BOOSTXL-DRV8305EVM: BOOSTXL-DRV8305EVM using with LAUNCHXL-F28027F

Hello Sean,

Yes I am using the instaSPIN-FOC lab. 

I started off with lab02b/c so that the motor parameters could be identified in user.h (per a TI forum thread with similar issue). This lab was a success in turning on the motor (rotor moving) however it does not run the pump nor does the motor reach the referenced speed. 

Attempting lab05b or lab10a (again per a TI forum thread with similar issue) I get compilation failures "fatal error #35: #error directive: The flux estimation frequency is not defined in user.h " therefore I am unable to load either of these to the board. 

I have already verified that the input DC voltage is correct for the boost board and my current max is based on the motor.  

I thought maybe there was an issue with the motor/pump however using the driver from the motor manufacturer as well as another competitor driver it seems to work as expected.

#ifndef _USER_H_
#define _USER_H_
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//! \file solutions/instaspin_foc/boards/boostxl-drv8305evm_revA/f28x/f2802xF/src/user.h
//! \brief Contains the public interface for user initialization data for the CTRL, HAL, and EST modules
//!
//! (C) Copyright 2015, Texas Instruments, Inc.

// **************************************************************************
// the includes

// modules
#include "sw/modules/types/src/types.h"
#include "sw/modules/motor/src/32b/motor.h"
#include "sw/modules/est/src/32b/est.h"
#include "sw/modules/est/src/est_states.h"
#include "sw/modules/est/src/est_Flux_states.h"
#include "sw/modules/est/src/est_Ls_states.h"
#include "sw/modules/est/src/est_Rs_states.h"
#include "sw/modules/ctrl/src/32b/ctrl_obj.h"

// platforms
#include "sw/modules/fast/src/32b/userParams.h"

//!
//!
//! \defgroup USER USER
//!
//@{

#ifdef __cplusplus
extern "C" {
#endif

// **************************************************************************
// the defines

//! \brief CURRENTS AND VOLTAGES
// **************************************************************************
//! \brief Defines the full scale frequency for IQ variable, Hz
//! \brief All frequencies are converted into (pu) based on the ratio to this value
//! \brief this value MUST be larger than the maximum speed that you are expecting from the motor
#define USER_IQ_FULL_SCALE_FREQ_Hz (800.0) // 800 Example with buffer for 8-pole 6 KRPM motor to be run to 10 KRPM with field weakening; Hz =(RPM * Poles) / 120

//! \brief Defines full scale value for the IQ30 variable of Voltage inside the system
//! \brief All voltages are converted into (pu) based on the ratio to this value
//! \brief WARNING: this value MUST meet the following condition: USER_IQ_FULL_SCALE_VOLTAGE_V > 0.5 * USER_MOTOR_MAX_CURRENT * USER_MOTOR_Ls_d * USER_VOLTAGE_FILTER_POLE_rps,
//! \brief WARNING: otherwise the value can saturate and roll-over, causing an inaccurate value
//! \brief WARNING: this value is OFTEN greater than the maximum measured ADC value, especially with high Bemf motors operating at higher than rated speeds
//! \brief WARNING: if you know the value of your Bemf constant, and you know you are operating at a multiple speed due to field weakening, be sure to set this value higher than the expected Bemf voltage
//! \brief It is recommended to start with a value ~3x greater than the USER_ADC_FULL_SCALE_VOLTAGE_V and increase to 4-5x if scenarios where a Bemf calculation may exceed these limits
//! \brief This value is also used to calculate the minimum flux value: USER_IQ_FULL_SCALE_VOLTAGE_V/USER_EST_FREQ_Hz/0.7
#define USER_IQ_FULL_SCALE_VOLTAGE_V (24.0) // 24.0 Set to Vbus

//! \brief Defines the maximum voltage at the input to the AD converter
//! \brief The value that will be represented by the maximum ADC input (3.3V) and conversion (0FFFh)
//! \brief Hardware dependent, this should be based on the voltage sensing and scaling to the ADC input
#define USER_ADC_FULL_SCALE_VOLTAGE_V (44.30) // BOOSTXL-DRV8305EVM = 44.30 V

//! \brief Defines the voltage scale factor for the system
//! \brief Compile time calculation for scale factor (ratio) used throughout the system
#define USER_VOLTAGE_SF ((float_t)((USER_ADC_FULL_SCALE_VOLTAGE_V)/(USER_IQ_FULL_SCALE_VOLTAGE_V)))

//! \brief Defines the full scale current for the IQ variables, A
//! \brief All currents are converted into (pu) based on the ratio to this value
//! \brief WARNING: this value MUST be larger than the maximum current readings that you are expecting from the motor or the reading will roll over to 0, creating a control issue
#define USER_IQ_FULL_SCALE_CURRENT_A (24.0) // BOOSTXL-DRV8305EVM = 24.0 A

//! \brief Defines the maximum current at the AD converter
//! \brief The value that will be represented by the maximum ADC input (3.3V) and conversion (0FFFh)
//! \brief Hardware dependent, this should be based on the current sensing and scaling to the ADC input
#define USER_ADC_FULL_SCALE_CURRENT_A (47.14) // BOOSTXL-DRV8305EVM = 47.14 A

