TUTORIAL Motor Parameter Identification with PSIM Tutorials/Motor...Motor Parameter Identification...
Transcript of TUTORIAL Motor Parameter Identification with PSIM Tutorials/Motor...Motor Parameter Identification...
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TUTORIAL
Motor Parameter Identification with PSIMFebruary 2017
Motor Parameter Identification with PSIM
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PSIM provides the motor identification capability for PMSM motors. It provides a set of code for TI DRV8305 EVM, DRV8312 EVM, and high‐voltage hardware kit. With small changes, users can adopt the code to their own motor drive inverter hardware.
With this capability, PSIM provides the easiest way for users to identify motor parameters first and then evaluate the performance of a sensorless motor control algorithm with InstaSPIN (See the tutorial “Simulation and Code Generation of TI InstaSPIN Using DRV8305 EVM.pdf” for more details).
The core of the InstaSPIN algorithm is a FAST estimator that performs parameter identifications and calculates flux, angle, speed, and torque based on motor phase voltages and currents and dc bus voltage. The FAST block is illustrated below.
Motor identification is a feature of InstaSPIN that allows identification of parameters for sensorless control. This feature enables users to run their motor to its highest performance even when motor parameters are unknown. A side benefit of the InstaSPIN motor identification is that it also provides controller design of inner current loop and outer speed loop PI controllers, and with these controller parameters, the motor drive system is ready to run.
The code provided in PSIM is largely based on TI’s Motorware InstaSPIN Lab2a. The difference is that, in PSIM’s code, parameters needed for motor identification and InstaSPIN are conveniently grouped in a parameter file, and the parameter file can be easily recreated and updated using PSIM’s InstaSPIN Parameter Editor (under the Utilities menu). This makes it easier to adopt the code for different operating conditions or power converter hardware.
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When using the code for different hardware, one should compare the control hardware with the control hardware of the sample code in terms of the DSP peripherals (for example, ADC and PWM channels). If the DSP peripherals are used in the same way, no change is needed to the code, and one needs to update the parameter file only. If DSP peripherals are configured differently, the code needs to be changed to match the control hardware.
Note that, at the moment, the code is for parameter identification is for surface‐mounted PMSM (SPM) only (where Ld = Lq). It is not for internal PMSM (IPM) (where Ld and Lq are different) or any other types of motors.
The following motor identification examples and code are provided in PSIM:
‐ “examples\Motor Identification\TI DRV8305”: For TI DRV8305 EVM ‐ “examples\Motor Identification\TI DRV8312”: For TI DRV8312 EVM ‐ “examples\Motor Identification\TI High‐Voltage Kit”: For TI high‐voltage kit
For further information on TI DRV8305, DRV8312, and High‐Voltage Kit, please refer to relevant TI documents.
This tutorial describes how to use PSIM’s InstaSPIN Parameter Editor and the motor identification code and examples to obtain motor parameters with the DRV8305 EVM hardware. The procedure for other hardware is similar. In this tutorial, the DRV8305 example files are copied to a new folder “C:\New folder\PSIM Project\InstaSPIN\Drv8305InstaSpinMotorID”.
1. Preparing for Motor Identification
There are four steps to identify motor parameters with PSIM and motor drive hardware.
‐ Collect motor drive inverter hardware information. The following parameters are needed:
‐ Current sensor gain ‐ Voltage sensor gain ‐ Voltage sensor filter cut‐off frequency ‐ ADC configuration ‐ PWM configuration
‐ Enter the current and voltage sensor information into PSIM’s InstaSPIN Parameter Editor and generate the parameter file “InstaSPIN_params_MotorID.h” for motor identification. Note that this file name is hard coded and cannot be changed.
‐ From TI CCS, load and run the motor identification code from the example folder.
