dsim user manual (psim+dsim) - psim software
TRANSCRIPT
User’s Manual
DSIM Technology Co.
Chapter : -1
DSIM User’s ManualVersion 2021a
Release 1
February 2021
Copyright © 2020-2021 DSIM Technology Co.
All rights reserved. No part of this manual may be photocopied or reproduced in any form or by any means without the writtenpermission of DSIM Technology Co.
DisclaimerDSIM Technology Co. (“DSIM Tech”) makes no representation or warranty with respect to the adequacy or accuracy of thisdocumentation or the software which it describes. In no event will DSIM Tech or its direct or indirect suppliers be liable forany damages whatsoever including, but not limited to, direct, indirect, incidental, or consequential damages of any characterincluding, without limitation, loss of business profits, data, business information, or any and all other commercial damages orlosses, or for any damages in excess of the list price for the licence to the software and documentation.
DSIM Technology Co.
Email: [email protected]: powersimtech.com
0 Chapter :
Contents1 General Information
1.1 Introduction 31.2 Modeling Power Electronic Systems in DSIM 3 1.3 Simulating Power Electronic Systems in DSIM 6 1.4 Software/Hardware Requirement 41.5 Installing the Program 6 1.6 Simulating a Circuit 61.7 Simulation Control 7 1.8 Component Parameter Specification and Format 7
2 Elements Supported in DSIM Simulation2.1 DSIM Environment 9 2.2 Creating a Circuit 122.3 File Menu 132.4 Edit Menu 142.5 View Menu 152.6 Subcircuit Menu 15
2.6.1 Creating Subcircuit - In the Main Circuit 172.6.2 Creating Subcircuit - Inside the Subcircuit 172.6.3 Connecting Subcircuit - In the Main Circuit 182.6.4 Other Features of the Subcircuit 19
2.7 Elements Menu 202.8 Simulate Menu 21 2.9 Options Menu 21
2.9.1 Setting Option 222.10 Utilities Menu 242.11 Window Menu 242.12 Help Menu 252.13 Managing the Element Library 25
2.13.1 Creating a Secondary Image 252.13.2 Adding a New Subcircuit Element into the Library 26
3 Waveform Display in SIMVIEW3.1 File Menu 293.2 Edit Menu 29 3.3 View Menu 293.4 Axis Menu 303.5 Screen Menu 33 3.6 Measure Menu 373.7 Analysis Menu 383.8 Label Menu 383.9 Option Menu 393.10 Exporting Data 40
Chapter : 1
4 Examples4.1 Example 1: 200kHz LLC Circuit 41 4.2 Example: 50kVA Solid-State Transformer 15 4.3 Example: 10kV four-port Solid-State Transformer 17 4.4 Example 4: Experimental Verifications of the Transient Model 18
2 Chapter :
1 General Information
1.1 IntroductionDSIM is a simulation engine specifically designed for power electronics. With a ground breaking simulationengine and innovative modeling approach which fully exploits the characteristics of power electronic systems,it achieves an unprecedented and unparalleled performance. It increases the simulation speed by several ordersof magnitude compared with any existing simulation software. Moreover, its ability to simulate large convertersystems and at the same time switch transients is unique, and it makes it ideally suited for large scale powerconverter systems, high power converter systems, microgrid, and any systems that are computation intensive.
The DSIM engine is embedded in the PSIM simulation environment, and shares the same graphic userinterface. The simulation environment consists of the PSIM schematic capture, the DSIM simulation engine,and the waveform processing program SIMVIEW.
This manual covers necessary details about DSIM. The organization of this manual is as follows:
First of all, in Chapter 1, the working principles of DSIM will be briefly introduced, in terms of modeling andsimulating, so that users can have a basic understanding of the DSIM engine.
1.2 Modeling Power Electronic Systems in DSIMPower electronic systems are hybrid dynamic systems composed of continuous states and discrete events.Usually, continuous states include physical variables such as capacitor voltage and inductor current, whilediscrete events, such as switching events of semiconductor switches, lead to the transition from one operatingmode to another. In power electronic systems, these continuous states and discrete events not only coexist, butalso deeply interact with each other and co-determine the operating mode of the system, as shown below.
