Nome |
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Performance comparison between Surface Mounted and Interior PM motor drives for Electric Vehicle application, file e384c42e-1663-d4b2-e053-9f05fe0a1d67
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8.346
|
Efficiency maps of electrical machines, file e384c42e-6ead-d4b2-e053-9f05fe0a1d67
|
5.704
|
Direct flux vector control of IPM motor drives in the maximum torque per voltage speed range, file e384c42e-1347-d4b2-e053-9f05fe0a1d67
|
4.822
|
Comparison of Induction and PM Synchronous motor drives for EV application including design examples, file e384c42e-1d5d-d4b2-e053-9f05fe0a1d67
|
2.766
|
Core Losses and Torque Ripple in IPM Machines: Dedicated Modeling and Design Trade Off, file e384c42e-0ba6-d4b2-e053-9f05fe0a1d67
|
2.647
|
Position-sensorless control of permanent-magnet-assisted synchronous reluctance motor, file e384c42d-f6fe-d4b2-e053-9f05fe0a1d67
|
2.480
|
Direct-flux field-oriented control of IPM motor drives with robust exploitation of the Maximum Torque per Voltage speed range, file e384c42e-105a-d4b2-e053-9f05fe0a1d67
|
2.264
|
Permanent Magnet minimization in PM-Assisted Synchronous Reluctance motors for wide speed range, file e384c42e-1dbd-d4b2-e053-9f05fe0a1d67
|
2.110
|
Sensorless Direct Field-Oriented Control of Three-Phase Induction Motor Drives for Low-Cost Applications, file e384c42e-049c-d4b2-e053-9f05fe0a1d67
|
1.981
|
An Integral Battery Charger with Power Factor Correction for Electric Scooter, file e384c42e-02ef-d4b2-e053-9f05fe0a1d67
|
1.864
|
Design of a line-start synchronous reluctance motor, file e384c42e-2af6-d4b2-e053-9f05fe0a1d67
|
1.726
|
Ferrite Assisted Synchronous Reluctance Machines: a General Approach, file e384c42e-2037-d4b2-e053-9f05fe0a1d67
|
1.676
|
Sensorless position control of permanent magnet motors with pulsating current injection and compensation of motor end-effects, file e384c42e-0ddb-d4b2-e053-9f05fe0a1d67
|
1.672
|
Direct Flux Field Oriented Control of IPM Drives with Variable DC-Link in the Field-Weakening Region, file e384c42e-0699-d4b2-e053-9f05fe0a1d67
|
1.656
|
Design of synchronous reluctance motors with multiobjective optimization algorithms, file e384c42e-364a-d4b2-e053-9f05fe0a1d67
|
1.586
|
Self-Commissioning Algorithm for Inverter Non-Linearity Compensation in Sensorless Induction Motor Drives, file e384c42e-0356-d4b2-e053-9f05fe0a1d67
|
1.583
|
End effects in linear tubular motors and compensated position sensorless control based on pulsating voltage injection, file e384c42e-0a39-d4b2-e053-9f05fe0a1d67
|
1.459
|
Unified Direct-Flux Vector Control for AC Motor Drives, file e384c42e-1661-d4b2-e053-9f05fe0a1d67
|
1.385
|
Automatic Design of Synchronous Reluctance Motors focusing on Barrier Shape Optimization, file e384c42f-dd9e-d4b2-e053-9f05fe0a1d67
|
1.306
|
Accurate Inverter Error Compensation and Related Self-Commissioning Scheme in Sensorless Induction Motor Drives, file e384c42e-10b0-d4b2-e053-9f05fe0a1d67
|
1.262
|
Design tradeoffs between constant power speed range, uncontrolled generator operation and rated current of IPM motor drives, file e384c42e-1660-d4b2-e053-9f05fe0a1d67
|
1.190
|
Self-Commissioning of Inverter Nonlinear Effects in AC Drives, file e384c42e-1dbe-d4b2-e053-9f05fe0a1d67
|
1.042
|
Multipolar Ferrite Assisted Synchronous Reluctance machines: a general design approach, file e384c42e-386e-d4b2-e053-9f05fe0a1d67
|
1.006
|
Model Based, Direct Flux Vector Control of Permanent Magnet Synchronous Motor Drives, file e384c42d-e566-d4b2-e053-9f05fe0a1d67
|