‐ Once motor parameters are determined from the step above, record the following parameters into a text file “Motor_ID_Parameter.txt” for later use:
Motor parameters:
‐ gMotorVars.Flux_VpHz: Motor rated flux ‐ gMotorVars.Rs_Ohm: Motor stator resistance ‐ gMotorVars.Lsd_H: Motor d‐axis inductance ‐ gMotorVars.Lsq_H: Motor q‐axis inductance
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Voltage/current sensing offsets:
‐ gMotorVars.I_bias_value[0]: Current A sensing offset ‐ gMotorVars.I_bias_value[1]: Current B sensing offset ‐ gMotorVars.I_bias_value[2]: Current C sensing offset ‐ gMotorVars.V_bias_value[0]: Voltage A sensing offset ‐ gMotorVars.V_bias_value[1]: Voltage B sensing offset ‐ gMotorVars.V_bias_value[2]: Voltage C sensing offset
PI Controller parameters:
‐ gMotorVars.Kp_Idq: Current loop proportional gain ‐ gMotorVars.Kp_spd: Current loop integral gain
There are many parameters that need to be defined and calculated for motor identification with InstaSPIN, based on inverter operating conditions and how voltages and currents are sensed. To ease the process of preparing the parameter file, PSIM provides a tool called InstaSPIN Parameter Editor to help users quickly generate the required “InstaSPIN_params_MotorID.h” file.
To generate the InstaSPIN parameter file “InstaSPIN_params_MotorID.h” for motor identification, in PSIM, go to Utilities >> InstaSPIN Parameter Editor. The dialog window is shown below. For more information on how to use the Parameter Editor, click on the Help button.
The entry of the InstaSPIN Parameter Editor can be saved to a text file for later use. Sample files are provided in the “examples\SimCoder\F2806x Target” folder for the following hardware setup:
‐ “InstaSpinMotorID_DRV8305” for TI DRV8305 EVM ‐ “InstaSpinMotorID_DRV8312” for TI DRV8312 EVM ‐ “InstaSpinMotorID_HVKit” for TI high‐voltage PFC and Motor Control Kit
To create the parameter file from an entry saved previously, click on the Load button and load the file into the InstaSPIN Parameter Editor. Then check the “Motor Identification” box, and click on the Generate button.
The dialog window below shows the entry for the motor identification with TI DRV8305 EVM. The dialog window is divided into several sections, and they are explained below.
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For the Motor section:
This section defines the motor type and motor parameters. Two types of motors can be defined: BLDC/PMSM (including IPM and SPM), and induction motor. But for motor identification, only BLDC/PMSM can be selected. For the PMSM motor identification with DRV8305 EVM, the following parameters are defined:
BLDC/PMSM box checked Back emf Cofficient Ke: disabled (need to identify) Stator Resistance Rs: disabled (need to identify) d‐axis Inductance Ls_d: disabled (need to identify) q‐axis Inductance Ls_q: disabled (need to identify) Number of Poles: 8
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Motor Max. Current 5A Motor Max. RPM: 11000 rpm
For the Inverter section:
This section defines the maximum dc bus voltage that can occur during the operation and inverter PWM switching frequency. For DRV8305 EVM, the following are defined:
DC Bus Voltage: 24 V Switching Frequency (kHz): 15 kHz
For the DC Voltage Sensing section:
This section defines how the dc bus voltage is sensed. There are two ways to sense the voltage: either Voltage Divider or User Defined. With Voltage Divider, divider resistances need to be specified. With User Defined, the dc sensing gain is defined directly. For DRV8305 EVM, it uses a voltage divider, and based on the DRV8305 EVM schematic, the resistances are:
Divider box checked Resistance R1: 62k Ohm Resistance R2: 4.99k Ohm
For the AC Voltage Sensing section:
This section defines how ac voltages are sensed. There are two ways to sense the voltage: either RC Circuit or User Defined. With RC Circuit, resistances R1 and R2 and capacitance C1 need to be specified. With User Defined, the ac voltage sensing filter cut‐off frequency is defined directly. For DRV8305 EVM, it uses a RC circuit, and based on the DRV8305 EVM schematic, the values are:
RC Circuit box checked Resistance R1: 62k Ohm Resistance R2: 4.99k Ohm Capacitance C1: 0.1u F
For the AC Current Sensing section:
This section defines how ac currents are sensed. There are three choices: either User Defined, or DRV8305 EVM, or DRV8312 EVM.
