MicroAPRS/bertos/drv/dc_motor.c

504 lines
13 KiB
C

/**
* \file
* <!--
* This file is part of BeRTOS.
*
* Bertos is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
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* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*
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* templates or use macros or inline functions from this file, or you compile
* this file and link it with other files to produce an executable, this
* file does not by itself cause the resulting executable to be covered by
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* invalidate any other reasons why the executable file might be covered by
* the GNU General Public License.
*
* Copyright 2008 Develer S.r.l. (http://www.develer.com/)
* -->
*
*
* \brief DC motor driver (implementation)
*
* Thi module provide a simple api to controll a DC motor in direction and
* speed, to allow this we use a Back-EMF technique.
* This technique is based, on the capability of the DC motor to become a generator
* of voltage when we turn off its supply. This happen every time we turn off the
* DC motor supply, and it continues to rotate for a short time thanks to its mechanical
* energy. Using this idea we can turn off the motor for a very short time, and
* we read the volage value from DC motor supply pins. This voltage say to us
* the actual speed of the motor.
*
* \author Daniele Basile <asterix@develer.com>
*/
#include "dc_motor.h"
#include "hw/hw_dc_motor.h"
#include "cfg/cfg_pwm.h"
// Define logging setting (for cfg/log.h module).
#define LOG_LEVEL DC_MOTOR_LOG_LEVEL
#define LOG_FORMAT DC_MOTOR_LOG_FORMAT
#include <cfg/log.h>
#include <cfg/debug.h>
#include <algo/pid_control.h>
#include <drv/timer.h>
#include <kern/proc.h>
#include <cpu/power.h>
#include <string.h>
#if CFG_PWM_ENABLE_OLD_API
#define PWM_ENABLE(dcm, en) pwm_enable((dcm)->cfg->pwm_dev, (en))
#define PWM_SETDUTY(dcm, duty) pwm_setDuty((dcm)->cfg->pwm_dev, (duty))
#define PWM_SETFREQ(dcm, freq) pwm_setFrequency((dcm)->cfg->pwm_dev, (freq))
#define PWM_SETPOL(dcm, pol) pwm_setPolarity((dcm)->cfg->pwm_dev, (pol))
#else
#define PWM_ENABLE(dcm, en) pwm_enable(&(dcm)->pwm, (en))
#define PWM_SETDUTY(dcm, duty) pwm_setDuty(&(dcm)->pwm, (duty))
#define PWM_SETFREQ(dcm, freq) pwm_setFrequency(&(dcm)->pwm, (freq))
#define PWM_SETPOL(dcm, pol) pwm_setPolarity(&(dcm)->pwm, (pol))
#endif
/**
* Define status bit for DC motor device.
*/
#define DC_MOTOR_ACTIVE BV(0) ///< DC motor enable or disable flag.
#define DC_MOTOR_DIR BV(1) ///< Spin direction of DC motor.
/*
* Some utility macro for motor directions
*/
#define POS_DIR 1
#define NEG_DIR 0
#define DC_MOTOR_POS_DIR(x) ((x) |= DC_MOTOR_DIR) // Set directions status positive
#define DC_MOTOR_NEG_DIR(x) ((x) &= ~DC_MOTOR_DIR) // Set directions status negative
// Update the status with current direction
#define DC_MOTOR_SET_STATUS_DIR(status, dir) \
(dir == POS_DIR ? DC_MOTOR_POS_DIR(status) : DC_MOTOR_NEG_DIR(status))
#if (CONFIG_KERN && CONFIG_KERN_PREEMPT)
#if CONFIG_DC_MOTOR_USE_SEM
#include <kern/sem.h>
Semaphore dc_motor_sem;
#define DC_MOTOR_LOCK sem_obtain(&dc_motor_sem)
#define DC_MOTOR_UNLOCK sem_release(&dc_motor_sem)
#else
#define DC_MOTOR_LOCK proc_forbid()
#define DC_MOTOR_UNLOCK proc_permit()
#endif
#else
#define DC_MOTOR_LOCK /* None */
#define DC_MOTOR_UNLOCK /* None */
#endif
/**
* DC motor definition.
*/
static DCMotor dcm_all[CONFIG_NUM_DC_MOTOR];
/*
* Process to poll dc motor status
*/
struct Process *dc_motor;
// Stack process for DC motor poll.
static PROC_DEFINE_STACK(dc_motor_poll_stack, 500);
// Only for Debug
LOG_INFOB(static int debug_msg_delay = 0;);
INLINE dc_speed_t dc_motor_readSpeed(int index)
{
DCMotor *dcm = &dcm_all[index];
return HW_DC_MOTOR_READ_VALUE(dcm->cfg->adc_ch, dcm->cfg->adc_min, dcm->cfg->adc_max);
}
/**
* Read the target speed from select device.