Power electronic system is represented in DSIM in four blocks: power circuit, control circuit, sensors, andswitch controllers. The figure below shows the relationship between these blocks.
Chapter 1 DSIM circuit structure, software/hardware requirement, and parameter format.
Chapter 2 Elements supported in DSIM simulation.
Chapter 3 Examples showing the performance of DSIM.
Chapter 1: General Information 3
The power circuit usually consists of switching devices, RLC branches and transformers. For the switchingdevices, DSIM do not offer discrete switch elements such as a single diode, IGBT, or MOSFET, to build theconverter. Instead, switch modules such as two-level bridge leg, three-level T-type bridge leg and three-levelNPC bridge leg should be used to construct the circuit. See Elements >> Power >> Switches >> SwitchModules for all the switch modules supported in DSIM. DSIM does support bi-directional switches, but the bi-directional switch should be used for one-time event only (such as load change, open-circuit, or short-circuit). Itshould not be used for PWM operation as the DSIM engine is not optimized to handle it.
For the versions after DSIM 2021a, the single switches are supported for simulation. This feature enables thesimulation of newly-designed topologies and largely increases users’ flexibility of constructing circuits. It needsto be mentioned that the single switches are not suggested for large-scale circuits. If hundreds of switches areused, the advantages of DSIM will be greatly weakened.
For switching modules, two types of model are supported in DSIM, namely ideal model and transient model.
Ideal ModelIf ideal model is selected, DSIM will model the switch as a small resistance in on-state and as open circuit inoff-state. The on-state resistance is defined as a parameter called Switch Resistance. It is considered the samefor all the active switches and the diodes in the module. Note that DSIM dose not support the zero swtichresistance. If the value is set to zero, DSIM will consider it as 1e-4. The forward voltage of diode is notconsidered in DSIM modeling. The off-state resistance is ignored. The transitions between on-state and off-stateare also ignored, so the system can be viewed as a piecewise-linear time-invariant (PLTI) system, which can becharacterized by a set of n first-order ordinary differential equations (ODEs). Taking two-level bridge leg as anexample, the figure below shows how DSIM model the switch module. Please refer to online help of eachmodule to see its legal control input.
Power Circuit
Control Circuit
Sensors Switch Controllers
+
-1 2
+
-1 4
+
-1 4
Two-level bridge leg
Three-level T-type bridge leg
Three-level NPC bridge leg
4 Chapter 1: General Information
Transient ModelSwitching transients between the two steady states are sometimes significant in terms of device protection,switching loss, voltage/current balancing and EMI analysis. However, simulating switching transients in a largesystem is often challenging due to high stiffness of the circuit. DSIM adopts an innovative modeling approachcalled Piecewise Analytical Transient (PAT) model, which is capable of simulating the switching transients ina very fast and stable way. All the model parameters are available from device datasheet.
Taking a two-level bridge leg as an example, the equivalent circuit for IGBT/diode bridge and for SiCMOSFET/diode bridge is shown as below. Note that the stray inductors are already incorporated in the modelwhose values should be entered as parameters. One should not put extra stray components in the main circuitwhich will cause highly stiff equations and therefore low simulation speed.
DSIM now offers transient model for all the switching modules except three-level NPC bridges. One canchoose between IGBT/diode model and SiC MOSFET/diode model. Please turn to online help for moreinformation about the definitions of the model parameters. In Chapter 3 Examples, comparisons of the modelresults and experimental results will be presented.
With the help of transient model, the power loss of switch modules can be evaluated in DSIM since the versionDSIM 2021a. The switch loss calculation is possible by interfacing the temperature and power loss with outsidethermal circuits. Please refer to the corresponding tutorial for detailed information.
The control circuit is represented in block diagram. DSIM supports only digital control temporarily.Components in z-domain, logic gates and computational blocks can be used in the control circuit. Sensors areused to measure power circuit quantities and pass them to the control circuit. Gating signals are then generatedfrom the control circuit and sent back to the power circuit through switch controllers to control switches.