For User Defined, the shunt resistance and current gain are defined. Note that when the shunt resistance is not 0, it is assumed that the current is measured through the shunt resistance, and the overall gain is equal to the shunt resistance multiplied by the current gain entered. If the shunt resistance is 0, it is assumed that the current is measured through a hall effect sensor, and the overall gain is the same as the current gain entered.
For DRV8305 EVM, the op. amp. circuit that it uses is fixed, but the reference can be changed through the Reference Divider k, and the gain can be changed through the resistance Rgain. Both can be set through SPI commands.
For DRV8312 EVM, the op. amp. Circuit that it uses is fixed, and the and the current gain is 19.1.
For this example, we will use the default settings of the DRV8305 EVM. Based on the DRV8305 EVM schematic, the values are:
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DRV8305 EVM box checked Reference Divider k: 2 Resistance Rgain: 50k Ohm
For the DSP Control section:
This section defines the parameters related to DSP and InstaSPIN settings. The following parameters are defined:
DSP Frequency (MHz): 90 MHz No. of PWM Periods Per Interrupt: 1 Ratio of InstaSPIN vs. ISR Rate: 1 Ratio of InstaSPIN vs. Current Loop Rate: 1 Ratio of InstaSPIN vs. Estimator Rate: 1
For more information on the parameter definition, refer to the Help page.
For the InstaSPIN Parameters section:
This section defines InstaSPIN parameters that can be set directly. They are used for motor identification. For this example, the parameters are defined as:
USER_MAX_VS_MAG_PU: 0.5 USER_R_OVER_L_EST_FREQ_Hz 300 USER_MOTOR_RES_EST_CURRENT 1.0 USER_MOTOR_IND_EST_CURRENT ‐1.0 USER_MOTOR_FLUX_EST_FREQ_Hz 20 USER_MAX_ACCEL_EST_Hzps 2
For more information on the parameter definition, refer to the Help page.
Once above data are entered into their respective fields, click on the Save button to save the data to a text file for later retrieval using the Load button. To generate the InstaSPIN parameter file for PSIM, click on the Generate button and save the file “InstaSPIN_params_MotorID.h” to the same location as the rest of the code, as shown below.
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The generated InstaSPIN parameter file is shown below. For easy inspection, the parameters are divided into 4 sections: commonly changed parameters, rarely changed parameters, constants, and derived parameters.
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// InstaSPIN Parameters for Motor Identification // Commonly changed //‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐ #define USER_PWM_FREQ_kHz 15.0 // User defined #define USER_NUM_PWM_TICKS_PER_ISR_TICK 1 // User defined #define USER_MOTOR_TYPE 1 // Motor dependent #define USER_MOTOR_NUM_POLE_PAIRS 4 // Motor dependent #define USER_MOTOR_RATED_FLUX 0.0 // Motor dependent #define USER_MOTOR_Rr 0.0 // Motor dependent #define USER_MOTOR_Rs 0.0 // Motor dependent #define USER_MOTOR_Ls_d 0.0 // Motor dependent #define USER_MOTOR_Ls_q 0.0 // Motor dependent #define USER_MOTOR_MAX_CURRENT 5.0 // Motor dependent #define USER_MOTOR_RES_EST_CURRENT 0.5 // Motor dependent #define USER_MOTOR_IND_EST_CURRENT ‐0.5 // Motor dependent #define