//! \brief Defines the current scale factor for the system
//! \brief Compile time calculation for scale factor (ratio) used throughout the system
#define USER_CURRENT_SF ((float_t)((USER_ADC_FULL_SCALE_CURRENT_A)/(USER_IQ_FULL_SCALE_CURRENT_A)))

//! \brief Defines the number of current sensors used
//! \brief Defined by the hardware capability present
//! \brief May be (2) or (3)
#define USER_NUM_CURRENT_SENSORS (3) // 3 Preferred setting for best performance across full speed range, allows for 100% duty cycle

//! \brief Defines the number of voltage (phase) sensors
//! \brief Must be (3)
#define USER_NUM_VOLTAGE_SENSORS (3) // 3 Required

//! \brief ADC current offsets for A, B, and C phases
//! \brief One-time hardware dependent, though the calibration can be done at run-time as well
//! \brief After initial board calibration these values should be updated for your specific hardware so they are available after compile in the binary to be loaded to the controller
#define I_A_offset (1.210729778) // BOOSTXL-DRV8305EVM = 1.047175646
#define I_B_offset (1.209441483) // BOOSTXL-DRV8305EVM = 1.044038892
#define I_C_offset (1.209092796) // BOOSTXL-DRV8305EVM = 1.040363491

//! \brief ADC voltage offsets for A, B, and C phases
//! \brief One-time hardware dependent, though the calibration can be done at run-time as well
//! \brief After initial board calibration these values should be updated for your specific hardware so they are available after compile in the binary to be loaded to the controller
#define V_A_offset (0.5084558129) // BOOSTXL-DRV8305EVM = 0.5256254077
#define V_B_offset (0.5074239969) // BOOSTXL-DRV8305EVM = 0.5250559449
#define V_C_offset (0.5065535307) // BOOSTXL-DRV8305EVM = 0.5247237682

//! \brief CLOCKS & TIMERS
// **************************************************************************
//! \brief Defines the system clock frequency, MHz
#define USER_SYSTEM_FREQ_MHz (60.0)

//! \brief Defines the Pulse Width Modulation (PWM) frequency, kHz
//! \brief PWM frequency can be set directly here up to 30 KHz safely (60 KHz MAX in some cases)
//! \brief For higher PWM frequencies (60 KHz+ typical for low inductance, high current ripple motors) it is recommended to use the ePWM hardware
//! \brief and adjustable ADC SOC to decimate the ADC conversion done interrupt to the control system, or to use the software Que example.
//! \brief Otherwise you risk missing interrupts and disrupting the timing of the control state machine
#define USER_PWM_FREQ_kHz (45.0) //30.0 Example, 8.0 - 30.0 KHz typical; 45-80 KHz may be required for very low inductance, high speed motors

//! \brief Defines the maximum Voltage vector (Vs) magnitude allowed. This value sets the maximum magnitude for the output of the
//! \brief Id and Iq PI current controllers. The Id and Iq current controller outputs are Vd and Vq.
//! \brief The relationship between Vs, Vd, and Vq is: Vs = sqrt(Vd^2 + Vq^2). In this FOC controller, the
//! \brief Vd value is set equal to USER_MAX_VS_MAG*USER_VD_MAG_FACTOR. Vq = sqrt(USER_MAX_VS_MAG^2 - Vd^2).
//! \brief Set USER_MAX_VS_MAG = 0.5 for a pure sinewave with a peak at SQRT(3)/2 = 86.6% duty cycle. No current reconstruction is needed for this scenario.
//! \brief Set USER_MAX_VS_MAG = 1/SQRT(3) = 0.5774 for a pure sinewave with a peak at 100% duty cycle. Current reconstruction will be needed for this scenario (Lab10a-x).
//! \brief Set USER_MAX_VS_MAG = 2/3 = 0.6666 to create a trapezoidal voltage waveform. Current reconstruction will be needed for this scenario (Lab10a-x).
//! \brief For space vector over-modulation, see lab 10 for details on system requirements that will allow the SVM generator to go all the way to trapezoidal.
#define USER_MAX_VS_MAG_PU (0.5) // Set to 0.5 if a current reconstruction technique is not used. Look at the module svgen_current in lab10a-x for more info.

//! \brief Defines the address of estimator handle
//!
#define USER_EST_HANDLE_ADDRESS (0x600)

//! \brief Defines the direct voltage (Vd) scale factor
//!
#define USER_VD_SF (0.95)

//! \brief Defines the Pulse Width Modulation (PWM) period, usec
//! \brief Compile time calculation
#define USER_PWM_PERIOD_usec (1000.0/USER_PWM_FREQ_kHz)

//! \brief Defines the Interrupt Service Routine (ISR) frequency, Hz
//!
#define USER_ISR_FREQ_Hz ((float_t)USER_PWM_FREQ_kHz * 1000.0 / (float_t)USER_NUM_PWM_TICKS_PER_ISR_TICK)