Q1
Ls
RG
VGS
Ls
RG
VGS
Lb/2
SiC MOSFET/diode model
Lb/2
Q2
Q1RG
VGE
Lb/2
Q2RG
VGE
Lb/2
IGBT/diode model
Chapter 1: General Information 5
The whole DSIM engine works in an event-driven manner, and one should use the switch controllers underElements >> Other >> Switch Controllers to generate switching signals. The offered components cover mostof the PWM generators including carrier-based PWM, SVPWM, square wave controller, etc. Otherwise, oneshould be careful in current DSIM version since switching events may not be located accurately.
1.3 Simulating Power Electronic Systems in DSIMDSIM engine uses a discrete state (DS) algorithm under an event-driven (ED) manner. It fully exploits thecharacteristics of power electronic systems and exhibits ultra-fast performance especially in large-scale or high-frequency systems, where typically hundred-fold acceleration can be achieved under the same accuracy,compared with existing simulation tools. Chapter 3 Examples shows some examples where such comparisonsare presented.
The DS algorithm is intrinsically a variable step-size algorithm which achieves adaptive numerical integrationof system states with less computational costs, and the ED manner avoids unnecessary iterative calculations forthe frequently-occurred switching events in power electronics. Since a variable step-size algorithm is employed,it’s not necessary for users to select a proper step-size. Instead, DSIM engine will choose the step-sizeadaptively in each calculation step. The following figure illustrates the DSIM simulation framework comparedwith the conventional one.
1.4 Installing the Program
Some of the files in the DSIM directory are:
File extensions used in DSIM are:
1.5 Simulating a Circuit To simulate the buck converter circuit “buck.dsimsch” in "examples\DSIM\dc-dc":
- Start PSIM. From the File menu, choose Open Examples..., then, go to "DSIM\dc-dc" folder to load
PSIM.exe PSIM circuit schematic editor
SIMVIEW.exe Waveform processing program
*.psimsch schematic file
*.psimpjt project file
*.schpack package file
*.lib library file
*.txt Simulation output file in text format
*.smv Simulation output file in binary format
Conventional simulation framework DSIM simulation framework
6 Chapter 1: General Information
the file “buck.psimsch”.
- From the Simulate menu, choose Run DSIM Simulation to start the simulation. Simulation results will be saved to File “buck.smv”.
- By default, Auto-run SIMVIEW is selected in the Options menu. SIMVIEW will be launched automatically. In SIMVIEW, select curves for display. If this option is not selected, from the Simulate menu, choose Run SIMVIEW to start SIMVIEW.
1.6 Simulation ControlDSIM adopts a variable-step algorithm, and users do not have to specify the simulation step. The SimulationControl element defines parameters and settings related to simulation.
To place the Simulation Control in the schematic, go to the Simulate menu, and select Simulation Control.
Image:
Parameters for the DSED solver
The figure below shows the effect when the Maximum Display Step Size is reduced.
End Time The total simulation time, in sec.
Maximum step size The maximum time step, in sec. If the adaptively chosen time step is larger than the "Maximum step size", the step size is forced to be "Maximum step size".
Relative error "Relative error" is used to control the numerical error in state integration. The engine chooses the step size based on "Relative error". Decreasing it leads to smaller time step, hence more accurate results but longer consuming time. In most cases, at least 1e-3 "Relative error" is recommended. One can also decrease it until no changes are observed in the simulated waveforms.
Maximum display step size
The "Maximum display step size" (in sec.) is used to limit the display step between two points in the output waveforms. This is typically used for high-frequency waveforms when the engine gives accurate results at each point, but with low "sampling frequency" due to relatively large step size, as shown below (red waveform). Decreasing "Maximum display step size" forces the engine to show details between two points (i.e. during each time step), as shown below (blue waveform). This will cause extra calculations but is more efficient than decreasing the "Maximum step size". It is recommended to use larger "Maximum display step size" to save time when simulated waveforms are displayed with enough resolution.
Print time Time from which simulation results are saved to the output file (default = 0). No output is saved before this time.
