JMAG-RT
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Agile Electrical Machine Development for Hybrid Electric Aircraft
Zoltán Nádudvari, Rolls-Royce Electric Hungary Kft
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Electric Noise in Cars from Inverter Current to Noise
Mehdi Mehrgou, AVL List Gmbh.
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Analysis of Magnet Clutch Motion Considering Rotation and Translation of Mover
Yuki Kurokawa, Marelli Corporation
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[L-MU-110] Reaching Steady-State at an Early Stage Using a Control Circuit Containing a JMAG-RT Model
Many motor performance evaluations are performed at steady-state. If transients occur during control/circuit coupling, it is necessary to calculate the number of electrical angle …
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[JAC255] Evaluating the N-T Curve of an IPM motor Using 3D Correction
In this example, obtains N-T curves using the correction function.
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[W-MO-85] Efficiency Map Evaluations Considering Harmonic Loss
In this paper, we propose a method that combines two approaches to calculate the efficiency at various operating points considering the influence of time harmonics and other effec…
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[W-MB-64] Modeling Loss in JMAG-RT
In this paper, we explain how loss is modeled in a JMAG-RT model.
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JMAG-RT Case Studies Using 3D Analysis
Natsumi Tamura, Mitsuba Corporation
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Electromagnetic Force Analysis of Permanent Magnet Synchronous Motor Driven by PWM Inverter
Katsuhiro Hoshino, Hitachi Automotive Systems, Ltd.
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[JFT059] How to Account for Harmonic Current (JMAG-RT)
This document explains how to use harmonic current waveforms in magnetic field analyses when obtained from running circuit simulation using plant models (JMAG-RT models).
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[L-MB-33]Supporting Motor Drive Development with a JMAG-MATLAB/Simulink Coupling
Together with Mathworks, the company that develops MATLAB/Simulink (hereafter referred to as "Simulink"), JMAG strongly supports model-based development (hereafter referred to as …
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[L-MB-28] The Incorporation of JMAG into Model Based Design
The JMAG-provided plant model (JMAG-RT) simulates the characteristics of an actual machine with high-fidelity information, acquired by means of FEA, and realizes a highly reliable…
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[RTML-001] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 54(mm) | Height: 51(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(Vshaped) | Average torque: 3.6(N·m)
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[RTML-002] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 54(mm) | Height: 54(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(flat) | Average torque: 3.6(N·m)
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[RTML-003] PMSM/SPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 53(mm) | Height: 36(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: SPM | Average torque: 3.6(N·m)
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[RTML-004] PMSM/IPM Constant rating 1(kW) 3-phase
Type: PMSM | Max Power: 1(kW) | Stator(Outside Diameter): 54(mm) | Height: 77(mm) | Voltage/Current: DC100(V)/20(A) | Rotor/Mover: IPM(Vshaped) | Average torque: 3.6(N·m)