USER_MOTOR_MAGNETIZING_CURRENT 0.0 // Motor dependent #define USER_MOTOR_FLUX_EST_FREQ_Hz 20.0 // Motor dependent //‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐ // Rarely changed //‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐ #define USER_IQ_FULL_SCALE_CURRENT_A 24.0 // Hardware dependent #define USER_IQ_FULL_SCALE_VOLTAGE_V 24.0 // Hardware dependent #define USER_MAX_ACCEL_EST_Hzps 2.0 // Hardware dependent #define USER_ADC_FULL_SCALE_VOLTAGE_V 44.302 // Hardware dependent #define USER_ADC_FULL_SCALE_CURRENT_A 47.1429 // Hardware dependent #define USER_VOLTAGE_FILTER_POLE_Hz 344.618 // Hardware dependent #define USER_NUM_ISR_TICKS_PER_CTRL_TICK 1 // User defined #define USER_NUM_CTRL_TICKS_PER_CURRENT_TICK 1 // User defined #define USER_NUM_CTRL_TICKS_PER_EST_TICK 1 // User defined #define USER_NUM_CTRL_TICKS_PER_SPEED_TICK 15 // User defined #define USER_NUM_CTRL_TICKS_PER_TRAJ_TICK 15 // User defined #define USER_SYSTEM_FREQ_MHz 90.0 // DSP dependent #define USER_NUM_CURRENT_SENSORS 3 // Hardware dependent #define USER_NUM_VOLTAGE_SENSORS 3 // Hardware dependent #define USER_IQ_FULL_SCALE_FREQ_Hz 806.667 // Motor dependent #define USER_IDRATED_DELTA 0.00002 // Hardware dependent #define USER_R_OVER_L_EST_FREQ_Hz 100.0 // Motor dependent //‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐ // Constants //‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐ #ifndef MATH_PI #define MATH_PI 3.1415926535897932384626433832795 #endif #define USER_OFFSET_POLE_rps 20.0 #define USER_FLUX_POLE_rps 100.0 #define USER_MAX_ACCEL_Hzps 20.0 #define USER_MAX_VS_MAG_PU 0.5 #define USER_DIRECTION_POLE_rps 6.0 #define USER_SPEED_POLE_rps 100 #define USER_DCBUS_POLE_rps 100 #define USER_FLUX_FRACTION 1.0 #define USER_SPEEDMAX_FRACTION_FOR_L_IDENT 1.0 #define USER_POWERWARP_GAIN 1.0 #define USER_EST_KAPPAQ 1.5 #define USER_IDRATED_FRACTION_FOR_L_IDENT 1.0 #define USER_IDRATED_FRACTION_FOR_RATED_FLUX 1.0 //‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐ // Derived variables //‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐‐ #define USER_ZEROSPEEDLIMIT (0.5 / USER_IQ_FULL_SCALE_FREQ_Hz) #define USER_FORCE_ANGLE_FREQ_Hz (2.0 * USER_ZEROSPEEDLIMIT * USER_IQ_FULL_SCALE_FREQ_Hz) #define USER_PWM_PERIOD_usec (1000.0/USER_PWM_FREQ_kHz) #define USER_VOLTAGE_SF (USER_ADC_FULL_SCALE_VOLTAGE_V/USER_IQ_FULL_SCALE_VOLTAGE_V) #define USER_CURRENT_SF (USER_ADC_FULL_SCALE_CURRENT_A/USER_IQ_FULL_SCALE_CURRENT_A) #define USER_VOLTAGE_FILTER_POLE_rps (2.0 * MATH_PI * USER_VOLTAGE_FILTER_POLE_Hz) #define USER_ISR_FREQ_Hz (USER_PWM_FREQ_kHz * 1000.0 / USER_NUM_PWM_TICKS_PER_ISR_TICK) #define USER_CTRL_FREQ_Hz (USER_ISR_FREQ_Hz/USER_NUM_ISR_TICKS_PER_CTRL_TICK) #define USER_TRAJ_FREQ_Hz (USER_CTRL_FREQ_Hz/USER_NUM_CTRL_TICKS_PER_TRAJ_TICK) #define USER_EST_FREQ_Hz (USER_CTRL_FREQ_Hz/USER_NUM_CTRL_TICKS_PER_EST_TICK) #define USER_MAX_CURRENT_SLOPE (USER_MOTOR_RES_EST_CURRENT/USER_IQ_FULL_SCALE_CURRENT_A/USER_TRAJ_FREQ_Hz) #define USER_MAX_CURRENT_SLOPE_POWERWARP (0.3*USER_MOTOR_RES_EST_CURRENT/USER_IQ_FULL_SCALE_CURRENT_A/USER_TRAJ_FREQ_Hz) #define USER_ISR_PERIOD_usec (USER_PWM_PERIOD_usec * USER_NUM_PWM_TICKS_PER_ISR_TICK) #define USER_CTRL_PERIOD_usec (USER_ISR_PERIOD_usec * USER_NUM_ISR_TICKS_PER_CTRL_TICK) #define USER_CTRL_PERIOD_sec (USER_CTRL_PERIOD_usec/1000000.0) #define USER_MAX_NEGATIVE_ID_REF_CURRENT_A (‐0.5 * USER_MOTOR_MAX_CURRENT)
