Modelamiento promediado no lineal de convertidores de potencia

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dc.contributor.advisorAngulo García, Fabiola
dc.contributor.advisorOsorio Londoño, Gustavo Adolfo
dc.contributor.authorGiraldo Hernández, David Eduardo
dc.contributor.researchgroupPercepción y Control Inteligente (Pci)
dc.date.accessioned2026-02-27T14:45:08Z
dc.date.available2026-02-27T14:45:08Z
dc.date.issued2025
dc.descriptiongraficasspa
dc.description.abstractEsta tesis presenta un modelado promediado de los convertidores flyback y boost bajo dos estrategias de control distintas, además, presenta el desarrollo de un mapa de tiempo discreto del convertidor flyback. En cada uno de estos modelos destaca una formulación alternativa basada en la corriente de valle. A diferencia de los modelos promediados convencionales, esta metodología emplea la corriente exacta de valle como variable de estado, lo que permite detectar con precisión las transiciones entre modos de conducción y capturar de manera fiel el comportamiento dinámico de los convertidores. El uso de la corriente de valle proporciona, además, una reducción significativa en los tiempos de simulación, manteniendo al mismo tiempo una alta precisión en los resultados. Esta ventaja convierte al modelo en una herramienta eficiente para el análisis y diseño de sistemas electrónicos de potencia, donde el equilibrio entre exactitud y desempeño computacional resulta esencial. Los resultados obtenidos demuestran que los modelos promediados propuestos constituyen una herramienta sólida para el estudio y optimización de convertidores de potencia, combinando precisión con bajo esfuerzo computacional y aportando fundamentos útiles tanto para la investigación como para aplicaciones prácticas (Texto tomado de la fuente).spa
dc.description.abstractThis thesis presents an averaged modeling of flyback and boost converters under two different control strategies, as well as the development of a discrete-time map of the flyback converter. Each of these models highlights an alternative formulation based on valley current. Unlike conventional averaged models, this methodology employs the exact valley current as a state variable, which enables precise detection of conduction mode transitions and accurately captures the dynamic behavior of the converters. The use of valley current also provides a significant reduction in simulation time while maintaining high accuracy in the results. This advantage makes the model an efficient tool for the analysis and design of power electronic systems, where the balance between accuracy and computational performance is essential. The results demonstrate that the proposed averaged models constitute a robust tool for the study and optimization of power converters, combining precision with low computational effort and providing useful foundations for both research and practical applications.eng
dc.description.curricularareaEléctrica, Electrónica, Automatización Y Telecomunicaciones.Sede Manizales
dc.description.degreelevelMaestría
dc.description.degreenameMagíster en Ingeniería - Automatización Industrial
dc.description.researchareaAnálisis de sistemas dinámicos y convertidores de potencia
dc.format.extentx, 53 páginas
dc.format.mimetypeapplication/pdf
dc.identifier.instnameUniversidad Nacional de Colombiaspa
dc.identifier.reponameRepositorio Institucional Universidad Nacional de Colombiaspa
dc.identifier.repourlhttps://repositorio.unal.edu.co/spa
dc.identifier.urihttps://repositorio.unal.edu.co/handle/unal/89700
dc.language.isospa
dc.publisherUniversidad Nacional de Colombia
dc.publisher.branchUniversidad Nacional de Colombia - Sede Manizales
dc.publisher.facultyFacultad de Ingeniería y Arquitectura
dc.publisher.placeManizales, Colombia
dc.publisher.programManizales - Ingeniería y Arquitectura - Maestría en Ingeniería - Automatización Industrial
dc.relation.indexedAgrosavia
dc.relation.indexedBireme
dc.relation.indexedRedCol
dc.relation.indexedLaReferencia
dc.relation.indexedAgrovoc
dc.relation.referencesAgarwal, A.; Prabowo, Y. & Bhattacharya, S.: , 2023; Analysis and design considerations of input parallel output series-phase shifted full bridge converter for a high-voltage capacitor charging power supply system; IEEE Transactions on Industry Applications; 59 (5): 6037--6050; doi:10.1109/TIA.2023.3276353.