Absolute Error If the error of calculation is larger than the absolute error, the step size will be reduced for accuracy. If there is an error saying "fail to find stable states", try smaller absolute error for high accuracy.
Absolute Error for zero crossing detection
If the absolute value of a variable is larger than this parameter, it is considered zero. Generally, the default value works well..
Chapter 1: General Information 7
Some tips on how to change simulation settings:
1) Try decrease the "Relative error" if you think the simulation is not accurate enough;
2) Try decrease the "Maximum display step size" if you think the results have low resolution;
3) Try decrease the "Maximum step size" when you find that the simulation results do not converge.
Parameters for the BDSED solver
Some tips on how to change simulation settings:
1) When the system is highly stiff and the simulation parameters are not well chosen, there is a possobility ofdivergence. Try to increase minimum step size for better numerical stability.Try decrease the "Relative error" ifyou think the simulation is not accurate enough;
2) When the efficiency of BDSED solver is not good, try a larger minimum step size, for example, 1e-5.
End Time The total simulation time, in sec.
Maximum step size The maximum time step, in sec. If the adaptively chosen time step is larger than the "Maximum step size", the step size is forced to be "Maximum step size".
Minimum step size The minimum simulation time step size(for reference only), in seconds. This parameter is referred to so as to know the level of time scale that users care. The real step sizes may not all be larger than the minimum step size. If this parameter is increased, the solver is prone to choose larger step, which improves the efficiency but sacrifices the accuracy, and vice versa. This parameters can be adjusted to meet the demand of both accuracy and efficiency. Generally, the default value works well.
Relative error "Relative error" is used to control the numerical error in state integration. The engine chooses the step size based on "Relative error". Decreasing it leads to smaller time step, hence more accurate results but longer consuming time. In most cases, at least 1e-3 "Relative error" is recommended. One can also decrease it until no changes are observed in the simulated waveforms.
Print time Time from which simulation results are saved to the output file (default = 0). No output is saved before this time.
Absolute Error If the error of calculation is larger than the absolute error, the step size will be reduced for accuracy. If there is an error saying "fail to find stable states", try smaller absolute error for high accuracy.
Absolute Error for zero crossing detection
If the absolute value of a variable is larger than this parameter, it is considered zero. Generally, the default value works well..
Red: W aveform w ith larger “M axim um display step size”Blue: W aveform w ith sm aller “M axim um display step size”
8 Chapter 1: General Information
2 Elements Supported in DSIM Simulation
This chapter lists all the elements that are supported in DSIM simulation. Users can choose to display onlyDSIM supported elements in Options >> Settings >> Advanced.
The following elements are supported in DSIM.
Under Elements >> Power:
- RLC branches Resistor Inductor Capacitor Capacitor (Electrolytic) R3 L3 C3 RL3 RC3 RLC3
- Switches- Switch Modules
1-ph Inverter2-level Bridge Leg
Chapter 2: Elements Supported in DSIM Simulation 9
3-level T-Type Bridge Leg3-level NPC Bridge Leg3-ph Inverter3-ph 3-level T-Type Bridge Leg3-ph 3-level NPC BridgeDual Active Bridge (DAB)1-ph Diode Bridge3-ph Diode Bridge
- Bi-directional Switch- 3-ph Bi-directional Switch
- TransformersIdeal Transformer1-ph Transformer1-ph Transformer (no Lm)
- Renewable Energy ModuleSolar Module (physical model)
- Motor DriveSquirrel-cage Ind. Machine (with load) PMSM (with load)
*The above motor drive modules contain the following types of mechanical loads: constant torque, constantspeed, constant power, general.