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2. Running Motor Identification Code in CCS
TI Code Composer Studio v6.1 is used to show how to load and run the motor identification code.
2.1 Importing the Motor Identification Project into CCS
Launch CCS v6.1. Go to Project >> Import CCS projects. The dialog window is shown below. Click on Browse… to go to “C:\New folder\Psim Project\InstaSPIN\Drv8305InstaSpinMotorID” and check the “DRV8305MotorID” project. Then click on Finish to start importing.
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The CCS Project Explorer will appear as shown below.
2.2 CCS Target Configuration
Before loading the code to the DRV8305 EVM, we need to create a target configuration for the DSP. Select View >> Target Configurations. Right click on “User Defined” in the Target Configuration dialog. A dialog window will appear as shown below.
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Select New Target Configuration in the pop‐up menu. A dialog will appear as shown below.
Change the file name to F28069.ccxml, then click on Finish. A dialog named “F28069.ccxml” will appear as shown in the figure below. In the “Connection” box, choose “Texas Instruments XDS100v2 USB Debug Probe” or a choice that matches your hardware, then check “TMS320F28069” in the list box of “Board or Device”. Click on Save to save the configuration.
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Back to the “Target Configurations” dialog, right click on the “F28069.ccxml” configuration, and select “Set as Default” as shown in figure below.
2.3 Compiling the Motor Identification Project
To compile the project, right click on the project name “Drv8305MotorID” in the Project Explorer, and then click on Build Project in the menu. Or click on the project name in the Project Explorer to select it as the current project (the project name changes to bold). Select Project >> Build to build the project or Project >> Rebuild All to rebuild the whole project. After the compiling is complete, CCS will display the following messages in figure below:
When the output file “Drv8305MotorID.out” is generated, it is ready to be loaded onto DSP.
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2.4 Hardware Setup for Motor Identification
Before running the generated code on the DRV8305 EVM board, one has to set up the DRV8305 EVM and F28069M LaunchPad according to the following procedure:
‐ Set the LaunchPad jumper and DPI switch positions as:
Jumpers: JP1 = off, JP2 = off, JP3 = on, JP4 = on, JP5 = on, JP6 = off, and JP7 = on DIP switch S1: S1_1 = on, S1_2 = on, and S1_3=on
‐ Connect the DRV8305 board to connectors J1‐2‐3‐4 of the LaunchPad, with the DRV8305 board on top of the LaunchPad. Note that the LaunchPad has two sets of connectors, J1‐2‐3‐4 and J5‐6‐7‐8, that can be connected to the DRV8305 EVM board, and the PSIM example provided is for connectors J1‐2‐3‐4. Make sure that the power and motor connection terminals of the DRV8305 board is on the same side as the USB connector of the LaunchPad. The image below shows how the DRV8305 EVM board is connected with the F28069F LaunchPad.
