An Electrothermal DMOS Model in ELDO applied to
the simulation of an integrated H-bridge (St. 17) 4.088
O. Schepp, A. Kostka, Technical University of Darmstadt,
Germany
Modelling the Forward Recovery of the High Power Diode
for Circuit Simulation (St. 18) 4.094
Rémy Kolessar, Royal Institute of Technology,
Bo Danielsson, ABB Power Systems AB, Sweden
A new model of a mos component compatible with
the automatic circuit simulation (St. 19) 4.099
Z. Bestaoui, C. Batard, B. Feuvrie, C. Bergmann,
IUT de Nantes, France
The Lumped-Charge Buffered Power Diode Model for
High Power Applications (St. 20) 4.105
Kraig J. Olejniczak, Zia Hossain, University of Arkansas,
Eric X. Yang, Vic A.K. Temple, Harris Semiconductor,
Cliff L. Ma, Analogy Inc., USA
An Automatic Parameter Extraction Technique for an
Improved PiN Diode Circuit Model (St. 21) 4.111
Antonio Strollo, Ettore Napoli, University of Naples,
Luigi Fratelli, Giuseppe Giannini, Ansaldo Trasporti, Italy
High Critical Temperature Superconducting Switches
for Power Electronics Applications (St. 22) 4.117
L. Garcia-Tabarés, I. Iglesias, A. Ramos, J.M. Asanza,
J. Calero, CEDEX, P. Abramian, CIEMAT, L.A. Angurel,
C. Diez, ICMA, X. Obradors, X. Granadors, ICMAB, Spain
An Accurate Circuit Model for Coreless PCB-based
transformers (St. 23) 4.123
S. Y. R. Hui, H. Chung, S. C. Tang, City University of
Hong Kong, Hong Kong
Analytical Model for Dynamic Avalanche Breakdown
in Power Devices (St. 24) 4.129
L. Göhler, Universität der Bundeswehr München,
J. Sigg, Siemens AG, Germany
General Approach to Thermal Simulation of Modern
Smart Power Modules (St. 25) 4.134
M. Furmanczyk, A. Szajfler, A. Napieralski, Technical
University of Lódz, Poland
The IGBT model optimised for the circuit analysis and
design (St. 26) 4.139
Witold Pawelski, Andrzej Napieralski, Technical University of
Lodz, Poland
PSPICE model for high voltage IGBTs (St. 27) 4.145
Giovanni Busatto, A. Polverino, Università di Napoli "Federico II“,
L. Fratelli, G. Giannini, Ansaldo Trasporti, Italy
Electrothermal simulation of fast switching integrated
power elctronic circuits (St. 28) 4.151
P. Vales, J.M. Dorkel, LAAS, France
On-State Electrothermal Modelling of Large Area Power
Components and Multichip Power Modules (St. 29) 4.157
K. Bellil, P. Tounsi, J.-M. Dorkel, Laboratoire d’Analyse et
d’Architecture des Syst. du CNRS,
Ph. Leturcq, Institut National des Sciences Appliquées
de Toulouse, France
Session D2a: Multilevel and matrix converters
Session Chairman:
Prof. B. Davat, GREEN, Nancy, France
Three-Phase Three-Level Voltage-Source Converters
Coupled with Harmonic Canceling Interphase Reactors 4.162
Kuniomi Oguchi, Naoya Nakajima, Takahiko Sano,
Ibaraki University, Japan (St. 30)
Stability Analysis of Multilevel Converters with Imbricated
Cells (St. 31) 4.168
J.L. Duarte, P.J.M. Julicher, L.J.J. Offringa, W.D.H. v.