//! \brief Defines the Interrupt Service Routine (ISR) period, usec
//!
#define USER_ISR_PERIOD_usec (USER_PWM_PERIOD_usec * (float_t)USER_NUM_PWM_TICKS_PER_ISR_TICK)

//! \brief DECIMATION
// **************************************************************************
//! \brief Defines the number of pwm clock ticks per isr clock tick
//! Note: Valid values are 1, 2 or 3 only
#define USER_NUM_PWM_TICKS_PER_ISR_TICK (3)

//! \brief Defines the number of isr ticks (hardware) per controller clock tick (software)
//! \brief Controller clock tick (CTRL) is the main clock used for all timing in the software
//! \brief Typically the PWM Frequency triggers (can be decimated by the ePWM hardware for less overhead) an ADC SOC
//! \brief ADC SOC triggers an ADC Conversion Done
//! \brief ADC Conversion Done triggers ISR
//! \brief This relates the hardware ISR rate to the software controller rate
//! \brief Typcially want to consider some form of decimation (ePWM hardware, CURRENT or EST) over 16KHz ISR to insure interrupt completes and leaves time for background tasks
#define USER_NUM_ISR_TICKS_PER_CTRL_TICK (1) // 2 Example, controller clock rate (CTRL) runs at PWM / 2; ex 30 KHz PWM, 15 KHz control

//! \brief Defines the number of controller clock ticks per current controller clock tick
//! \brief Relationship of controller clock rate to current controller (FOC) rate
#define USER_NUM_CTRL_TICKS_PER_CURRENT_TICK (1) // 1 Typical, Forward FOC current controller (Iq/Id/IPARK/SVPWM) runs at same rate as CTRL.

//! \brief Defines the number of controller clock ticks per estimator clock tick
//! \brief Relationship of controller clock rate to estimator (FAST) rate
//! \brief Depends on needed dynamic performance, FAST provides very good results as low as 1 KHz while more dynamic or high speed applications may require up to 15 KHz
#define USER_NUM_CTRL_TICKS_PER_EST_TICK (1) // 1 Typical, FAST estimator runs at same rate as CTRL;

//! \brief Defines the number of controller clock ticks per speed controller clock tick
//! \brief Relationship of controller clock rate to speed loop rate
#define USER_NUM_CTRL_TICKS_PER_SPEED_TICK (15) // 15 Typical to match PWM, ex: 15KHz PWM, controller, and current loop, 1KHz speed loop

//! \brief Defines the number of controller clock ticks per trajectory clock tick
//! \brief Relationship of controller clock rate to trajectory loop rate
//! \brief Typically the same as the speed rate
#define USER_NUM_CTRL_TICKS_PER_TRAJ_TICK (15) // 15 Typical to match PWM, ex: 10KHz controller & current loop, 1KHz speed loop, 1 KHz Trajectory

//! \brief Defines the controller frequency, Hz
//! \brief Compile time calculation
#define USER_CTRL_FREQ_Hz (uint_least32_t)(USER_ISR_FREQ_Hz/USER_NUM_ISR_TICKS_PER_CTRL_TICK)

//! \brief Defines the estimator frequency, Hz
//! \brief Compile time calculation
#define USER_EST_FREQ_Hz (uint_least32_t)(USER_CTRL_FREQ_Hz/USER_NUM_CTRL_TICKS_PER_EST_TICK)

//! \brief Defines the trajectory frequency, Hz
//! \brief Compile time calculation
#define USER_TRAJ_FREQ_Hz (uint_least32_t)(USER_CTRL_FREQ_Hz/USER_NUM_CTRL_TICKS_PER_TRAJ_TICK)

//! \brief Defines the controller execution period, usec
//! \brief Compile time calculation
#define USER_CTRL_PERIOD_usec (USER_ISR_PERIOD_usec * USER_NUM_ISR_TICKS_PER_CTRL_TICK)

//! \brief Defines the controller execution period, sec
//! \brief Compile time calculation
#define USER_CTRL_PERIOD_sec ((float_t)USER_CTRL_PERIOD_usec/(float_t)1000000.0)

//! \brief LIMITS
// **************************************************************************
//! \brief Defines the maximum negative current to be applied in Id reference
//! \brief Used in field weakening only, this is a safety setting (e.g. to protect against demagnetization)
//! \brief User must also be aware that overall current magnitude [sqrt(Id^2 + Iq^2)] should be kept below any machine design specifications
#define USER_MAX_NEGATIVE_ID_REF_CURRENT_A (-0.5 * USER_MOTOR_MAX_CURRENT) // -0.5 * USER_MOTOR_MAX_CURRENT Example, adjust to meet safety needs of your motor

//! \brief Defines the low speed limit for the flux integrator, pu
//! \brief This is the speed range (CW/CCW) at which the ForceAngle object is active, but only if Enabled
//! \brief Outside of this speed - or if Disabled - the ForcAngle will NEVER be active and the angle is provided by FAST only
#define USER_ZEROSPEEDLIMIT (0.5 / USER_IQ_FULL_SCALE_FREQ_Hz) // 0.002 pu, 1-5 Hz typical; Hz = USER_ZEROSPEEDLIMIT * USER_IQ_FULL_SCALE_FREQ_Hz

