Progetto STM32
concorso
Dependencies: HCSR04 NetworkSocketAPI Servo X_NUCLEO_53L0A1 X_NUCLEO_IDW01M1v2 X_NUCLEO_IHM02A1 mbed-rtos mbed
Fork of
HelloWorld_IHM02A1
by 
ST
main.cpp
- Committer:
- Davidroid
- Date:
- 2016-01-14
- Revision:
- 11:79fcaf38c09d
- Parent:
- 9:f35fbeedb8f4
- Child:
- 12:5be6dd48b94a
File content as of revision 11:79fcaf38c09d:
/**
******************************************************************************
* @file main.cpp
* @author Davide Aliprandi, STMicrolectronics
* @version V1.0.0
* @date November 4th, 2015
* @brief mbed test application for the STMicrolectronics X-NUCLEO-IHM02A1
* Motor Control Expansion Board: control of 2 motors.
******************************************************************************
* @attention
*
* <h2><center>© COPYRIGHT(c) 2015 STMicroelectronics</center></h2>
*
* Redistribution and use in source and binary forms, with or without modification,
* are permitted provided that the following conditions are met:
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
* 3. Neither the name of STMicroelectronics nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
/* mbed specific header files. */
#include "mbed.h"
/* Helper header files. */
#include "DevSPI.h"
/* Expansion Board specific header files. */
#include "x_nucleo_ihm02a1_class.h"
/* Definitions ---------------------------------------------------------------*/
/* Number of movements per revolution. */
#define MPR_1 4
/* Number of steps. */
#define STEPS_1 100000
#define STEPS_2 200000
/* Delay in milliseconds. */
#define DELAY_1 1000
#define DELAY_2 2000
#define DELAY_3 5000
/* Variables -----------------------------------------------------------------*/
/* Motor Control Expansion Board. */
X_NUCLEO_IHM02A1 *x_nucleo_ihm02a1;
/* Initialization parameters of the motors connected to the expansion board. */
L6470_InitTypeDef init[L6470DAISYCHAINSIZE] =
{
/* First Motor. */
{
9.0, /* Motor supply voltage in V. */
400, /* Min number of steps per revolution for the motor. */
1.7, /* Max motor phase voltage in A. */
3.06, /* Max motor phase voltage in V. */
300.0, /* Motor initial speed [step/s]. */
500.0, /* Motor acceleration [step/s^2] (comment for infinite acceleration mode). */
500.0, /* Motor deceleration [step/s^2] (comment for infinite deceleration mode). */
992.0, /* Motor maximum speed [step/s]. */
0.0, /* Motor minimum speed [step/s]. */
602.7, /* Motor full-step speed threshold [step/s]. */
3.06, /* Holding kval [V]. */
3.06, /* Constant speed kval [V]. */
3.06, /* Acceleration starting kval [V]. */
3.06, /* Deceleration starting kval [V]. */
61.52, /* Intersect speed for bemf compensation curve slope changing [step/s]. */
392.1569e-6, /* Start slope [s/step]. */
643.1372e-6, /* Acceleration final slope [s/step]. */
643.1372e-6, /* Deceleration final slope [s/step]. */
0, /* Thermal compensation factor (range [0, 15]). */
3.06 * 1000 * 1.10, /* Ocd threshold [ma] (range [375 ma, 6000 ma]). */
3.06 * 1000 * 1.00, /* Stall threshold [ma] (range [31.25 ma, 4000 ma]). */
MICROSTEP_1_128, /* Step mode selection. */
0xFF, /* Alarm conditions enable. */
0x2E88 /* Ic configuration. */
},
/* Second Motor. */
{
9.0, /* Motor supply voltage in V. */
400, /* Min number of steps per revolution for the motor. */
1.7, /* Max motor phase voltage in A. */
3.06, /* Max motor phase voltage in V. */
300.0, /* Motor initial speed [step/s]. */