dc.relation.referencesAkbarabadi, S. A.; Atighechi, H. & Jatskevich, J.: , 2013; Circuit-averaged and state-space-averaged-value modeling of secondorder flyback converter in ccm and dcm including conduction losses; en 4th International Conference on Power Engineering, Energy and Electrical Drives; IEEE; págs. 995--1000.
dc.relation.referencesAl-Baidhani, H.; Salvatierra, T.; Ordóñez, R. & Kazimierczuk, M. K.: , 2020; Simplified nonlinear voltage-mode control of pwm dc-dc buck converter; IEEE Transactions on Energy Conversion; 36 (1): 431--440.
dc.relation.referencesAl-Numay, M.: , 2009; Averaged discrete-time model for fast simulation of pwm converters in dcm; International Journal of Modelling and Simulation; 29 (1): 46--51.
dc.relation.referencesAndreescu, G.-D.; Cornea, O.; Muntean, N. & Guran, E.: , 2015; Bidirectional flyback inverter with low output voltage thd; en 2015 IEEE 10th Jubilee International Symposium on Applied Computational Intelligence and Informatics; IEEE; págs. 95--99.
dc.relation.referencesAngulo, F.; Giraldo, D. E.; Rojas, S.; Bolaños, M. A.; Osorio, G.; Astaiza, N.; Mina-Casaran, J. D. & Herrera, W.: , 2024; A novel nonlinear averaged model for a flyback converter with peak current mode control; en 2024 International Conference on Electrical, Computer and Energy Technologies (ICECET; IEEE; págs. 1--6.
dc.relation.referencesAvila, A.; Garcia-Bediaga, A.; Alzuguren, I.; Vasic, M. & Rujas, A.: , 2022; enA Modular Multifunction Power Converter Based on a Multiwinding Flyback Transformer for EV Application; IEEE Transactions on Transportation Electrification; 8 (1): 168--179; doi:10.1109/TTE.2021.3107951; URL https://ieeexplore.ieee.org/document/9523549/.
dc.relation.referencesAzer, P. & Emadi, A.: , 2020; Generalized state space average model for multi-phase interleaved buck, boost and buck-boost dc-dc converters: Transient, steady-state and switching dynamics; IEEE Access; 8: 77735--77745.
dc.relation.referencesBacha, S.; Munteanu, I.; Bratcu, A. I. et al.: , 2014; Power electronic converters modeling and control; Advanced textbooks in control and signal processing; 454: 454.
dc.relation.referencesBaek, J. & Shin, J.-W.: , 2023; Averaged model of single-ended primary inductor converter in discontinuous inductor current mode; en 2023 11th International Conference on Power Electronics and ECCE Asia (ICPE 2023-ECCE Asia); IEEE; págs. 2145--2150.
dc.relation.referencesBaxter, J. A. & Costinett, D. J.: , 2019; Converter analysis using discrete time state-space modeling; en 2019 20th Workshop on Control and Modeling for Power Electronics (COMPEL); IEEE; págs. 1--8.
dc.relation.referencesBenadero, L.; El Aroudi, A.; Martinez-Salamero, L. & Tse, C. K.: , 2023; In-depth analysis of smooth and nonsmooth bifurcations for an open-loop boost converter feeding constant power loads in discontinuous conduction mode; International Journal of Bifurcation and Chaos; 33 (04): 2350043.
dc.relation.referencesBereš, M.; Kováč, D.; Vince, T.; Kováčová, I.; Molnár, J.; Tomčíková, I.; Dziak, J.; Jacko, P.; Fecko, B. & Gans, Š.: , 2021; Efficiency enhancement of non-isolated dc-dc interleaved buck converter for renewable energy sources; Energies; 14 (14): 4127.