//! \brief Defines the force angle frequency, Hz
//! \brief Frequency of stator vector rotation used by the ForceAngle object
//! \brief Can be positive or negative
#define USER_FORCE_ANGLE_FREQ_Hz (2.0 * USER_ZEROSPEEDLIMIT * USER_IQ_FULL_SCALE_FREQ_Hz) // Default will keep FREQ >= 2.0 * low speed limit for the flux integrator

//! \brief Defines the maximum current slope for Id trajectory during PowerWarp
//! \brief For Induction motors only, controls how fast Id input can change under PowerWarp control
#define USER_MAX_CURRENT_SLOPE_POWERWARP (0.3*USER_MOTOR_RES_EST_CURRENT/USER_IQ_FULL_SCALE_CURRENT_A/USER_TRAJ_FREQ_Hz) // 0.3*RES_EST_CURRENT / IQ_FULL_SCALE_CURRENT / TRAJ_FREQ Typical to produce 1-sec rampup/down

//! \brief Defines the starting maximum acceleration AND deceleration for the speed profiles, Hz/s
//! \brief Updated in run-time through user functions
//! \brief Inverter, motor, inertia, and load will limit actual acceleration capability
#define USER_MAX_ACCEL_Hzps (20.0) // 20.0 Default

//! \brief Defines maximum acceleration for the estimation speed profiles, Hz/s
//! \brief Only used during Motor ID (commission)
#define USER_MAX_ACCEL_EST_Hzps (5.0) // 5.0 Default, don't change

//! \brief Defines the maximum current slope for Id trajectory during estimation
#define USER_MAX_CURRENT_SLOPE (USER_MOTOR_RES_EST_CURRENT/USER_IQ_FULL_SCALE_CURRENT_A/USER_TRAJ_FREQ_Hz) // USER_MOTOR_RES_EST_CURRENT/USER_IQ_FULL_SCALE_CURRENT_A/USER_TRAJ_FREQ_Hz Default, don't change

//! \brief Defines the fraction of IdRated to use during rated flux estimation
//!
#define USER_IDRATED_FRACTION_FOR_RATED_FLUX (1.0) // 1.0 Default, don't change

//! \brief Defines the fraction of IdRated to use during inductance estimation
//!
#define USER_IDRATED_FRACTION_FOR_L_IDENT (1.0) // 1.0 Default, don't change

//! \brief Defines the IdRated delta to use during estimation
//!
#define USER_IDRATED_DELTA (0.00002)

//! \brief Defines the fraction of SpeedMax to use during inductance estimation
//!
#define USER_SPEEDMAX_FRACTION_FOR_L_IDENT (1.0) // 1.0 Default, don't change

//! \brief Defines flux fraction to use during inductance identification
//!
#define USER_FLUX_FRACTION (1.0) // 1.0 Default, don't change

//! \brief Defines the PowerWarp gain for computing Id reference
//! \brief Induction motors only
#define USER_POWERWARP_GAIN (1.0) // 1.0 Default, don't change

//! \brief Defines the R/L estimation frequency, Hz
//! \brief User higher values for low inductance motors and lower values for higher inductance
//! \brief motors. The values can range from 100 to 300 Hz.
#define USER_R_OVER_L_EST_FREQ_Hz (300) // 300 Default for high speed motors, can reduce to 100 if RoverL from Motor ID is < 2000

//! \brief POLES
// **************************************************************************
//! \brief Defines the analog voltage filter pole location, Hz
//! \brief Must match the hardware filter for Vph
#define USER_VOLTAGE_FILTER_POLE_Hz (344.62) // BOOSTXL-DRV8305 = 344.62 Hz

//! \brief Defines the analog voltage filter pole location, rad/s
//! \brief Compile time calculation from Hz to rad/s
#define USER_VOLTAGE_FILTER_POLE_rps (2.0 * MATH_PI * USER_VOLTAGE_FILTER_POLE_Hz)

//! \brief Defines the software pole location for the voltage and current offset estimation, rad/s
//! \brief Should not be changed from default of (20.0)
#define USER_OFFSET_POLE_rps (20.0) // 20.0 Default, do not change

//! \brief Defines the software pole location for the flux estimation, rad/s
//! \brief Should not be changed from default of (100.0)
#define USER_FLUX_POLE_rps (100.0) // 100.0 Default, do not change

//! \brief Defines the software pole location for the direction filter, rad/s
#define USER_DIRECTION_POLE_rps (6.0) // 6.0 Default, do not change

//! \brief Defines the software pole location for the speed control filter, rad/s
#define USER_SPEED_POLE_rps (100.0) // 100.0 Default, do not change

//! \brief Defines the software pole location for the DC bus filter, rad/s
#define USER_DCBUS_POLE_rps (100.0) // 100.0 Default, do not change

//! \brief Defines the convergence factor for the estimator
//! \brief Do not change from default for FAST
#define USER_EST_KAPPAQ (1.5) // 1.5 Default, do not change

// **************************************************************************
// end the defines

//! \brief USER MOTOR & ID SETTINGS
// **************************************************************************