500.0, /* Motor acceleration [step/s^2] (comment for infinite acceleration mode). */
500.0, /* Motor deceleration [step/s^2] (comment for infinite deceleration mode). */
992.0, /* Motor maximum speed [step/s]. */
0.0, /* Motor minimum speed [step/s]. */
602.7, /* Motor full-step speed threshold [step/s]. */
3.06, /* Holding kval [V]. */
3.06, /* Constant speed kval [V]. */
3.06, /* Acceleration starting kval [V]. */
3.06, /* Deceleration starting kval [V]. */
61.52, /* Intersect speed for bemf compensation curve slope changing [step/s]. */
392.1569e-6, /* Start slope [s/step]. */
643.1372e-6, /* Acceleration final slope [s/step]. */
643.1372e-6, /* Deceleration final slope [s/step]. */
0, /* Thermal compensation factor (range [0, 15]). */
3.06 * 1000 * 1.10, /* Ocd threshold [ma] (range [375 ma, 6000 ma]). */
3.06 * 1000 * 1.00, /* Stall threshold [ma] (range [31.25 ma, 4000 ma]). */
MICROSTEP_1_128, /* Step mode selection. */
0xFF, /* Alarm conditions enable. */
0x2E88 /* Ic configuration. */
}
};
/* Main ----------------------------------------------------------------------*/
int main()
{
/*----- Initialization. -----*/
/* Initializing SPI bus. */
DevSPI dev_spi(D11, D12, D3);
/* Initializing Motor Control Expansion Board. */
x_nucleo_ihm02a1 = new X_NUCLEO_IHM02A1(&init[0], &init[1], A4, A5, D4, A2, &dev_spi);
/* Building a list of motor control components. */
L6470 **motors = x_nucleo_ihm02a1->GetComponents();
/* Printing to the console. */
printf("Motor Control Application Example for 2 Motors\r\n\n");
/*----- Setting home and marke positions, getting positions, and going to positions. -----*/
/* Printing to the console. */
printf("--> Setting home position.\r\n");
/* Setting the home position. */
motors[0]->SetHome();
/* Waiting. */
wait_ms(DELAY_1);
/* Getting the current position. */
int position = motors[0]->GetPosition();
/* Printing to the console. */
printf("--> Getting the current position: %d\r\n", position);
/* Waiting. */
wait_ms(DELAY_1);
/* Printing to the console. */
printf("--> Moving forward %d steps.\r\n", STEPS_1);
/* Moving. */
motors[0]->Move(StepperMotor::FWD, STEPS_1);
/* Waiting while active. */
motors[0]->WaitWhileActive();
/* Getting the current position. */
position = motors[0]->GetPosition();
/* Printing to the console. */
printf("--> Getting the current position: %d\r\n", position);
/* Printing to the console. */
printf("--> Marking the current position.\r\n");
/* Marking the current position. */
motors[0]->SetMark();
/* Waiting. */
wait_ms(DELAY_1);
/* Printing to the console. */
printf("--> Moving backward %d steps.\r\n", STEPS_2);
/* Moving. */
motors[0]->Move(StepperMotor::BWD, STEPS_2);
/* Waiting while active. */
motors[0]->WaitWhileActive();
/* Waiting. */
wait_ms(DELAY_1);
/* Getting the current position. */
position = motors[0]->GetPosition();
/* Printing to the console. */
printf("--> Getting the current position: %d\r\n", position);
/* Waiting. */
wait_ms(DELAY_1);
/* Printing to the console. */
printf("--> Going to marked position.\r\n");
/* Going to marked position. */
motors[0]->GoMark();
/* Waiting while active. */
motors[0]->WaitWhileActive();
/* Waiting. */
wait_ms(DELAY_1);
/* Getting the current position. */
position = motors[0]->GetPosition();
/* Printing to the console. */
printf("--> Getting the current position: %d\r\n", position);
/* Waiting. */
wait_ms(DELAY_1);
/* Printing to the console. */