dc.relation.referencesCalvo, C. R.: , 2023; Estudio de paralelización de convertidores Flyback en aplicaciones de carga de baterías y condensadores de hasta 1.2 kilovatios; Tesis Doctoral; Universidad de León.
dc.relation.referencesCao, J.; Chen, B.; Ye, H. & Feng, J.: , 2023; A peak-current mode boost converter with fast linear transient response; Microelectronics Journal; 139: 105897.
dc.relation.referencesCheng, C.; Xie, F.; Zhang, B.; Qiu, D.; Xiao, W. & Ji, H.: , 2022; Modeling and nonlinear dynamic analysis of cascaded dc--dc converter systems based on simplified discrete mapping; IEEE Transactions on Industrial Electronics; 70 (6): 5830--5839.
dc.relation.referencesChoi, J.-H.; Kwon, H.-M. & Lee, J.-Y.: , 2022; Design of a 3.3 kw/100 khz ev charger based on flyback converter with active snubber; IEEE Transactions on Vehicular Technology; 71 (7): 7161--7170.
dc.relation.referencesDhifaou, R. & Brahmi, H.: , 2021; Fast simulation and chaos investigation of a dc-dc boost inverter; Complexity; 2021 (1): 9162259.
dc.relation.referencesEl Aroudi, A.; Robert, B. & Martinez-Salamero, L.: , 2006; Modelling and analysis of multicell converters using discrete time models; en 2006 IEEE International Symposium on Circuits and Systems; IEEE; págs. 4--pp.
dc.relation.referencesEl Aroudi, A.; Haroun, R.; Al-Numay, M.; Calvente, J. & Giral, R.: , 2019a; A large-signal model for a peak current mode controlled boost converter with constant power loads; IEEE Journal of Emerging and Selected Topics in Power Electronics; 9 (1): 559--568.
dc.relation.referencesEl Aroudi, A.; Martinez-Treviño, B. A.; Vidal-Idiarte, E. & Martinez-Salamero, L.: , 2019b; Mitigating the problem of inrush current in a digital sliding mode controlled boost converter taking into account load and inductor nonlinearities and propagation delay in the feedback loop; en 2019 IEEE International Symposium on Circuits and Systems (ISCAS); IEEE; págs. 1--5.
dc.relation.referencesElmes, J.; Jourdan, C.; Abdel-Rahman, O. & Batarseh, I.: , 2009; High-voltage, high-power-density dc-dc converter for capacitor charging applications; en 2009 Twenty-Fourth Annual IEEE Applied Power Electronics Conference and Exposition; IEEE; págs. 433--439.
dc.relation.referencesFeng, W.; Chen, Y.; Jiang, J. & Jiang, W.: , 2020; Modeling and controller design of flyback converter operating in dcm for led constant current drive; en IOP Conference Series: Earth and Environmental Science, tomo 512; IOP Publishing; pág. 012172.
dc.relation.referencesForouzesh, M.; Siwakoti, Y. P.; Gorji, S. A.; Blaabjerg, F. & Lehman, B.: , 2017; Step-up dc--dc converters: a comprehensive review of voltage-boosting techniques, topologies, and applications; IEEE transactions on power electronics; 32 (12): 9143--9178.
dc.relation.referencesGasparri, O.; Di Lorenzo, R.; Pidutti, A.; Del Croce, P. & Baschirotto, A.: , 2020; Dc-dc buck converter with constant off-time peak current mode control; en 2020 27th IEEE International Conference on Electronics, Circuits and Systems (ICECS); IEEE; págs. 1--4.
dc.relation.referencesGiraldo-Hernández, D. E.; Bolaños-Navarrete, M. A.; Angulo, F.; Osorio, G.; Astaiza, N.; Mina-Casaran, J. D. & Herrera, W.: , 2025a; Large-signal nonlinear average model for a voltage-controlled flyback converter; Energies; 18 (3): 451.
