., LIU X.D., “Silicon on insulator Mach-Zehnder waveguide interferometers operating at 1.3 μm”, Appl. Phys. Lett., vol. 67, pp. 2448-2449, 1995.

[ZHU 97] ZHU Y., YANG Q., WANG Q., “Resonant cavity SiGe/SiMQW heterojunction phototransistor grown on the SIMOX substrate for 1.3 µm operation”, Electronic Components and Technology Conference, pp. 1199-1204, 1997.

[ZHU 04] ZHUANG Y., CHANG W., YU P., “Peripheral-coupled-waveguide MQW electroabsorption modulator for near transparency and high spurious free dynamic range RF fiber-optic link”, IEEE Photonics Technology Letters, vol. 16, n° 9, pp. 2033-2035, 2004.

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