‐ Connect the motor to the J4 connector of the DRV8305 EVM board (MOTA = black, MOTB = red, and MOTC = yellow).
‐ Connect the LaunchPad USB connector CON1 to the computer USB port.
‐ Connect a 24‐V dc power supply to the J3 connector (PVDD and GND) of the DRV8305 EVM board.
DRV8305 EVM
LaunchPad
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2.5 Running the Motor Identification Program on DRV8305 EVM
To load the program into DSP, click on the project “Drv8305MotorID” to set it as the current
project (the current project name will appear in bold). Then select Run >> Debug to connect the
computer to the DSP. If the connection is successful, the program will be uploaded to the DSP, and
the F28069 DSP will automatically reset and run to the start place of the main function as shown
below.
Start of program
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To run the DSP program in CCS, click on “Enable Silicon Real‐time Mode” to enable the real‐time mode, then click on “Resume” on the toolbar as shown below.
If the Scripting Console is not displayed in CCS, go to View >> Scripting Console to display the Scripting Console window. In the Scripting Console window, click on the “Open file” icon, and load and run the script file “MotorID.js” as shown below.
Enable Silicon Real‐time Mode
Script file
Project folder
Open file
Resume
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After the script runs, a list of motor identification variables will be displayed in the CCS watch window as shown below.
Click on the “Continuous Refresh” icon. Set the values of the flags gMotorVars.Flag_enableSys and gMotorVars.Flag_Run_Identify to 1 as shown below.
Continuous Refresh
Enable Flags
Controller & Estimator States
Motor identification variables
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Then the motor identification process will start. During the motor identification process, monitor the controller state gMotorVars.CtrlState and the estimator state gMotorVars.EstState . They will change from one state to another in the following way:
gMotorVars.CtrlState: CTRL_State_Idle ‐> CTRL_State_OnLine gMotorVars.EstState: EST_State_Idle ‐> EST_State_RoverL ‐> EST_State_Rs ‐>
EST_State_RampUp ‐> EST_State_RatedFlux ‐> EST_State_Ls ‐> EST_State_RampDown ‐> EST_State_Idle
The complete process will last around 90 seconds.
3. Obtaining Motor and Other Parameters
Once the motor parameter identification process is completed, one can obtain the motor parameters, hardware offset parameters, and control loop PID parameters from CCS’s watch window as shown below.
Motor Parameters:
Motor parameters obtained from CCS are: gMotorVars.Rs_Ohm = 0.3814004 gMotorVars.Lsd_H = 0.0006486884
Motor Parameters
Hardware Offsets
Controller Parameters
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gMotorVars.Lsq_H = 0.0006486884 gMotorVars.Flux_VpHz = 0.03385419
Voltage/Current Offset Parameters:
Voltage/current offset parameters obtained from CCS are: gMotorVars.I_bias.value[0] = 1.000818074 gMotorVars.I_bias.value[1] = 1.001404524 gMotorVars.I_bias.value[2] = 1.001073182 gMotorVars.V_bias.value[0] = 0.4976398945 gMotorVars.V_bias.value[1] = 0.4967572689 gMotorVars.V_bias.value[2] = 0.4971625209
Control Loop Parameters:
Current loop PID controller parameters obtained from CCS are:
controller_obj‐>pid_id.Kp = 2.42086 controller_obj‐>pid_id.Ki = 0.039197 controller_obj‐>pid_id.Kd = 0.0 controller_obj‐>pid_id.Kp = 2.42086 controller_obj‐>pid_id.Ki = 0.039197 controller_obj‐>pid_id.Kd = 0.0
The parameters obtained from the motor identification process can be entered into a PSIM schematic circuit for simulation. Refer to the tutorial “Simulation and Code Generation of TI InstaSPIN Using DRV8305 EVM.pdf” for more details.