Work. Pt  Sine wave  Generator  I PSI N
1. Positioning and objective
The aim of the test “ Working point – Sine wave – Generator – I, Ψ, N” is to characterize the behavior of the machine when operating at the targeted input values I, Ψ, N (Magnitude of current, Control angle, Speed).
These three inputs are enough to impose a precise working point.

“Working point – Sine wave – Generator – I, Ψ, N ” illustration 
The results of this test give an overview of the electromagnetic analysis of the machine considering its topology.
The general data of the machine, like machine constants and power balance are computed and displayed. The generator convention is used to build the model.
The magnetic flux density is also computed in every region of the machine magnetic circuit to evaluate the design.
When both the following conditions are met this test allows performing electromagnetic computations with coupled thermal analysis.:
 The type of machine is Reluctance Synchronous Machine with Inner rotor
 One of the two following thermal solving modes is selected: One iteration or iterative solving mode.
Two computation modes are available:
 “Fast computation mode” is perfectly suited for the predesign step (Hybrid model based on MagnetoStatic Finite Element computations and Park transformation theory)
 “Accurate computation mode” is perfectly suited for the final design step (Pure Finite Element modeling based on transient computations)
It also gives the capability to make comparisons between the results obtained from measurements and those evaluated withour software.
The following table helps to classify the test “Working point – Sine wave – Generator – I, Ψ, N”.
Family  Working point 
Package  Sine wave 
Convention  Generator 
Test  I, Ψ, N 
Positioning of the test “Working point – Sine wave – Generator – I, Ψ, N” 
2. User inputs
The three main user input parameters are the supply line current, control angle and speed. In addition, temperatures of winding must be set.
3. Main outputs
Test results are illustrated with data, graphs, and tables
3.1 Tables of results

Machine performance – Base speed point
 General data
 Machine constants
 Power balance
 Flux in airgap
 Flux density in iron

Power electronics
 Inverter
 Working point

Inductances
 Working point
 DQ model representation

Ripple mechanical torque
 Working point

Thermal data
 Table of temperatures
3.2 Curves – in the “Fast computation modes”
 Ripple mechanical torque versus rotor angular position
 Flux density in airgap versus rotor angular position
 Chart of temperature (radial and axial views)
3.3 Curves – in the “Accurate computation modes”
 Mechanical torque versus rotor angular position
 Mechanical torque harmonic analysis
 Flux density in airgap versus rotor angular position
 Flux density in airgap harmonic analysis
 Phase voltage versus rotor angular position
 Phase voltage harmonic analysis
 Phase current versus rotor angular position
 Phase current harmonic analysis
3.4 Graphics
 Isovalues
3.5 Temperatures
 Chart of temperature (radial and axial views)

Thermal data
 Table of temperatures