Groningen, Eindhoven University of Technology, The Netherlands
Five Level Laboratory VAr Compensator With Separated
Floating DC Voltages (St. 32) 4.175
Tonny W. Rasmussen, Technical University of Denmark,
Denmark
Control strategy for multilevel converter applied for
electric power system (St. 33) 4.181
Noriyuki Kimura, Akira Matsumoto, Toshimitsu Morizane,
Katsunori Taniguchi, Osaka Institute of Technology, Japan
Serial connection: soft switching a way to reduce
parasitic overcurrents (St. 34) 4.187
N. Lapassat, D. Chatroux, Commissariat à l’Energie Atomique,
D. Lafore, CEGEMA-ESIM, France
Switch-Effective Modulation Strategy for Matrix Converters 4.193
Åke Christensson, ABB Corporate Research, Sweden (St. 35)
A Matrix Converter switching controller for low losses
operation without snubber circuits (St. 36) 4.199
J-J Huselstein, R. Cittadini, C. Glaize, Université Montpellier II,
France
A 3kW unit-power-factor multilevel rectifier based on
a double-boost converter (St. 37) 4.204
Patrick Bartholomeus, Philippe Le Moigne,
Ecole Centrale de Lille, France
Single- and three-phase multilevel converters for traction
systems 50Hz/16 2/3 Hz (St. 38) 4.210
N. Schibli, A.-Ch. Rufer, Swiss Federal Institute of Technology,
Switzerland
A new approach in multilevel power conversion (St. 39) 4.216
Mario Marchesoni, A. Damiano, Università degli Studi
di Cagliari,
M. Fracchia, Università degli Studi di Genova,
I. Marongiu, Università degli Studi di Cagliari, Italy
Session D2b: Power converters
Session Chairman:
Prof. J. W. Kolar, T. U. Vienna, Austria
Thyristor power supplies for plasma technology (St. 40) 4.222
Teolan Tomson, Estonian Energy Research Institute , Estonia,
Aruy Marotta, Heinz Hoppe de Souza, Ins. de Fisika
“Gleb Wataghin”, Brazil
An Improved Three-Phase Diode Rectifier for Reducing
AC Line Current Harmonics (St. 41) 4.227
Shigeo Masukawa, Shoji Iida, Tokyo Denki University, Japan
Optimizing Switching Losses and EMC of Pulse Controlled
Inverters using EMC-Snubber Circuits (St. 42) 4.233
Olaf Scheuer, B. Orlik, University of Bremen, Germany
DC Link Currents in Bidirectional Power Converters with
Coordinated Pulse Patterns (St. 43) 4.239
L. Sack, University of Erlangen, Germany
The space vector control of the PWM-Rectifier using
U/f references (St. 44) 4.245
Jaakko Ollila, Tampere University of Technology, Finland
Comparison of state of the art Gate Drive Techniques for
High Side Switch (St. 45) 4.250
I. Zverev, University of Rostock, S. Konrad,
V. Schilling, Technical University of Ilmenau,
J. Petzoldt, University of Rostock, Germany
Analysis of Phase-Shift Controlled AC-AC Converters
Based on Switching Vector Theory (St. 46) 4.256
J. Kyyrä, Helsinki University of Technology, Finland
The energy efficient defence circuits of the commuter train
converters (St. 47) 4.262
S.I. Volsky, P. V. Butenko, E.A. Lomonova,
Moscow State Aviation Institute, Russia,
A.B. Uan-Zo-li, Virginia Tech, USA,
J.B. Klaassens, Delft Technical University, The Netherlands
A new forward converter using non-dissipative snubber 4.268
João B. Vieira Jr., Universidade Federal de Uberlândia,
J. A. Corrêa Pinto, Escola Técnica Federal do Pará - ETFPA,
A. A. Pereira, V. J. Farias, L. C. de Freitas, Universidade
Federal de Uberlândia, Brasil (St. 48)
Watercooled GTO Compact Converter (St. 49) 4.272
Heinrich Baumann, Johannes Scholten, Manfred Zengerle,
ABB Daimler-Benz Transportation GmbH, Germany
An optimised energy recovery snubber circuit for
switching power converters (St. 50) 4.276
Diana Izvorska, Joe Leisten, University of Teesside, U. K.,
Petrov Roumen, Swichtec Power Systems Ltd, New Zealand
Protective Device for Electronic Tap Changer for
Distribution Transformers (St. 51) 4.282
P. Bauer, S.W. de Haan, TU Delft, The Netherlands
A Novel Direct Frequency Converter Structure