Under Elements >> Control:
- Computational Blocks Multiplier
DividerSquare-rootSineSine (rad.)Sine (p.u.)ArcsineCosineCosine (rad.)Cosine (p.u.)ArccosineSine/Cosine (rad.)Sine/Cosine (p.u.)TangentArctangentArctangent (p.u.)Arctangent 2 (rad.)Arctangent 2 (p.u.)Exponential (a^x)
10 Chapter 2: Elements Supported in DSIM Simulation
Power (x^a)LOG (base e)LOG10 (base 10)Absolute ValueSign BlockMaximum / Minimum Block
- Other Function Blocks Multiplexer (2-input)
Space Vector PWMSpace Vector PWM (alpha / beta)
- Logic ElementsAND GateAND Gate (3-input)OR GateOR Gate (3-input)XOR GateNOT GateNAND GateNOR Gate
- Digital Control ModuleZero-Order HoldUnit DelayIntegratorDifferentiatorPIz-domain Transfer Function
- Under the Control menu Proportional Comparator Limiter Upper Limiter Lower Limiter Range Limiter Summer (+/-) Summer (+/+) Summer (3-input)
Under Elements >> Other:
- Switch Controllers On-Off Controller
Square Wave Controller (Variable freq.)Carrier PWM Controller (z-domain)Square Wave Controller (z-domain)
Chapter 2: Elements Supported in DSIM Simulation 11
Phase Shift Controller (z-domain)Phase Shift Controller (fixed D) (z-domain)Space Vector PWM (2-level) (z-domain)Space Vector PWM (3-level) (z-domain)
- Sensors Voltage Sensor
Current SensorVoltage Sensor (average)Current Sensor (average)
- Probes Voltage Probe
Current ProbeVoltage Probe (node-to-node)
- Function Blocks abc-dqo Transformation
dqo-abc TransformationClarke Transformation (abc-alpha/beta)Clarke Transformation (ab-alpha/beta)Clarke Transformation (ac-alpha/beta)Inverse Clarke Transformation (alpha/beta-abc)Park Transformation (alpha/beta-dq)Park Transformation (alpha/beta/sin/cos-dq)Inverse Park Transformation (dq-alpha/beta)Inverse Park Transformation (dq/sin/cos- al/be)x/y-r/angle Transformationr/angle-x/y TransformationMath FunctionMath Function (2-input)Math Function (5-input)Math Function (10-input)C BlockSimplified C Block
Under Elements >> Sources:
- Voltage DC
Sine3-ph SineGrounded Source (multiple) (constant, sine, triangular, sawtooth, square, step, step(2-level))
- Under the Sources menu:Constant
Time Ground
12 Chapter 2: Elements Supported in DSIM Simulation
Ground (1) Ground (2)
Chapter 2: Elements Supported in DSIM Simulation 13
3 Examples
The high performance of DSIM and its ability to simulate switching transients makes it an ideal solution forlarge scale power converter systems, high power converter systems, microgrid, and any systems that arecomputation intensive. In this chapter, some examples are described to show how DSIM empowers the designand research of relatively complicated systems.
Example: 200kHz LLC Circuit
LLC circuit usually operates in a high-frequency range. With conventional simulation approach, very smallsimulation time step is needed to get correct results, making the whole simulation time consuming. DSIM offersan event-driven mechanism which greatly shortens the simulation time. This LLC circuit can be found underexamples >> DSIM >> LLC converter (200kHz).The following figure shows the circuit structure. The studied case is a LLC isolated bidirectional DC-DCconverter, with a variable-frequency control around 200kHz. A variable-frequency square wave controller isused to generate the switching signals. Note that for simplicity, the same switching signals are used for bothprimary and secondary side bridges. This is not the case in practice, but just an approximation to show theperformance of DSIM in similar cases.
To use an existing simulation tool with fixed step-size, a very small time step must be selected. A test result isshown in the following figure, where the simulated waveforms of the output DC voltage Vo under different timesteps are shown. It can be observed that any time step larger than 1e-9s is not enough to get correct waveforms.
Vo
400
H(z)
200k
freq
freq
0.5
0S1
S2
S4
S3
V
V
A
QD
freq
delay
Qn
Square Wave
+
-1 2
+
-1 2
+
-12
+
-12
LLC Isolated Bidirectional DC-DC Converter (8 switches, 200kHz)
14 Chapter 3: Examples
With 1e-9s time step, existing tool takes more than 20 minutes for 0.1 second simulation. However, with theDiscrete State Event-Driven algorithm, DSIM takes less than 1 second to get the same results, which is morethan 1300 times faster. The following figure shows the comparisons of the simulated results, where Vo is theoutput DC voltage, and Vcr is the resonant capacitor voltage. The tests are conducted with an Intel Core i7-6600U CPU.