998
|
A new PM-assisted Synchronous Reluctance machine with a nonconventional fractional slot per pole combination, file e384c42e-37cc-d4b2-e053-9f05fe0a1d67
|
992
|
Design of high-speed synchronous reluctance machines, file e384c42e-6ce6-d4b2-e053-9f05fe0a1d67
|
938
|
A SyR and IPM machine design methodology assisted by optimization algorithms, file e384c42e-1d55-d4b2-e053-9f05fe0a1d67
|
921
|
Experimental Identification of the Magnetic Model of Synchronous Machines, file e384c42e-2312-d4b2-e053-9f05fe0a1d67
|
921
|
Optimal design of IPM-PMASR motors for wide constant power speed range applications, file e384c42d-f40e-d4b2-e053-9f05fe0a1d67
|
874
|
Position estimation delays in signal injection-based sensorless PMSM drives, file e384c42e-1d5b-d4b2-e053-9f05fe0a1d67
|
808
|
Magnetic Model Self-Identification for PM Synchronous Machine Drives, file e384c42d-e4fe-d4b2-e053-9f05fe0a1d67
|
803
|
Optimal number of rotor parameters for the automatic design of Synchronous Reluctance machines, file e384c42e-388d-d4b2-e053-9f05fe0a1d67
|
777
|
Impact of the motor magnetic model on direct flux vector control of interior PM motors, file e384c42e-2289-d4b2-e053-9f05fe0a1d67
|
746
|
Direct Flux Control of PM synchronous motor drives for traction applications, file e384c42e-388e-d4b2-e053-9f05fe0a1d67
|
724
|
Sensorless direct flux vector control of synchronous reluctance motor drives in a wide speed range including standstill, file e384c42f-3ee3-d4b2-e053-9f05fe0a1d67
|
724
|
Design of Ferrite Assisted Synchronous Reluctance machines robust towards demagnetization, file e384c42e-2ddf-d4b2-e053-9f05fe0a1d67
|
712
|
Multipolar SPM machines for direct drive application: a comprehensive design approach, file e384c42e-1d4a-d4b2-e053-9f05fe0a1d67
|
702
|
Sensorless Direct Flux Vector Control of Synchronous Reluctance Motors Including Standstill, MTPA and Flux Weakening, file e384c42f-69e7-d4b2-e053-9f05fe0a1d67
|
612
|
Two Design Procedures for PM Synchronous Machines for Electric Powertrains, file e384c42f-87fa-d4b2-e053-9f05fe0a1d67
|
565
|
Predictive direct flux vector control of Permanent Magnet Synchronous Motor Drives, file e384c42e-2dde-d4b2-e053-9f05fe0a1d67
|
564
|
Loss Function Modeling of Efficiency Maps of Electrical Machines, file e384c42f-7e0b-d4b2-e053-9f05fe0a1d67
|
560
|
Parameter Identification and Self-Commissioning in AC Motor Drives: a Technology Status Review, file e384c430-3889-d4b2-e053-9f05fe0a1d67
|
560
|
Low cost PM synchronous servo-applications employing asynchronous-motor frame, file e384c42e-8c21-d4b2-e053-9f05fe0a1d67
|
518
|
Synchronous reluctance motor with concentrated windings for IE4 efficiency, file e384c42f-db6b-d4b2-e053-9f05fe0a1d67
|
506
|
High-speed scalability of synchronous reluctance machines considering different lamination materials, file e384c42e-a259-d4b2-e053-9f05fe0a1d67
|
502
|
Barriers shapes and minimum set of rotor parameters in the automated design of Synchronous Reluctance machines, file e384c42e-2af7-d4b2-e053-9f05fe0a1d67
|
497
|
Performance assessment of ferrite- and neodymiumassisted synchronous reluctance machines, file e384c42f-dc9e-d4b2-e053-9f05fe0a1d67
|
483
|
Multipolar SPM machines for direct drive application: a general design approach, file e384c42e-28a1-d4b2-e053-9f05fe0a1d67
|
469
|
Parametric Design Method for SPM Machines Including Rounded PM Shape, file e384c42f-a469-d4b2-e053-9f05fe0a1d67
|
467
|
Design of synchronous reluctance machines with multi-objective optimization algorithms, file e384c42e-2aeb-d4b2-e053-9f05fe0a1d67
|
459
|