printf("--> Going to home position.\r\n");
/* Going to home position. */
motors[0]->GoHome();
/* Waiting while active. */
motors[0]->WaitWhileActive();
/* Waiting. */
wait_ms(DELAY_1);
/* Getting the current position. */
position = motors[0]->GetPosition();
/* Printing to the console. */
printf("--> Getting the current position: %d\r\n", position);
/* Waiting. */
wait_ms(DELAY_2);
/*----- Running together for a certain amount of time. -----*/
/* Printing to the console. */
printf("--> Running together for %d seconds.\r\n", DELAY_3 / 1000);
/* Preparing each motor to perform a run at a specified speed. */
for (int m = 0; m < L6470DAISYCHAINSIZE; m++)
motors[m]->PrepareRun(StepperMotor::BWD, 400);
/* Performing the action on each motor at the same time. */
x_nucleo_ihm02a1->PerformPreparedActions();
/* Waiting. */
wait_ms(DELAY_3);
/*----- Increasing the speed while running. -----*/
/* Preparing each motor to perform a run at a specified speed. */
for (int m = 0; m < L6470DAISYCHAINSIZE; m++)
motors[m]->PrepareGetSpeed();
/* Performing the action on each motor at the same time. */
uint32_t* results = x_nucleo_ihm02a1->PerformPreparedActions();
/* Printing to the console. */
printf(" Speed: M1 %d, M2 %d.\r\n", results[0], results[1]);
/* Printing to the console. */
printf("--> Doublig the speed while running.\r\n");
/* Preparing each motor to perform a run at a specified speed. */
for (int m = 0; m < L6470DAISYCHAINSIZE; m++)
motors[m]->PrepareRun(StepperMotor::BWD, results[m] << 1);
/* Performing the action on each motor at the same time. */
results = x_nucleo_ihm02a1->PerformPreparedActions();
/* Waiting. */
wait_ms(DELAY_3);
/* Preparing each motor to perform a run at a specified speed. */
for (int m = 0; m < L6470DAISYCHAINSIZE; m++)
motors[m]->PrepareGetSpeed();
/* Performing the action on each motor at the same time. */
results = x_nucleo_ihm02a1->PerformPreparedActions();
/* Printing to the console. */
printf(" Speed: M1 %d, M2 %d.\r\n", results[0], results[1]);
/* Waiting. */
wait_ms(DELAY_1);
/*----- Hard Stop. -----*/
/* Printing to the console. */
printf("--> Hard Stop.\r\n");
/* Preparing each motor to perform a hard stop. */
for (int m = 0; m < L6470DAISYCHAINSIZE; m++)
motors[m]->PrepareHardStop();
/* Performing the action on each motor at the same time. */
x_nucleo_ihm02a1->PerformPreparedActions();
/* Waiting. */
wait_ms(DELAY_2);
/*----- Doing a full revolution on each motor, one after the other. -----*/
/* Printing to the console. */
printf("--> Doing a full revolution on each motor, one after the other.\r\n");
/* Doing a full revolution on each motor, one after the other. */
for (int m = 0; m < L6470DAISYCHAINSIZE; m++)
for (int i = 0; i < MPR_1; i++)
{
/* Computing the number of steps. */
int steps = (int) (((int) init[m].fullstepsperrevolution * pow(2.0f, init[m].step_sel)) / MPR_1);
/* Moving. */
motors[m]->Move(StepperMotor::FWD, steps);
/* Waiting while active. */
motors[m]->WaitWhileActive();
/* Waiting. */
wait_ms(DELAY_1);
}
/* Waiting. */
wait_ms(DELAY_2);
/*----- High Impedance State. -----*/
/* Printing to the console. */
printf("--> High Impedance State.\r\n");
/* Preparing each motor to set High Impedance State. */
for (int m = 0; m < L6470DAISYCHAINSIZE; m++)
motors[m]->PrepareHardHiZ();
/* Performing the action on each motor at the same time. */
x_nucleo_ihm02a1->PerformPreparedActions();
/* Waiting. */
wait_ms(DELAY_2);
}