dc.relation.referencesGiraldo-Hernández, D. E.; Bolaños-Navarrete, M. A.; Angulo, F.; Osorio, G.; Astaiza, N.; Mina-Casaran, J. D. & Herrera, W.: , 2025b; Development of a discrete-time map for nonlinear analysis of flyback converter; International Journal of Electrical and Electronic Engineering Telecommunications; 14 (2): 94--100.
dc.relation.referencesGökçegöz, F.; Akboy, E. & Hülya Obdan, A.: , 2021; Analysis and design of a flyback converter for universal input and wide load ranges; Electrica; 21 (2): 235--241.
dc.relation.referencesGonzález, H.: , 2012; Generalización de le ecuación de bernoulli a partir de la dinámica de newton; Lat. Am. J. Phys. Educ; 6 (4): 585--588.
dc.relation.referencesGraziani, S. F.; Barchowsky, A. & Grainger, B. M.: , 2018; A flying capacitor multilevel flyback converter for pulsed power applications; en 2018 IEEE Energy Conversion Congress and Exposition (ECCE); IEEE; págs. 7063--7068.
dc.relation.referencesGraziani, S. F.; Cook, T. V. & Grainger, B. M.: , 2022; Isolated flying capacitor multilevel converters; IEEE Open Journal of Power Electronics; 3: 197--208.
dc.relation.referencesGu, D.; Xi, J. & He, L.: , 2019; A digital pwm controller of mhz active clamp flyback with gan devices for ac-dc adapter; en IECON 2019-45th Annual Conference of the IEEE Industrial Electronics Society, tomo 1; IEEE; págs. 1496--1501.
dc.relation.referencesGui, Y.; Han, R.; M. Guerrero, J.; C. Vasquez, J.; Wei, B. & Kim, W.: , 2021; enLarge-Signal Stability Improvement of DC-DC Converters in DC Microgrid; IEEE Transactions on Energy Conversion; 36 (3): 2534--2544; doi:10.1109/TEC.2021.3057130; URL https://ieeexplore.ieee.org/document/9347789/.
dc.relation.referencesHart, D. W.: , 2001; Electrónica de Potencia; Prentice Hall; 1a edición; ISBN 84-205-3179-0.
dc.relation.referencesHowimanporn, S. & Bunlaksananusorn, C.: , 2003; Performance comparison of continuous conduction mode (ccm) and discontinuous conduction mode (dcm) flyback converters; en The Fifth International Conference on Power Electronics and Drive Systems, 2003. PEDS 2003., tomo 2; IEEE; págs. 1434--1438.
dc.relation.referencesIordanov, P. & Halton, M.: , 2012; Discrete-time modelling and robust analysis of a buck converter; IFAC Proceedings Volumes; 45 (13): 647--652.
dc.relation.referencesJafari, H. & Habibi, M.: , 2019; High-voltage charging power supply based on an lcc-type resonant converter operating at continuous conduction mode; IEEE Transactions on Power Electronics; 35 (5): 5461--5478.
dc.relation.referencesLee, C.-H.; Shin, B. H. & Bang, Y.-B.: , 2015; Designing a permanent-magnetic actuator for vacuum circuit breakers using the taguchi method and dynamic characteristic analysis; IEEE Transactions on Industrial Electronics; 63 (3): 1655--1664.
dc.relation.referencesLitrán, S. P.; Durán, E.; Semião, J. & Díaz-Martín, C.: , 2022; Multiple-output dc--dc converters: Applications and solutions; Electronics; 11 (8): 1258.
dc.relation.referencesMaestri, S.; Retegui, R. G.; Uicich, G.; Benedetti, M. & Cravero, J. M.: , 2013; Comparison of topologies suitable for capacitor charging systems; en 2013 15th European Conference on Power Electronics and Applications (EPE); IEEE; págs. 1--9.