Advanced testing of SiC power MOSFET modules for electric motor drives, file e384c42f-dedf-d4b2-e053-9f05fe0a1d67
|
456
|
Plug-in, Direct Flux Vector Control of PM Synchronous Machine Drives, file e384c42e-8bbd-d4b2-e053-9f05fe0a1d67
|
432
|
Integrated battery charger for electric scooter, file e384c42f-d191-d4b2-e053-9f05fe0a1d67
|
431
|
Analysis of overload and sensorless control capability of PM-assisted synchronous reluctance machines, file e384c42f-9274-d4b2-e053-9f05fe0a1d67
|
423
|
FEA-based multi-objective optimization of IPM motor design including rotor losses, file e384c42f-c8c9-d4b2-e053-9f05fe0a1d67
|
422
|
Sensorless Direct Torque Control for PM-Assisted Synchronous Motors With Injection High-Frequency Signal Into Stator Flux Reference Frame, file e384c42f-9dd8-d4b2-e053-9f05fe0a1d67
|
394
|
On-line temperature estimation of SiC power MOSFET modules through on-state resistance mapping, file e384c42f-e86d-d4b2-e053-9f05fe0a1d67
|
391
|
FIELD ORIENTED CONTROL OF IPM DRIVES FOR FLUX WEAKENING APPLICATIONS, file e384c42f-cd52-d4b2-e053-9f05fe0a1d67
|
374
|
Hybrid sensorless control of axial flux permanent magnet motor drives, including zero speed, file e384c42e-37cd-d4b2-e053-9f05fe0a1d67
|
360
|
Sensorless Magnetic Model and PM Flux Identification of Synchronous Drives at Standstill, file e384c42f-94d2-d4b2-e053-9f05fe0a1d67
|
357
|
Vector control of matrix converter-fed synchronous reluctance motor based on flux observer, file e384c42f-c95b-d4b2-e053-9f05fe0a1d67
|
352
|
Combined Active Flux and High Frequency Injection Methods for Sensorless Direct Flux Vector Control of Synchronous Reluctance Machines, file e384c430-44d8-d4b2-e053-9f05fe0a1d67
|
347
|
Sensorless self-commissioning of synchronous reluctance motors at standstill without rotor locking, file e384c42f-683a-d4b2-e053-9f05fe0a1d67
|
346
|
Comparison of flux observers for sensorless control of permanent magnet assisted SynRel motors, file e384c42f-c214-d4b2-e053-9f05fe0a1d67
|
324
|
Sensorless Commissioning of Synchronous Reluctance Machines Augmented with High Frequency Voltage Injection, file e384c42f-9a18-d4b2-e053-9f05fe0a1d67
|
301
|
Design of two PM Synchronous Machines for EV Traction Using Open-Source Design Instruments, file e384c42f-9e4a-d4b2-e053-9f05fe0a1d67
|
298
|
Sensorless standstill commissioning of synchronous reluctance machines with automatic tuning, file e384c42f-9960-d4b2-e053-9f05fe0a1d67
|
295
|
Sensorless Self-Commissioning of Synchronous Reluctance Motors at Standstill, file e384c42f-2c7d-d4b2-e053-9f05fe0a1d67
|
292
|
Magnet shape optimization of surface-mounted permanent magnet synchronous machine through FEA method, file e384c42f-9e4b-d4b2-e053-9f05fe0a1d67
|
291
|
Self-commissioning algorithm for matrix converter, nonlinearity compensation, file e384c42f-cdbe-d4b2-e053-9f05fe0a1d67
|
290
|
Sensorless Control of Matrix Converter-Fed Synchronous Reluctance Motor Drives, file e384c42f-a0a8-d4b2-e053-9f05fe0a1d67
|
282
|
DC-AC Conversion Strategy optimized for Battery or Fuel-Cell-Supplied AC Motor Drives, file e384c42f-cb0a-d4b2-e053-9f05fe0a1d67
|
274
|
Sensorless vector controlled synchronous reluctance motor fed by matrix converter, file e384c42f-cdf4-d4b2-e053-9f05fe0a1d67
|
255
|
On-line Junction Temperature Estimation of SiC Power MOSFETs through On-state Voltage Mapping, file e384c42f-f42f-d4b2-e053-9f05fe0a1d67
|
253
|
Torque Ripple Minimization of PM-assisted Synchronous Reluctance Machines via Asymmetric Rotor Poles, file e384c431-45f9-d4b2-e053-9f05fe0a1d67
|
226
|