Example: 50kVA Solid-State Transformer
This example shows a 50kVA solid-state transformer (SST). The system consists of three stages, as shown inthe following figure. It is tested under a 5-second grid-side low-voltage ride-through dynamic, where thewaveform of the grid-side voltage is also shown below.
The DSIM circuit of this example is shown below.
0 0.02 0.04 0.06 0.08 0.1Time (s)
380
390
400
410
420
430
Vo (V
)
Discrete step=1e-7sDiscrete step=5e-8sDiscrete step=1e-8s
Discrete step 1e-8sDiscrete step 5e-9sDiscrete step 1e-9s
Existing tool
1218s (20min 18s)
0.879s
×13860 0.005 0.01 0.015 0.02 0.025 0.03 0.035390
400
410
420
Vo (V
)
0 0.005 0.01 0.015 0.02 0.025 0.03 0.035Time (s)
390
400
410
420
Vo (V
)
0 0.5 1 1.510-4
-1000
0
1000
2000
Vcr
(V)
0 0.5 1 1.5Time (s) 10-4
-1000
0
1000
2000
Vcr
(V)
Existing tool with time step 1e-9s
DSIM
Existing tool with time step 1e-9s
DSIM
Overall circuit of the 50kVA SST and simulated low-voltage ride-through dynamic
Chapter 3: Examples 15
For the 5-second dynamic, if ideal switch model is used, DSIM takes less than 5 second to finish the simulation,which is about 50 times faster than current software; if transient switch model is used, DSIM takes about 50seconds, which is 700 times faster than another commercial software. The comparisons are shown as below.The tests are conducted with an Intel Core i7-7700K CPU.
The simulated results are in good agreements with experimental results. Some comparisons of the grid-sidewaveforms and the DC-link voltage are shown below.
The PAT model in DSIM also gives good results compared with measured ones, as shown below.
0.003 0.100
00.1e-3 9
34010e-3
10e-3300
10e-3300
1000
0.001
0.001
0.00190
50
20*sqrt(3)
sa1
sa2
sa3
sa4
sb1
sb2
sb3
sb4
sc1
sc2
sc3
sc4
ds11
ds12
ds14
ds21
ds23
ds22
ds24
s1
s2
s3
s4
ds13
50kVA Solid-State Transformer
Three-level T-Type module4kHz
DAB module20 kHz
Inverter module8kHz
+
-1 4 3 2
+ +
- -11 14 21 24
+
-sa1sb1sc1
a
b
c
Tool Device Model Solver CPU Time (s)
Software A IGBT/PiN diode: igbt_b and dp1SiC MOSFET/SiC SBD : mp1 and dp1
Trapezoidal method and Newton-Raphson iteration
33712.0(9h 21min 52s)
Software B Ideal switch model Ode23tb (Rapid mode) 250.9DSIM Transient model (PAT) DSED 47.0DSIM Ideal model DSED 4.82
×717.3×51.8
(a) grid-side voltage (b) grid-side current (c) high-voltage side DC-link voltage (d) low-voltage side DC-link voltage
16 Chapter 3: Examples
Example: 10kV four-port Solid-State Transformer
This example shows how DSIM helps to simulate a very large system: a four-port solid-state transformer (SST),also known as electric energy router (EER). It consists of 576 switches in total and the rated power for each portis 1MW. The system diagram and the circuit built in DSIM is shown below.
To simulate a 0.2s dynamic, DSIM takes only 17 seconds, which is more than 1000 times faster than acommercial software specialized in power electronics, while the simulated results are very close, with less than0.01% relative error, as shown below. DSED represents the DSIM algorithm.