Controlled by a Cooperative Predictive Algorithm (St. 52) 4.286
Eduardo P Wiechman, Rolando P Burgos, Universidad de
Concepcion, Jose R. Rodriguez, Universidad Santa Maria, Chile
High power Soft Switching PWM IGBT Converter Electrical
and EMC Characterization (St. 53) 4.292
Cazabat S., Gonzalez J., Alcatel Alsthom Recherche,
Critchley R., Cegelec, Forest F., Melhem W., LESIR,
Pouliquen H., EDF, A. Puzo, Alcatel Alsthom Recherche, France
High power factor high efficiency bidirectional GTO
rectifiers for locomotive application (St. 54) 4.298
J. Bou Saada, P. Colignon, P. Thomas, GEC-Alsthom
ACEC Transport, F. Avaux, L. Delporte, P. Mathys, ULB Elmitel,
Belgium
Modular DC-link converter units for the power supply of
electrical railway networks (St. 55) 4.305
P.G. Kamp, B. Endres, M. Wolf, Siemens AG, Germany
Session D2c: Resonance applications
Session Chairman:
Prof. Y. Cheron, LEEI/ENSEEIHT, France
Improvement of the power factor of dimmers using high
frequency zero current switching (St. 56) 4.311
G. Schröder, University of Siegen, K.-J. Lux, Micromatik GmbH,
B.H. Yu, D-Tech GmbH, H. Siebel, University of Siegen, Germany
Novel zero current switching high frequency inverter
applied for an emission control in diesel engine (St. 57) 4.315
Yoshihiro Hatanaka, Sachio Kubota, Sekiya Yoshiaki,
Tokyo University of Mercantile Marine, Japan
Design of a LCC resonant inverter for high-frequency
lamp ballast resonant current controlled with high power
factor (St. 58) 4.321
F. Ferrero, M. Rico, A. Marcos, C. Blanco, E. Corominas,
A. Calleja, Universidad de Oviedo, Spain
Self-adjusting resonant converters and application by
high power electrical ARC furnaces (St. 59) 4.327
Kuno Janson, Jaan Järvik, Tallinn Technical University, Estonia
Soft switching inverter power source for arc welding (St. 60) 4.333
Hubert Mecke, Wolfgang Fischer, Frank Werther,
Otto-von-Guericke-University Magdeburg, Germany
A Novel Auxiliary Resonant Commutated Pole Inverter
Topology with Zero Current Turn-off Switching (St. 61) 4.338
Min-Hong Kim, Samsung Motors Inc., Dong-Seok Hyun,
Hanyang University, Korea
IGBT Half-Bridge Inverter for Induction Heating
Applications with Active Auxiliary Resonant Circuit (St. 62) 4.344
Jin-Woo Jung, LG Electronic Inc., Byoung-Kuk Lee,
Bum-Seok Suh, Dong-Seok Hyun, Hanyang University, Korea
New Phase-Shifted Soft-Switching PWM Series Resonant
Inverter Topologies and Their Practical Evaluations (St. 63) 4.350
Mutsuo Nakaoka, Yamaguchi National University, Satosi Nagai,
Tsuyama National College of Technology, Naoya Baba,
Yasuhiro Arai, Yamaguchi National University, Japan
Soft-Switched PWM High-Frequency Load-Resonant
Inverter with Power Factor Correction for Induction Heating
Cooking Appliance (St. 64) 4.356
S. P. Wang, M. Nakaoka, Yamaguchi National University,
K. Izaki, I. Hirota, H. Yamashita, H. Omori, Matsushita Electric
Industrial Co. Ltd, Japan
A Novel Resonant DC Link Multi-function Three Phase
PWM Converter for Battery Energy Storage System (St. 65) 4.362
E. Hiraki, M. Kurokawa, M. Nakaoka, Yamaguchi University, Japan
Digital predicitive current control of quasi resonant DC link
inverter fed asynchronous motors (St. 66) 4.368
Aldo Perfetto, Università di Napoli „Federico II“,
C. Attaianese, Università di Cassino, S. Meo, Università di Napoli
“Federico II”, Italy
Design Optimisation of an Active Clamp Forward Converter
(St. 67) 4.373
P.J. Haigh, Powertron Ltd., A.J. Forsyth, University of
Birmingham, United Kingdom
Session D2d: Resonance 1
Session Chairman:
Prof. Th. Meynard, LEEI/ENSEEIHT, France
A Control Analysis and Closed-Loop Design for
Serie-Parallel Resonant Converter (St. 68) 4.379
T. Planas, SUPELEC, J. Laeuffer, General Electric
Medical System-Europe, E. Godoy, B. Lorcet,
D. Sadarnac, SUPELEC, France
FPGA based Control of an ARCP-Inverter without
Additional Sensors (St. 69) 4.385