//! \brief Define each motor with a unique name and ID number
// BLDC & SMPM motors
#define Estun_EMJ_04APB22 101
#define Anaheim_BLY172S 102
#define My_Motor 104
#define hobby_3p5T 105
#define hobby_4p5T 106
#define small_hobby 107
#define teknic_2310P 108
#define hobbywing_ezrun_8p5T 109
#define eflite_helicopter_420 110
#define Bodine_34B3FEBL 114
#define Pittman_elcom_5233B599 115
#define medical_instrument 117
#define Test_Motor 118
#define ScrollLabs_SVF50 119
// IPM motors
// If user provides separate Ls-d, Ls-q
// else treat as SPM with user or identified average Ls
#define Belt_Drive_Washer_IPM 201

// ACIM motors
#define Marathon_5K33GN2A 301
#define Kinetek_YDQ1p3_4 302
#define LPKF_CAD_CAM 303

//! \brief Uncomment the motor which should be included at compile
//! \brief These motor ID settings and motor parameters are then available to be used by the control system
//! \brief Once your ideal settings and parameters are identified update the motor section here so it is available in the binary code
#define USER_MOTOR Estun_EMJ_04APB22
//#define USER_MOTOR Anaheim_BLY172S
//#define USER_MOTOR hobby_3p5T
//#define USER_MOTOR hobby_4p5T
//#define USER_MOTOR My_Motor
//#define USER_MOTOR small_hobby
//#define USER_MOTOR Belt_Drive_Washer_IPM
//#define USER_MOTOR Marathon_5K33GN2A
//#define USER_MOTOR teknic_2310P
//#define USER_MOTOR hobbywing_ezrun_8p5T
//#define USER_MOTOR eflite_helicopter_420
//#define USER_MOTOR Bodine_34B3FEBL
//#define USER_MOTOR Pittman_elcom_5233B599
//#define USER_MOTOR medical_instrument
//#define USER_MOTOR Test_Motor
//#define USER_MOTOR Kinetek_YDQ1p3_4
//#define USER_MOTOR LPKF_CAD_CAM

#if (USER_MOTOR == Estun_EMJ_04APB22) // Name must match the motor #define
#define USER_MOTOR_TYPE MOTOR_Type_Pm // Motor_Type_Pm (All Synchronous: BLDC, PMSM, SMPM, IPM) or Motor_Type_Induction (Asynchronous ACI)
#define USER_MOTOR_NUM_POLE_PAIRS (4) // PAIRS, not total poles. Used to calculate user RPM from rotor Hz only
#define USER_MOTOR_Rr (NULL) // Induction motors only, else NULL
#define USER_MOTOR_Rs (2.303403) // Identified phase to neutral resistance in a Y equivalent circuit (Ohms, float)
#define USER_MOTOR_Ls_d (0.008464367) // For PM, Identified average stator inductance (Henry, float)
#define USER_MOTOR_Ls_q (0.008464367) // For PM, Identified average stator inductance (Henry, float)
#define USER_MOTOR_RATED_FLUX (0.38) // Identified TOTAL flux linkage between the rotor and the stator (V/Hz)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL) // Induction motors only, else NULL
#define USER_MOTOR_RES_EST_CURRENT (1.0) // During Motor ID, maximum current (Amperes, float) used for Rs estimation, 10-20% rated current
#define USER_MOTOR_IND_EST_CURRENT (-1.0) // During Motor ID, maximum current (negative Amperes, float) used for Ls estimation, use just enough to enable rotation
#define USER_MOTOR_MAX_CURRENT (3.82) // CRITICAL: Used during ID and run-time, sets a limit on the maximum current command output of the provided Speed PI Controller to the Iq controller
#define USER_MOTOR_FLUX_EST_FREQ_Hz (20.0) // During Motor ID, maximum commanded speed (Hz, float), ~10% rated

#elif (USER_MOTOR == Anaheim_BLY172S)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (4)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.3968007)
#define USER_MOTOR_Ls_d (0.0006708066)
#define USER_MOTOR_Ls_q (0.0006708066)
#define USER_MOTOR_RATED_FLUX (0.03433958)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (1.0)
#define USER_MOTOR_IND_EST_CURRENT (-1.0)
#define USER_MOTOR_MAX_CURRENT (5.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (20.0)

#define USER_MOTOR_FREQ_LOW (10.0) // Hz - suggested to set to 10% of rated motor frequency
#define USER_MOTOR_FREQ_HIGH (100.0) // Hz - suggested to set to 100% of rated motor frequency
#define USER_MOTOR_FREQ_MAX (120.0) // Hz - suggested to set to 120% of rated motor frequency
#define USER_MOTOR_VOLT_MIN (3.0) // Volt - suggested to set to 15% of rated motor voltage
#define USER_MOTOR_VOLT_MAX (18.0) // Volt - suggested to set to 100% of rated motor voltage

#elif (USER_MOTOR == small_hobby)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (6)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (1.277921)
#define USER_MOTOR_Ls_d (0.0001230481)
#define USER_MOTOR_Ls_q (0.0001230481)
#define USER_MOTOR_RATED_FLUX (0.004417491)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (0.5)
#define USER_MOTOR_IND_EST_CURRENT (-0.5)
#define USER_MOTOR_MAX_CURRENT (5.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (200.0)