dc.relation.referencesMao, Y.-J.; Lam, C.-S.; Sin, S.-W.; Wong, M.-C. & Martins, R. P.: , 2018; Review and selection strategy for highaccuracy modeling of pwm converters in dcm; Journal of Electrical and Computer Engineering; 2018 (1): 3901693; doi: https://doi.org/10.1155/2018/3901693; URL https://onlinelibrary.wiley.com/doi/abs/10.1155/2018/3901693.
dc.relation.referencesMirzaei, A. & Rezvanyvardom, M.: , 2020; High voltage gain soft switching full bridge interleaved flyback dc-dc converter for pv applications; Solar Energy; 196: 217--227.
dc.relation.referencesNduwamungu, A.; Lie, T. T.; Lestas, I.; Nair, N.-K. C. & Gunawardane, K.: , 2024; Control strategies and stabilization techniques for dc/dc converters application in dc mgs: Challenges, opportunities, and prospects—a review; Energies; 17 (3): 669.
dc.relation.referencesNelms, R. & Schatz, J. E.: , 1992; A capacitor charging power supply utilizing a ward converter; IEEE Transactions on Industrial Electronics; 39 (5): 421--428.
dc.relation.referencesNirgude, G.; Tirumala, R. & Mohan, N.: , 2001; A new, large-signal average model for single-switch dc-dc converters operating in both ccm and dcm; en 2001 IEEE 32nd Annual Power Electronics Specialists Conference (IEEE Cat. No. 01CH37230), tomo 3; IEEE; págs. 1736--1741.
dc.relation.referencesPavlovic, T.; Bjazic, T. & Ban, Z.: , 2012; Simplified averaged models of dc--dc power converters suitable for controller design and microgrid simulation; IEEE transactions on Power electronics; 28 (7): 3266--3275.
dc.relation.referencesPeretz, M. M. & Ben-Yaakov, S.: , 2009; A heuristic digital control method for optimal capacitor charging; en 2009 IEEE Energy Conversion Congress and Exposition; IEEE; págs. 1118--1125.
dc.relation.referencesPesce, C.; Riedemann, J.; Peña, R.; Degano, M.; Pereda, J.; Villalobos, R.; Maury, C.; Young, H. & Andrade, I.: , 2021; A modified multi-winding dc--dc flyback converter for photovoltaic applications; Applied Sciences; 11 (24): 11999.
dc.relation.referencesPonce-Silva, M.; Salazar-Pérez, D.; Rodríguez-Benítez, O. M.; Vela-Valdés, L. G.; Claudio-Sánchez, A.; De León-Aldaco, S. E.; Cortés-García, C.; Saavedra-Benítez, Y. I.; Lozoya-Ponce, R. E. & Aquí-Tapia, J. A.: , 2020; Flyback converter for solid-state lighting applications with partial energy processing; Electronics; 10 (1): 60.
dc.relation.referencesPrakash, K. S. & Barai, M.: , 2016; Time-variant slope compensation for peak current mode control (pcmc) of boost converter with point-of-load applications; en 2016 IEEE 6th International Conference on Power Systems (ICPS); IEEE; págs. 1--6.
dc.relation.referencesRaj, A. & Praveen, R.: , 2022; Highly efficient dc-dc boost converter implemented with improved mppt algorithm for utility level photovoltaic applications; Ain Shams Engineering Journal; 13 (3): 101617.
dc.relation.referencesRamos-Paja, C. A.; Bastidas-Rodriguez, J. D. & Saavedra-Montes, A. J.: , 2021; Design and control of a battery charger/discharger based on the flyback topology; Applied Sciences; 11 (22): 10506.
dc.relation.referencesRashid, M. H.: , 2014; Power electronics : devices, circuits, and applications; Pearson; 4a edición; ISBN 9780273785149; 0273785141.
dc.relation.referencesRashid, M. H.: , 2017; Power electronics handbook; Butterworth-heinemann.