L. Sack, H.G. Eckel, K. Rascher, University of Erlangen,
Germany
A generalized sliding mode controller for half-wave
quantum resonant converters (St. 70) 4.391
Miguel Castilla, L. Garcia de Vicuña, Mariano Lopez,
Universidad Politecnica de Cataluña-UPC, Spain
A full-bridge SR-PWM DC-DC converter operating
at reduced conduction and commutation losses using
phase-shift control (St. 71) 4.397
J.B. Vieira Jr., J.C. da Silva e Sousa, A.A. Pereira,
V.J. Farias, L.C. de Freitas, Universidade Federal de
Uberlândia, Brazil
A High-Power-Factor Buck Converter with Soft-Switching
Operation (St. 72) 4.403
Katsunori Taniguchi, Toshimitsu Morizane,
Noriyuki Kimura, Osaka Institute of Technology,
Lee Hyun-Woo, Kyungnam University, Japan
Thermal Failures on a 2kW-100kHz IGBT-based DC-DC
Resonant (St. 73) 4.409
Dario D’Amore, Politecnico di Milano, Italy
Reliable method used to size a multiresonant LCCL type
converter (St. 74) 4.414
B. Dakyo, F. Lafitte, L. Protin, Université du Havre, France
Evaluation of resonant converters for increased
softswitching range (St. 75) 4.419
Roy Nilsen, Norwegian University of Science & Technology,
Terje Melaa, Tom F. Nestli, ABB Corporate Research,
Norway, Per Ranstad, ABB Fläkt Industri AB, Sweden,
Alf Kåre Ådnanes, Øye Kjartan, ABB Corporate Research,
Norway
Predicting real characteristics of buck-boost zero-voltage
switching quasi-resonant converters (St. 76) 4.426
N. P. Polyzos, E.C. Tatakis, University of Patras, Greece
Session D2e: Resonance 2
Session Chairman:
Odd Roar Schmidt, Powec, Norway
An asymmetrical reactor type zero current switching
DC-DC converter with constant frequency voltage control
(St. 77) 4.432
Masaki Suzuki, Yoshihiro Hatanaka, Sachio Kubota,
Tokyo University of Mercantile Marine, Japan
Direct three-phase „low frequency“ to single phase "high
frequency“ converter with sinusoidal line currents (St. 78) 4.438
Florent Andrianoelison, Cyril Pouet, Darius Dedecius,
LARGE, France
A series resonant DC/DC converter operating in ZVS
mode from maximum power to no load (St. 79) 4.443
Florent Andrianoelison, Darius Dedecius, LARGE,
Yvon Cheron, LEEI, France
Design Improvement and Experimental Characterization
of the Full Bridge ZVS Converter With Secondary Clamped
Inductor (St. 80) 4.448
João Beirante, Beatriz V. Borges, Instituto de
Telecomunicações, Portugal, Stanimir Valtchev,
Technical University of Sofia, Bulgaria
A Self-Resonant-PWM Boost Converter with Unity
Power Factor Operation by Using a Bang-Bang Current
Control Strategy with Fixed Switching Frequency (St. 81) 4.454
L.C. de Freitas, R. Tóffano Jr., J.C. de Oliveira, V. J. Farias,
J. B. Vieira Jr., Universidade Federal de Uberlândia, Brazil
Application of the AC link in power conversion systems
(St. 82) 4.459
Antoni Bogdan, Tadeusz Citko, Bialystok Technical University,
Poland
Improvement of Performance of Four Quadrant
Converter using Unidirectional DC Link Inductor (St. 83) 4.465
B. Dobrucky, University of Transport and Communications,
Slovak Republic, J. Kyyrä, Helsinki University of Technology,
Finland, V. Rácek, Slovak Technical University, M. Hukel,
J. Dubovsky, University of Transport and Communications,
Slovak Republic
Session D5g: Sensorless drives - Induction Machines
Session Chairman:
Prof. S. Bolognani, Univ. of Padova, Italy
Robust control of sensorless vector control drives (St. 84) 4.470
R. Blasco-Giménez, F. Morant, Univerisdad Politécnica
de Valencia, Spain
A microcontroller implementation of speed sensorless
field oriented control of induction machine (St. 85) 4.476
Martin Riese, Dresden University of Technology, Germany
A novel sensorless controller for induction motor drives
(St. 86) 4.480
Shyh-Shing Perng, National Taiwan Institute of Technology,
Yen-Shin Lai, National Taipei Institute of Technology,
Liu Chang-Huan, National Taiwan Institute of Technology,
Taiwan R.O.C.