#elif (USER_MOTOR == teknic_2310P)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (4)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.3654691)
#define USER_MOTOR_Ls_d (0.0002068772)
#define USER_MOTOR_Ls_q (0.0002068772)
#define USER_MOTOR_RATED_FLUX (0.04052209)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (1.0)
#define USER_MOTOR_IND_EST_CURRENT (-1.0)
#define USER_MOTOR_MAX_CURRENT (5.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (20.0)

#elif (USER_MOTOR == hobby_3p5T)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (4)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.0149275)
#define USER_MOTOR_Ls_d (2.575126e-06)
#define USER_MOTOR_Ls_q (2.575126e-06)
#define USER_MOTOR_RATED_FLUX (0.003589415)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (15.0)
#define USER_MOTOR_IND_EST_CURRENT (-5.0)
#define USER_MOTOR_MAX_CURRENT (30.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (60.0)

#elif (USER_MOTOR == hobby_4p5T)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (4)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.01420126)
#define USER_MOTOR_Ls_d (6.466606e-06)
#define USER_MOTOR_Ls_q (6.466606e-06)
#define USER_MOTOR_RATED_FLUX (0.004845501)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (5.0)
#define USER_MOTOR_IND_EST_CURRENT (-5.0)
#define USER_MOTOR_MAX_CURRENT (10.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (60.0)

#elif (USER_MOTOR == hobbywing_ezrun_8p5T)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (1)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.01366183)
#define USER_MOTOR_Ls_d (1.556967e-05)
#define USER_MOTOR_Ls_q (1.556967e-05)
#define USER_MOTOR_RATED_FLUX (0.009272549)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (3.0)
#define USER_MOTOR_IND_EST_CURRENT (-2.0)
#define USER_MOTOR_MAX_CURRENT (10.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (60.0)

#elif (USER_MOTOR == eflite_helicopter_420)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (3)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.01953091)
#define USER_MOTOR_Ls_d (2.998549e-06)
#define USER_MOTOR_Ls_q (2.998549e-06)
#define USER_MOTOR_RATED_FLUX (0.003449948)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (3.0)
#define USER_MOTOR_IND_EST_CURRENT (-3.0)
#define USER_MOTOR_MAX_CURRENT (15.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (80.0)

#elif (USER_MOTOR == Bodine_34B3FEBL)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (2)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.1749963)
#define USER_MOTOR_Ls_d (0.000843199)
#define USER_MOTOR_Ls_q (0.000843199)
#define USER_MOTOR_RATED_FLUX (0.1139098)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (1.0)
#define USER_MOTOR_IND_EST_CURRENT (-1.0)
#define USER_MOTOR_MAX_CURRENT (10.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (20.0)

#elif (USER_MOTOR == Pittman_elcom_5233B599)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (2)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.3675933)
#define USER_MOTOR_Ls_d (0.0001611779)
#define USER_MOTOR_Ls_q (0.0001611779)
#define USER_MOTOR_RATED_FLUX (0.1274101)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (0.5)
#define USER_MOTOR_IND_EST_CURRENT (-0.5)
#define USER_MOTOR_MAX_CURRENT (5.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (20.0)

#elif (USER_MOTOR == medical_instrument)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (2)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.3858043)
#define USER_MOTOR_Ls_d (9.675411e-06)
#define USER_MOTOR_Ls_q (9.675411e-06)
#define USER_MOTOR_RATED_FLUX (0.006834516)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (0.5)
#define USER_MOTOR_IND_EST_CURRENT (-0.5)
#define USER_MOTOR_MAX_CURRENT (10.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (100.0)

#elif (USER_MOTOR == Test_Motor)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (6)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.05910907)
#define USER_MOTOR_Ls_d (7.49289e-06)
#define USER_MOTOR_Ls_q (7.49289e-06)
#define USER_MOTOR_RATED_FLUX (0.003744936)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (1.5)
#define USER_MOTOR_IND_EST_CURRENT (-1.0)
#define USER_MOTOR_MAX_CURRENT (8.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (100.0)

#elif (USER_MOTOR == My_Motor)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (2)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.3918252)
#define USER_MOTOR_Ls_d (0.00023495)
#define USER_MOTOR_Ls_q (0.00023495)
#define USER_MOTOR_RATED_FLUX (0.03955824)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (3.0)
#define USER_MOTOR_IND_EST_CURRENT (-0.5)
#define USER_MOTOR_MAX_CURRENT (20.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (20.0)

#elif (USER_MOTOR == Belt_Drive_Washer_IPM)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (4)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (2.832002)
#define USER_MOTOR_Ls_d (0.0115)
#define USER_MOTOR_Ls_q (0.0135)
#define USER_MOTOR_RATED_FLUX (0.5022156)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (1.0)
#define USER_MOTOR_IND_EST_CURRENT (-1.0)
#define USER_MOTOR_MAX_CURRENT (4.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (20.0)