dc.relation.referencesRashid, M. H.: , 2023; Power electronics Handbook; Butterworth-Heinemann; 5a edición; ISBN 9780323992169.
dc.relation.referencesRavi, V.; Satpathy, S. & Lakshminarasamma, N.: , 2019; An energy-based analysis for high voltage low power flyback converter feeding capacitive load; IEEE Transactions on Power Electronics; 35 (1): 546--564.
dc.relation.referencesRodríguez, J. C. & Grijalva, F.: , 2020; Modeling a switching-regulated capacitively coupled power supply for medium-voltage ac; IEEE Journal of Emerging and Selected Topics in Power Electronics; 10 (1): 52--60.
dc.relation.referencesRojas, S.; Giraldo, D. E.; Angulo, F.; Bolaños, M. A.; Osorio, G.; Astaiza, N.; Silva, J. & Herrera, W.: , 2023; Modeling and control design of a fast capacitor charger using a power converter; en 2023 IEEE 6th Colombian Conference on Automatic Control (CCAC); IEEE; págs. 1--5.
dc.relation.referencesSayed, K.; Almutairi, A.; Albagami, N.; Alrumayh, O.; Abo-Khalil, A. G. & Saleeb, H.: , 2022; A review of dc-ac converters for electric vehicle applications; Energies; 15 (3): 1241.
dc.relation.referencesSeguel, J. L.; Seleme Jr, S. I. & Morais, L. M.: , 2022; Comparative study of buck-boost, sepic, cuk and zeta dc-dc converters using different mppt methods for photovoltaic applications; Energies; 15 (21): 7936.
dc.relation.referencesShah, C.; Vasquez-Plaza, J. D.; Campo-Ossa, D. D.; Patarroyo-Montenegro, J. F.; Guruwacharya, N.; Bhujel, N.; Trevizan, R. D.; Rengifo, F. A.; Shirazi, M.; Tonkoski, R. et al.: , 2021; Review of dynamic and transient modeling of power electronic converters for converter dominated power systems; IEEE Access; 9: 82094--82117.
dc.relation.referencesSokal, N. O. & Redl, R.: , 1990; Control algorithms and circuit designs for optimally flyback-charging an energy-storage capacitor (eg for a flash lamp); en Fifth Annual Proceedings on Applied Power Electronics Conference and Exposition; IEEE; págs. 295--302.
dc.relation.referencesSokal, N. O. & Redl, R.: , 1997; Control algorithms and circuit designs for optimal flyback-charging of an energy-storage capacitor (eg, for flash lamp or defibrillator); IEEE Transactions on Power Electronics; 12 (5): 885--894.
dc.relation.referencesSystem, H. P.: , 2023; Hughes recloser description; URL https://hughespowersystem.com/en/reclosers.html.
dc.relation.referencesTahami, F.; Abedi, M. & Rezaei, K.: , 2010; Optimum nonlinear model predictive controller design for flyback pfc rectifiers; en 2010 IEEE Symposium on Industrial Electronics and Applications (ISIEA); IEEE; págs. 70--75. Thummala, P.; Zhang, Z. & Andersen, M. A.: , 2013; High voltage bi-directional flyback converter for capacitive actuator; en 2013 15th European Conference on Power Electronics and Applications (EPE); IEEE; págs. 1--10.
dc.relation.referencesVračar, D. & Pejović, P.: , 2022; Active-clamped flyback dc-dc converter in an 800v application: Design notes and control aspects; Journal of Electrical Engineering; 73 (4): 237--247.
dc.relation.referencesVračar, D. & Pejović, P. V.: , 2022; Active-clamp flyback converter as auxiliary power-supply of an 800 v inductive-charging system for electric vehicles; IEEE Access; 10: 38254--38271; doi:10.1109/ACCESS.2022.3165059.
dc.relation.referencesXiao, Z.; Lei, W.; Gao, G.; Wang, H. & Mu, W.: , 2024; Simplified discrete-time modeling for convenient stability prediction of dab converter in energy storage system; IEEE Transactions on Power Electronics.