Control of a Shaft-Sensorless Position Induction Motor
Using an Asymmetric Outer-Section Cage (St. 87) 4.486
G.M. Asher, J. Cilia, K.J. Bradley, M. Summer, University of
Nottingham, United Kingdom
Implementation of a Sensorless Induction Motor Drive
Control System with prescribed Closed Loop Speed
and Rotor Magnetic Flux Dynamics (St. 88) 4.492
S. J. Dodds, East London University, United Kingdom,
Jan Vittek, University of Zilina, Slovakia, Martin Mienkina,
Trinec Steel Works, Czech Republic
A PCMCIA DSP-card to boost inverter performance:
Sensorless drive control via extended Kalman filter (St. 89) 4.498
Eckart von Westerholt, Schneider Electric, France
Real-Time Sensorless Control for Rotor Field Oriented
Induction Motor (St. 90) 4.504
Dragos Ovidiu Kisch, Marian Ghinea, Gabriel Sirbu,
University Politehnica of Bucharest, Mariana Kisch,
Cygnus Computer Bucharest, Romania
Sensorless Vector Control of Induction Machines with
Stator Voltage Offset Compensation (St. 91) 4.508
Yukio Kataoka, Hisao Kubota, Kouki Matsuse, Meiji University,
Japan
Field Oriented Control of Induction Motor without Speed
Sensor (St. 92) 4.512
M. Hövermann, B. Orlik, U. Schumacher, University of Bremen,
Germany
Sensitivity analysis of sensorless induction motor drive
to motor parameter changes (St. 93) 4.518
Teresa Orlowska-Kowalska, Piotr Wojsznis,
Technical University of Wroclaw, Poland
DSP Implementation of an AC-Machine Sensorless
Speed Measurement System Using the Wigner Distribution 4.524
José Alex Restrepo Z, Trina A. de Pérez, María I. Giménez
de Guzmán, Victor M. Guzmán, Universidad Simón Bolivar,
Venzuela (St. 94)
Session D5h: Sensorless drives - Brushless Machines
Session Chairman:
Prof. F. Blaabjerg, Aalborg University, Denmark
A Sensorless Position control by Salient-Pole Brushless
DC Motor (St. 95) 4.529
Nobuyuki Kasa, Tokyo Metropolitan Institute of Technology,
Hiroshi Watanabe, Tokyo Metropolitan Institute of Technology,
Japan
High frequency method of sensor elimination in interior
permanent magnet (IPM) motors (St. 96) 4.535
Jun Oyama, Mengesha Mamo, Takashi Abe,
Tsuyoshi Higuchi, Eiji Yamada, Nagasaki University, Japan
An Improved Method for Sensorless Adaptive Control of
Permanent-Magnet Synchronous Motors (St. 97) 4.541
Lennart Harnefors, Peter Taube, Hans-Peter Nee,
The Royal Institute of Technology, Sweden
A DSP based controller for the sensorless control of
synchronous machines (St. 98) 4.547
D. Arab Khaburi, F. Meibody Tabar, A. Comsa,
F.M. Sargos, GREEN, France
A permanent magnet synchronous motor flux control scheme
without position sensors (St. 99) 4.553
Gastón Pesse, Tomás Pagá, Universidad Simón Bolívar,
Venezuela
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