IGBT SiC MOSFET
iaLA
ibLA
icLA
ucn
ubn
uan
uaniaLA
Sa1
Sa2ubnibLA
Sb1
Sb2 ucnicLA
Sc1
Sc2
0Sn1Sn2
V
PWM
Qz
Vcr
Qn
+
-12
+
-12
+
-12
+
-12
10kV/2MW Electric Energy Router
HVAC
HVDC
LVDCLVAC
三相10kV交流电网
~ ~ ~
10kV直流端口
±375V直流端口
380V交流端口
~
~
~
+
-
+ -
Structure of the EER
Three-phase 10kVAC grid
10kV DC port
380VAC port
±375VDC port
Tool Configurations Number ofCalculated Points Relative Error CPU Time (s)
Software CVariable-step methodMax step-size 1e-3
Absolute tolerance 1e-4196061
Grid-side Current: 1.3e-5LVDC Transformer Current: 8.4e-5
22328(6h 12min 8s)
DSIMDSED method
Max step-size 1e-3Relative tolerance 1e-3
Grid-side Current: 7.0e-6LVDC Transformer Current: 4.7e-5 17.7101874
×1261
Simulated results comparisons of HVAC phase A grid-side current
Simulated results comparisons of LVDC output voltage
Simulated results comparisons of HVDC module 1 transformer current
-60
0
60
0.00 0.05 0.10 0.15 0.20-60
0
60
0.10010 0.10015 0.10020-44
0
44
DSED
i HD1/A
Commercial software A
t/s
i HD1/A
DSED Commercial software A
372
374
376
0.00 0.05 0.10 0.15 0.20372
374
376
0.13390 0.13395 0.13400
374.25
375.00
DSEDu LD1
/V
Commercial software A
t/s
u LD1
/V
DSED Commercial software A
-50
0
50
0.0 0.1 0.2-50
0
50
0.13390 0.13395 0.13400-48
-45
DSED
i ga/A
Commercial software A
t/s
i ga/A
DSED Commercial software AC
C
C
C
C C
Chapter 3: Examples 17
Example 4: Experimental Verifications of the Transient Model
This example shows the experimental verifications of the PAT model in DSIM. Double pulse tests areconducted on Infineon IGBT FZ600R65KF1 (6500V, 600A). Some experimental results are shown as below.
Generally PAT model gives good results compared with experimental waveforms, if the input parameters areaccurate enough. Under some small-current conditions, the model error can be larger.
0 1 2 3 4 5 6t/ s
0
500
1000
1500i c/A
Simulation result for icSimulation result for vceExperimental result for icExperimental result for vce
0
1000
2000
3000
v ce/V
0
1000
2000
3000
v ce/V
Switching-on signal
3000V,390A
2500V,220A
icmax Error3.88%
1.66%3.38%*1
7.44%*2
Eon Error 4.67%
Eon Error 13.20%
tr Error
*1 3000V,390A*2 2500V,220A
0 1 2 3 4 5 6t/ s
0
500
1000
1500
i c/A
Simulation result for icSimulation result for vceExperimental result for icExperimental result for vce
0
1000
2000
3000
v ce/V
0
1000
2000
3000
v ce/V
Switching-on signal
3000V,270A
2500V,190A
icmax Error 0.99%1.65%
tr Error19.21%*1
17.32%*2
Eon Error 13.46%
Eon Error 13.37%
*1 3000V,270A*2 2500V,190A
0 2 4 6 8t/ s
0
250
500
750
1000
i c/A
Simulation result for icSimulation result for vceExperimental result for icExperimental result for vce
0
1000
2000
3000
4000
5000
v ce/V
0
1000
2000
3000
4000
5000
v ce/V
Switching-off signal
3000V,475A
2000V,305A
vcemax Error
tf Error 6.05%
21.74%
Eoff Error 0.65%
Eoff Error 16.14%
0.28%
0.92%vcemax Error
tf Error
0 2 4 6 8t/ s
0
250
500
750
1000
i c/A
Simulation result for icSimulation result for vceExperimental result for icExperimental result for vce
0
1000
2000
3000
4000
5000
v ce/V
0
1000
2000
3000
4000
5000
v ce/V
Switching-off signal
3000V,300A
2000V,192A
vcemax Error 3.44%
vcemax Error 4.01%Eoff Error 18.90%
Eoff Error 27.98%
tf Error
33.52%tf Error
22.72%
18 Chapter 3: Examples