Commande boucle fermée multivariable pour le vol en ... - ISAE

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298 BIBLIOGRAPHIE[138] Philippe, C. ESA perspectives on advances control technology for complex space systems.Keynote lecture. IEEE Conference on Control Applications. Munich, Germany, October 4-62006.[139] Piper, G. E., Watkins, J. M., and Leitner, J. A. On the impact of cross-link delayson spacecraft formation control. In AIAA Guidance, Navigation, and Control Conference andExhibit (Austin, TX, August 11-14 2003).[140] Pirson, L., Charbonnel, C., Udrea, B., Rennie, M., McGuinness, P., and Palomo, P.Darwin precursor demonstration mission : The ICC2 study, from GNC design to real-time testbench validation. In 6th International ESA Conference on Guidance, Navigation and ControlSystems (Loutraki, Greece, October 17-20, 2005).[141] Ploen, S. R., Hadaegh, F. Y., and Scharf, D. P. Rigid body equations of motion formodeling and control of spacecraft formations - part 1 : Absolute equations of motion. In 2004American Control Conference (Boston, MA, USA, June 30-July 2 2004).[142] Ploen, S. R., Quadrelli, M. B., Scharf, D. P., and Hadaegh, F. Y. Dynamics ofdrag-free formations for earth imaging applications. In AIAA/AAS Astrodynamics SpecialistConference and Exhibit (Keystone, CO, USA, August 21-24 2006).[143] Pluym, J. P., and Damaren, C. J. Second order relative motion model for spacecraft underJ 2 perturbations. In AIAA/AAS Astrodynamics Specialist Conference and Exhibit (Keystone,CO, USA, August 21-24 2006).[144] Purcell, G., Kuang, D., Lichten, S., Wu, S.-C., and Young, L. Autonomous formationflyer (aff) sensor technology development. Tech. Rep. TMO PR 42-134, Jet PropulsionLaboratory, California Institute of Technology, April-June 1998.[145] Richards, A., How, J., Schouwenaars, T., and Feron, E. Plume avoidance maneuverplanning using mixed integer linear programming. In AIAA Guidance, Navigation, and ControlConference and Exhibit (Montreal, Canada, August 6-9 2001).[146] Robertson, A., Inalhan, G., and How, J. P. Spacecraft formation flying control designfor the Orion mission. In AIAA Guidance, Navigation, and Control Conference and Exhibit(Portland, OR, August 1999).[147] Robertson, A. D. Control System Design for Spacecraft Formation Flying : Theory andExperiment. PhD thesis, Stanford University, Department of Aeronautics and Astronautics,Stanford, CA, June 2001.[148] Romanelli, C. C., Natarajan, A., Schaub, H., Parker, G. G., and King, L. B. Coulombspacecraft voltage study due to differential orbital perturbation. In 2006 AAS/AIAA SpaceFlight Mechanics Meeting (Tampa, FL, January 22-26 2006).[149] Ross, I. M. Linearized dynamic equations for spacecraft subject to J 2 perturbations. Journalof Guidance, Control, and Dynamics 26, 4 (2003), 657–659.[150] Rugh, W. J. Linear System Theory. Prentice Hall, 1996.[151] Safonov, M. G., Goh, K. C., and Ly, J. H. Control system synthesis via bilinear matrixinequalities. In American Control Conference (Baltimore, Maryland, June 1994), pp. 45–49.Commande boucle fermée multivariable pour le vol en formation de vaisseaux spatiaux
BIBLIOGRAPHIE 299[152] Sandell, N. R., Varaiya, P., Athans, M., and Safonov, M. G. Survey of decentralizedcontrol methods for large scale systems. IEEE Transactions on Automatic Control AC-23, 2(April 1978), 108–128.[153] Sanner, R. M., and Proffen, D. K. Virtual rigid body (VRB) satellite control with formationpreserving cross-coupling. In 2nd International Symposium on Formation Flying Missionsand Technologies (Washington, D.C., September 14-16 2004).[154] Scharf, D. P., Hadaegh, F. Y., and Ploen, S. R. A survey of spacecraft formation flyingguidance and control (part I) : Guidance. In 2003 American Control Conference (Denver, CO,June 4-6 2003).[155] Scharf, D. P., Hadaegh, F. Y., and Ploen, S. R. A survey of spacecraft formation flyingguidance and control (part II) : Control. In 2004 American Control Conference (Boston, MA,June 30-July 2 2004).[156] Scheeres, D. J., and Vinh, N. X. Dynamics and control of relative motion in an unstableorbit. In AIAA/AAS Astrodynamics Specialist Meeting (Denver, CO, August 14-17 2000).[157] Schweighart, S., and Sedwick, R. A perturbative analysis of geopotential disturbances forsatellite cluster formation flying. In IEEE Aerospace Conference (Big Sky, MT, 2001).[158] Schweighart, S. A., and Sedwick, R. J. High-fidelity linearized J 2 model for satelliteformation flight. Journal of Guidance, Control, and Dynamics 25, 6 (November-December 2002),1073–1080.[159] Scorletti, G., and Duc, G. A convex approach to decentralized H ∞ control. In 1997American Control Conference (Albuquerque, NM, June 1997).[160] Seatzu, C., Giua, A., and Usai, G. Decentralized volume control of open-channels using H 2norm minimization. In IEEE International Conference on Systems, Man, and Cybernetics (SanDiego, CA, October 11-14 1998), pp. 3891–3896.[161] Sebe, N. A unified approach to decentralized controller design. In 42nd IEEE Conference onDecision and Control (Maui, Hawaii, December 2003), pp. 1086–1091.[162] Singh, G., and Hadaegh, F. Y. Collision avoidance guidance for formation-flying applications.In AIAA Guidance, Navigation, and Control Conference and Exhibit (Montreal, Canada,August 6-9 2001).[163] Skogestad, S., and Postlethwaite, I. Multivariable Feedback Control : Analysis and Design,second edition ed. John Wiley & Sons, 2005.[164] Sparks, A. Satellite formationkeeping control in the presence of gravity perturbations. In 2000American Control Conference (Chicago, IL, June 28-30 2000).[165] Starin, S. R., Yedavalli, R. K., and Sparks, A. G. Design of a LQR controller of reducedinputs for multiple spacecraft formation flying. In American Control Conference (Arlington,VA, June 25-27 2001).[166] Starin, S. R., Yedavalli, R. K., and Sparks, A. G. Spacecraft formation flying maneuversusing linear-quadratic regulation with no radial axis inputs. In AIAA Guidance, Navigation,and Control Conference and Exhibit (Montreal, Canada, August 6-9 2001).Commande boucle fermée multivariable pour le vol en formation de vaisseaux spatiaux