Cost-effective Line Termination Net for IGBT PWM VSI AC Motor drives, file e384c42f-cb0d-d4b2-e053-9f05fe0a1d67
|
224
|
A simple design method for surface-mounted PM machines for traction application, file e384c42f-ba45-d4b2-e053-9f05fe0a1d67
|
199
|
Sensorless Control of Matrix Converter-Fed Synchronous Reluctance Motors Based on Direct Flux Vector Control Method, file e384c42f-475c-d4b2-e053-9f05fe0a1d67
|
178
|
Standstill Determination of PM Flux Linkage Based on Minimum Saliency Tracking for PM-SyR Machines, file e384c430-d236-d4b2-e053-9f05fe0a1d67
|
166
|
Flux-Map Based FEA Evaluation of Synchronous Machine Efficiency Maps, file e384c433-4d4c-d4b2-e053-9f05fe0a1d67
|
164
|
Reduction of Torque Ripple in Synchronous Reluctance Machines through Flux Barrier Shift, file e384c430-3c59-d4b2-e053-9f05fe0a1d67
|
155
|
Estimation of PM Machine Efficiency Maps from Limited Experimental Data, file e384c430-85e5-d4b2-e053-9f05fe0a1d67
|
147
|
A direct-drive solution for Hydrogen supplied all-electric airplane, file e384c42f-c9b1-d4b2-e053-9f05fe0a1d67
|
128
|
FEAfix: FEA Refinement of Design Equations for Synchronous Reluctance Machines, file e384c431-70af-d4b2-e053-9f05fe0a1d67
|
110
|
Winding Thermal Modeling and Parameters Identification for Multi-Three Phase Machines Based on Short-Time Transient Tests, file e384c431-a8e9-d4b2-e053-9f05fe0a1d67
|
99
|
Power loss analysis and measurement of a high efficiency DC-DC converter for EV traction AC drives, file e384c42f-c8a7-d4b2-e053-9f05fe0a1d67
|
92
|
Computationally efficient design procedure for single-layer IPM machines, file e384c430-c221-d4b2-e053-9f05fe0a1d67
|
92
|
Transient Overload Characteristics of PM-Assisted Synchronous Reluctance Machines, Including Sensorless Control Feasibility, file e384c430-99a2-d4b2-e053-9f05fe0a1d67
|
91
|
Efficient Multiphysics Design Workflow of Synchronous Reluctance Motors, file e384c432-a46a-d4b2-e053-9f05fe0a1d67
|
87
|
Novel Sensorless Control Algorithm for SyR Machines Based on Low Speed Active Flux, file e384c430-f296-d4b2-e053-9f05fe0a1d67
|
82
|
Sensorless Self-Commissioning of Synchronous Reluctance Machine with Rotor Self-Locking Mechanism, file e384c430-e93b-d4b2-e053-9f05fe0a1d67
|
78
|
FEA-Augmented Design Equations for Synchronous Reluctance Machines, file e384c430-429f-d4b2-e053-9f05fe0a1d67
|
75
|
Commissioning and Sensorless Control of High Power SyR Machine Prototypes, file e384c430-c982-d4b2-e053-9f05fe0a1d67
|
75
|
A new PM-assisted synchronous reluctance machine with a nonconventional fractional slot per pole combination, file e384c430-8d85-d4b2-e053-9f05fe0a1d67
|
74
|
Automatic Tuning for Sensorless Commissioning of Synchronous Reluctance Machines Augmented with High Frequency Voltage Injection, file e384c430-2832-d4b2-e053-9f05fe0a1d67
|
73
|
syreDrive: Automated Sensorless Control Code Generation for Synchronous Reluctance Motor Drives, file e384c433-5791-d4b2-e053-9f05fe0a1d67
|
72
|
Effect of the numbers of slots and barriers on the optimal design of synchronous reluctance machines2014 International Conference on Optimization of Electrical and Electronic Equipment (OPTIM), file e384c430-4f3a-d4b2-e053-9f05fe0a1d67
|
59
|
A New Laboratory for Hands-on Teaching of Electrical Engineering, file e384c430-a8a8-d4b2-e053-9f05fe0a1d67
|
59
|
Coordinated On-line Junction Temperature Estimation and Prognostic of SiC Power Modules, file e384c430-3e01-d4b2-e053-9f05fe0a1d67
|
58
|
Injectionless Sensorless Control of Synchronous Reluctance Machine for Zero to Low Speeds Region, file e384c430-6567-d4b2-e053-9f05fe0a1d67
|
58
|
Totale |
83.096 |