#elif (USER_MOTOR == Marathon_5K33GN2A) // Name must match the motor #define
#define USER_MOTOR_TYPE MOTOR_Type_Induction // Motor_Type_Pm (All Synchronous: BLDC, PMSM, SMPM, IPM) or Motor_Type_Induction (Asynchronous ACI)
#define USER_MOTOR_NUM_POLE_PAIRS (2) // PAIRS, not total poles. Used to calculate user RPM from rotor Hz only
#define USER_MOTOR_Rr (5.508003) // Identified phase to neutral in a Y equivalent circuit (Ohms, float)
#define USER_MOTOR_Rs (10.71121) // Identified phase to neutral in a Y equivalent circuit (Ohms, float)
#define USER_MOTOR_Ls_d (0.05296588) // For Induction, Identified average stator inductance (Henry, float)
#define USER_MOTOR_Ls_q (0.05296588) // For Induction, Identified average stator inductance (Henry, float)
#define USER_MOTOR_RATED_FLUX (0.8165*220.0/60.0) // sqrt(2/3)* Rated V (line-line) / Rated Freq (Hz)
#define USER_MOTOR_MAGNETIZING_CURRENT (1.378) // Identified magnetizing current for induction motors, else NULL
#define USER_MOTOR_RES_EST_CURRENT (0.5) // During Motor ID, maximum current (Amperes, float) used for Rs estimation, 10-20% rated current
#define USER_MOTOR_IND_EST_CURRENT (NULL) // not used for induction
#define USER_MOTOR_MAX_CURRENT (2.0) // CRITICAL: Used during ID and run-time, sets a limit on the maximum current command output of the provided Speed PI Controller to the Iq controller
#define USER_MOTOR_FLUX_EST_FREQ_Hz (5.0) // During Motor ID, maximum commanded speed (Hz, float). Should always use 5 Hz for Induction.

#elif (USER_MOTOR == Kinetek_YDQ1p3_4)
#define USER_MOTOR_TYPE MOTOR_Type_Induction
#define USER_MOTOR_NUM_POLE_PAIRS (2)
#define USER_MOTOR_Rr (0.0)
#define USER_MOTOR_Rs (0.0)
#define USER_MOTOR_Ls_d (0.0)
#define USER_MOTOR_Ls_q (USER_MOTOR_Ls_d)
#define USER_MOTOR_RATED_FLUX (0.8165*16.0/120.0 - USER_MOTOR_Ls_d*USER_MOTOR_MAGNETIZING_CURRENT*2*MATH_PI)
#define USER_MOTOR_MAGNETIZING_CURRENT (0.0)
#define USER_MOTOR_RES_EST_CURRENT (20.0)
#define USER_MOTOR_IND_EST_CURRENT (NULL)
#define USER_MOTOR_MAX_CURRENT (40.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (5.0)

#elif (USER_MOTOR == LPKF_CAD_CAM)
#define USER_MOTOR_TYPE MOTOR_Type_Induction
#define USER_MOTOR_NUM_POLE_PAIRS (1)
#define USER_MOTOR_Rr (0.1832338)
#define USER_MOTOR_Rs (0.2610424)
#define USER_MOTOR_Ls_d (1.370321e-09)
#define USER_MOTOR_Ls_q (USER_MOTOR_Ls_d)
#define USER_MOTOR_RATED_FLUX (0.8165*30.0/1000.0 - USER_MOTOR_Ls_d*USER_MOTOR_MAGNETIZING_CURRENT*2*MATH_PI)
#define USER_MOTOR_MAGNETIZING_CURRENT (3.386112)
#define USER_MOTOR_RES_EST_CURRENT (3.0)
#define USER_MOTOR_IND_EST_CURRENT (NULL)
#define USER_MOTOR_MAX_CURRENT (5.0)
#define USER_MOTOR_FLUX_EST_FREQ_Hz (20.0)

#elif (USER_MOTOR == ScrollLabs_SVF50)
#define USER_MOTOR_TYPE MOTOR_Type_Pm
#define USER_MOTOR_NUM_POLE_PAIRS (4)
#define USER_MOTOR_Rr (NULL)
#define USER_MOTOR_Rs (0.0414625593)
#define USER_MOTOR_Ls_d (1.72044079e-09)
#define USER_MOTOR_Ls_q (1.72044079e-09)
#define USER_MOTOR_RATED_FLUX (0.0426666625)
#define USER_MOTOR_MAGNETIZING_CURRENT (NULL)
#define USER_MOTOR_RES_EST_CURRENT (3.5)
#define USER_MOTOR_IND_EST_CURRENT (-3.5)
#define USER_MOTOR_MAX_CURRENT (7.0)
#define USER_MOTOR_IDENT_FREQUENCY_Hz (100.0)

#else
#error No motor type specified
#endif

#ifndef USER_MOTOR
#error Motor is not defined in user.h
#endif

#ifndef USER_MOTOR_TYPE
#error The motor type is not defined in user.h
#endif

#ifndef USER_MOTOR_NUM_POLE_PAIRS
#error Number of motor pole pairs is not defined in user.h
#endif