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THÈSEEn vue de l'obtention duDOCTO
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iRemerciementsÀ l’issue de la lo
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viTABLE DES MATIÈRESII Modèles po
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viiiTABLE DES MATIÈRES4.5.4 Probl
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xTABLE DES MATIÈRESE Non-existence
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xiiSIGLES ET ACRONYMESSigleExplicat
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xivTABLE DES FIGURES3.2 Orbite halo
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xviTABLE DES FIGURES5.9 Effet d’u
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Liste des tableaux1.1 Missions de v
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Liste des publications[1] Gaulocher
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Première partieIntroduction1
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4 1. LE VOL EN FORMATIONLe vol en f
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6 1. LE VOL EN FORMATIONLa Fig. 1.3
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8 1. LE VOL EN FORMATIONSoleil. Le
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10 1. LE VOL EN FORMATIONFigure 1.6
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12 1. LE VOL EN FORMATIONÀ l’int
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14 1. LE VOL EN FORMATIONque d’ha
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16 1. LE VOL EN FORMATIONLa Fig. 1.
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Deuxième partieModèles pour le vo
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22 2. DYNAMIQUE TRANSLATIONNELLE EN
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60 3. MODÈLE COUPLÉ EN TRANSLATIO
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100 3. MODÈLE COUPLÉ EN TRANSLATI
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Chapitre 4Méthodologie pour le pil
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4.1 Revue bibliographique 129Hussei
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4.2 Objectifs 131du système en bou
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4.3 Analyse de la dynamique 133d’
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4.3 Analyse de la dynamique 1352402
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4.4 Modèle linéaire fractionnaire
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4.5 Contrôle modal auto-séquencé
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4.6 Contrôle séquencé H 2 -optim
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Chapitre 5Méthodologie pour le pil
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5.1 Revue bibliographique 185Planet
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5.3 Modélisation de la mission Peg
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5.4 Synthèse d’un correcteur pou
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5.5 Commutation entre correcteurs 2
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Page 273 and 274: 5.5 Commutation entre correcteurs 2
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Page 305: 5.7 Bilan global 279complètement d
Page 309 and 310: Récapitulation et contributionsDan
Page 311: RÉCAPITULATION ET CONTRIBUTIONS 28
Page 314 and 315: 288 PERSPECTIVESde base pour le mod
Page 316 and 317: 290 BIBLIOGRAPHIE[13] Bamford, W. A
Page 318 and 319: 292 BIBLIOGRAPHIE[44] Dailey, R. L.
Page 320 and 321: 294 BIBLIOGRAPHIE[75] Hussein, I. I
Page 322 and 323: 296 BIBLIOGRAPHIE[106] Losser, Y. A
Page 326 and 327: 300 BIBLIOGRAPHIE[167] Stilwell, D.
Page 328 and 329: 302 BIBLIOGRAPHIE[197] Yamamoto, T.
Page 331: Annexe AConstantes et unitésConsta
Page 334 and 335: 308 B. NOTATIONSLe carré d’une m
Page 336 and 337: 310 B. NOTATIONSLa dérivée tempor
Page 339 and 340: Annexe CNotions de base en cinémat
Page 341 and 342: C.1 Cinématique 315Figure C.1 - Un
Page 343 and 344: C.1 Cinématique 317Cette matrice e
Page 345 and 346: C.1 Cinématique 319Nous utiliseron
Page 347 and 348: C.1 Cinématique 321Il est possible
Page 349 and 350: C.2 Dynamique 323l’expression (C.
Page 351 and 352: C.2 Dynamique 325Figure C.5 - Corps
Page 353 and 354: C.2 Dynamique 327= m −→ •−
Page 355 and 356: Annexe DCalcul des gradients et hes
Page 357 and 358: D.2 Deuxième harmonique zonal (J 2
Page 359 and 360: Annexe ENon-existence d’une repr
Page 361 and 362: 335- Condition d’ordre trois (N =
Page 363 and 364: Annexe FTransformée de Fourier dis
Page 365 and 366: Annexe GThéorème de Floquet ettra
Page 367: 341Le logarithme naturel log z d’
Page 370 and 371: 344 H. LA SYNTHÈSE H 2Les dimensio
Page 372 and 373: 346 H. LA SYNTHÈSE H 2Tout d’abo
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Annexe IDistance entre un hyper-ell
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I.1 Premier algorithme 351longueurs
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I.2 Deuxième algorithme 353˜x (k)
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I.2 Deuxième algorithme 355Mainten
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Annexe JRéduction de correcteursL
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359Le critère pour la réduction d
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