dc.relation.referencesXue, Y.; Chang, L.; Kjaer, S. B.; Bordonau, J. & Shimizu, T.: , 2004; Topologies of single-phase inverters for small distributed power generators: an overview; IEEE Transactions on Power Electronics; 19 (5): 1305--1314; doi:10.1109/TPEL.2004.833460.
dc.relation.referencesYan, D.; Yang, C.; Hang, L.; He, Y.; Luo, P.; Shen, L. & Zeng, P.: , 2021; Review of general modeling approaches of power converters; Chinese Journal of Electrical Engineering; 7 (1): 27--36.
dc.relation.referencesYuanbin, W.: , 2009; Research on chaos in switching dc-dc converters; en 2009 Second International Conference on Intelligent Computation Technology and Automation, tomo 3; IEEE; págs. 91--94.
dc.relation.referencesZeng, J.; Zhang, G.; Yu, S. S.; Zhang, B. & Zhang, Y.: , 2020; Llc resonant converter topologies and industrial applications—a review; Chinese Journal of Electrical Engineering; 6 (3): 73--84.
dc.relation.referencesZhou, S.; Zhou, G.; He, M.; Mao, S.; Zhao, H. & Liu, G.: , 2023; Stability effect of different modulation parameters in voltage-mode pwm control for ccm switching dc-dc converter; IEEE Transactions on Transportation Electrification.
dc.rights.accessrightsinfo:eu-repo/semantics/openAccess
dc.rights.licenseReconocimiento 4.0 Internacional
dc.rights.urihttp://creativecommons.org/licenses/by/4.0/
dc.subject.ddc620 - Ingeniería y operaciones afines::621 - Física aplicada
dc.subject.proposalConvertidores de potencia CC-CCspa
dc.subject.proposalConvertidores flybackspa
dc.subject.proposalConvertidores boostspa
dc.subject.proposalTécnicas promediadasspa
dc.subject.proposalSistemas en tiempo discretospa
dc.subject.proposalControl de corrientespa
dc.subject.proposalControl de voltajespa
dc.subject.proposalDC-DC power converterseng
dc.subject.proposalFlyback converterseng
dc.subject.proposalBoost converterseng
dc.subject.proposalAveraged techniqueseng
dc.subject.proposalDiscrete time systemseng
dc.subject.proposalCurrent controleng
dc.subject.proposalVoltage controleng
dc.subject.unescoTecnología electrónica
dc.subject.unescoElectronic engineering
dc.titleModelamiento promediado no lineal de convertidores de potenciaspa
dc.title.translatedNonlinear averaged modeling of power converterseng
dc.typeTrabajo de grado - Maestría
dc.type.coarhttp://purl.org/coar/resource_type/c_bdcc
dc.type.coarversionhttp://purl.org/coar/version/c_ab4af688f83e57aa
dc.type.contentText
dc.type.driverinfo:eu-repo/semantics/masterThesis
dc.type.versioninfo:eu-repo/semantics/acceptedVersion
dcterms.audience.professionaldevelopmentBibliotecarios
dcterms.audience.professionaldevelopmentEstudiantes
dcterms.audience.professionaldevelopmentInvestigadores
dcterms.audience.professionaldevelopmentMaestros
oaire.accessrightshttp://purl.org/coar/access_right/c_abf2
oaire.awardtitleValidación tecnológica para la fabricación de reconectadores automáticos para redes inteligentes, del tipo seco con polos encapsulados utilizando compuestos poliméricos termoestables, contrato No. 099-2022.
oaire.fundernameMinisterio de Ciencia, Tecnología e Innovación y al Fondo Nacional para el Financiamiento de la Ciencia, la Tecnología y la Innovación Francisco José de Caldas
oaire.fundernameRymel Ingeniería Eléctrica S.A.S.

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