#ifndef USER_MOTOR_Rr
#error The rotor resistance is not defined in user.h
#endif

#ifndef USER_MOTOR_Rs
#error The stator resistance is not defined in user.h
#endif

#ifndef USER_MOTOR_Ls_d
#error The direct stator inductance is not defined in user.h
#endif

#ifndef USER_MOTOR_Ls_q
#error The quadrature stator inductance is not defined in user.h
#endif

#ifndef USER_MOTOR_RATED_FLUX
#error The rated flux of motor is not defined in user.h
#endif

#ifndef USER_MOTOR_MAGNETIZING_CURRENT
#error The magnetizing current is not defined in user.h
#endif

#ifndef USER_MOTOR_RES_EST_CURRENT
#error The resistance estimation current is not defined in user.h
#endif

#ifndef USER_MOTOR_IND_EST_CURRENT
#error The inductance estimation current is not defined in user.h
#endif

#ifndef USER_MOTOR_MAX_CURRENT
#error The maximum current is not defined in user.h
#endif

#ifndef USER_MOTOR_FLUX_EST_FREQ_Hz
#error The flux estimation frequency is not defined in user.h
#endif

// **************************************************************************
// the functions

//! \brief Sets the user parameter values
//! \param[in] pUserParams The pointer to the user param structure
extern void USER_setParams(USER_Params *pUserParams);

//! \brief Checks for errors in the user parameter values
//! \param[in] pUserParams The pointer to the user param structure
extern void USER_checkForErrors(USER_Params *pUserParams);

//! \brief Gets the error code in the user parameters
//! \param[in] pUserParams The pointer to the user param structure
//! \return The error code
extern USER_ErrorCode_e USER_getErrorCode(USER_Params *pUserParams);

//! \brief Sets the error code in the user parameters
//! \param[in] pUserParams The pointer to the user param structure
//! \param[in] errorCode The error code
extern void USER_setErrorCode(USER_Params *pUserParams,const USER_ErrorCode_e errorCode);

//! \brief Recalculates Inductances with the correct Q Format
//! \param[in] handle The controller (CTRL) handle
extern void USER_softwareUpdate1p6(CTRL_Handle handle);

//! \brief Updates Id and Iq PI gains
//! \param[in] handle The controller (CTRL) handle
extern void USER_calcPIgains(CTRL_Handle handle);

//! \brief Computes the scale factor needed to convert from torque created by Ld, Lq, Id and Iq, from per unit to Nm
//! \return The scale factor to convert torque from (Ld - Lq) * Id * Iq from per unit to Nm, in IQ24 format
extern _iq USER_computeTorque_Ls_Id_Iq_pu_to_Nm_sf(void);

//! \brief Computes the scale factor needed to convert from torque created by flux and Iq, from per unit to Nm
//! \return The scale factor to convert torque from Flux * Iq from per unit to Nm, in IQ24 format
extern _iq USER_computeTorque_Flux_Iq_pu_to_Nm_sf(void);

//! \brief Computes the scale factor needed to convert from per unit to Wb
//! \return The scale factor to convert from flux per unit to flux in Wb, in IQ24 format
extern _iq USER_computeFlux_pu_to_Wb_sf(void);

//! \brief Computes the scale factor needed to convert from per unit to V/Hz
//! \return The scale factor to convert from flux per unit to flux in V/Hz, in IQ24 format
extern _iq USER_computeFlux_pu_to_VpHz_sf(void);

//! \brief Computes Flux in Wb or V/Hz depending on the scale factor sent as parameter
//! \param[in] handle The controller (CTRL) handle
//! \param[in] sf The scale factor to convert flux from per unit to Wb or V/Hz
//! \return The flux in Wb or V/Hz depending on the scale factor sent as parameter, in IQ24 format
extern _iq USER_computeFlux(CTRL_Handle handle, const _iq sf);

//! \brief Computes Torque in Nm
//! \param[in] handle The controller (CTRL) handle
//! \param[in] torque_Flux_sf The scale factor to convert torque from (Ld - Lq) * Id * Iq from per unit to Nm
//! \param[in] torque_Ls_sf The scale factor to convert torque from Flux * Iq from per unit to Nm
//! \return The torque in Nm, in IQ24 format
extern _iq USER_computeTorque_Nm(CTRL_Handle handle, const _iq torque_Flux_sf, const _iq torque_Ls_sf);

//! \brief Computes Torque in lbin
//! \param[in] handle The controller (CTRL) handle
//! \param[in] torque_Flux_sf The scale factor to convert torque from (Ld - Lq) * Id * Iq from per unit to lbin
//! \param[in] torque_Ls_sf The scale factor to convert torque from Flux * Iq from per unit to lbin
//! \return The torque in lbin, in IQ24 format
extern _iq USER_computeTorque_lbin(CTRL_Handle handle, const _iq torque_Flux_sf, const _iq torque_Ls_sf);

#ifdef __cplusplus
}
#endif // extern "C"

//@} // ingroup
#endif // end of _USER_H_ definition

Updated per your recommendations allows the code to complie successfully however the motor still isn't operating the pump and the current draw is still less than nominal.