*/
dc_speed_t dc_motor_readTargetSpeed(int index)
{
DCMotor *dcm = &dcm_all[index];
return HW_DC_MOTOR_READ_VALUE(dcm->cfg->speed_dev_id, CONFIG_DC_MOTOR_MIN_SPEED, CONFIG_DC_MOTOR_MAX_SPEED);
}
static void dc_motor_start(int index)
{
DCMotor *dcm = &dcm_all[index];
DC_MOTOR_LOCK;
/*
* Clean all PID stutus variable, becouse
* we start with new one.
*/
pid_control_reset(&dcm->pid_ctx);
dcm->status |= DC_MOTOR_ACTIVE;
DC_MOTOR_UNLOCK;
}
/*
* There are two \a mode to stop the dc motor:
* - DC_MOTOR_DISABLE_MODE
* - DC_MOTOR_IDLE
*
* The DC_MOTOR_DISABLE_MODE shut down the DC motor and
* leave it floating to rotate.
* The DC_MOTOR_IDLE does not shut down DC motor, but put
* its supply pin in short circuite, in this way the motor result
* braked from intentional rotation.
*/
static void dc_motor_stop(int index)
{
DCMotor *dcm = &dcm_all[index];
DC_MOTOR_LOCK;
dcm->status &= ~DC_MOTOR_ACTIVE;
dcm->expire_time = DC_MOTOR_NO_EXPIRE;
PWM_ENABLE(dcm, false);
if (dcm->cfg->braked)
{
DC_MOTOR_STOP_BRAKED(dcm->index);
}
else
{
DC_MOTOR_STOP_FLOAT(dcm->index);
}
DC_MOTOR_UNLOCK;
}
/*
* Sampling a signal on DC motor and compute
* a new value of speed according with PID control.
*/
static void dc_motor_do(int index)
{
DCMotor *dcm = &dcm_all[index];
dc_speed_t curr_pos = 0;
pwm_duty_t new_pid = 0;
DC_MOTOR_LOCK;
//If select DC motor is not active we return
if (!(dcm->status & DC_MOTOR_ACTIVE))
{
DC_MOTOR_UNLOCK;
return;
}
/*
* To set dc motor direction we must also set the
* PWM polarity according with dc motor driver chip
*/
PWM_SETPOL(dcm, dcm->status & DC_MOTOR_DIR);
DC_MOTOR_SET_DIR(dcm->index, dcm->status & DC_MOTOR_DIR);
//Compute next value for reaching target speed from current position
if (dcm->cfg->pid_enable)
{
/*
* Here we cannot disable the switch context because the
* driver, that read the speed could be need to use signal or
* other thing that needs the kernel switch context, for this
* reason we unlock before to read the speed.
*/
DC_MOTOR_UNLOCK;
curr_pos = dc_motor_readSpeed(index);
DC_MOTOR_LOCK;
new_pid = pid_control_update(&dcm->pid_ctx, dcm->tgt_speed, curr_pos);
}
else
{
new_pid = dcm->tgt_speed;
}
LOG_INFOB(
if (debug_msg_delay == 20)
{
LOG_INFO("DC Motor[%d]: curr_speed[%d],curr_pos[%d],tgt[%d]\n", dcm->index,
curr_pos, new_pid, dcm->tgt_speed);
debug_msg_delay = 0;
}
debug_msg_delay++;
);
//Apply the compute duty value
PWM_SETDUTY(dcm, new_pid);
//Restart dc motor
PWM_ENABLE(dcm, true);
DC_MOTOR_ENABLE(dcm->index);
DC_MOTOR_UNLOCK;
}
/*
* Check if the DC motor run time is expired, if this happend
* we turn off motor and reset status.
*/
INLINE bool check_timerIsExpired(int index)
{
DC_MOTOR_LOCK;
bool check = ((dcm_all[index].expire_time - timer_clock()) < 0) &&
(dcm_all[index].expire_time != DC_MOTOR_NO_EXPIRE);
DC_MOTOR_UNLOCK;
return check;
}
/**
* Process to poll DC motor status.
* To use a Back-EMF technique (see brief for more details),
* we turn off a motor for CONFIG_DC_MOTOR_SAMPLE_DELAY, that value are stored
* in each DC motor config. For this implementation we assume
* that have a common CONFIG_DC_MOTOR_SAMPLE_DELAY, choose among a max delay
* to all DC motor configuration.
* The DC motor off time is choose to allow the out signal to
* be stable, so we can read and process this value for feedback controll loop.
* The period (CONFIG_DC_MOTOR_SAMPLE_PERIOD - CONFIG_DC_MOTOR_SAMPLE_DELAY)
* that every time we turn off a DC motor is choose to have a feedback controll
* more responsive or less responsive.
*/
static void NORETURN dc_motor_poll(void)
{
for (;;)
{
/*
* For all DC motor we read and process output singal,
* and choose the max value to off time
*/
for (int i = 0; i < CONFIG_NUM_DC_MOTOR; i++)
{
if (!dcm_all[i].cfg)
continue;
if (check_timerIsExpired(i))
dc_motor_stop(i);
else
dc_motor_do(i);
/*
* If we read speed from trimmer we update the target
* speed value when motor is running so we can make
* dc motor speed regulation.
*/
if (dcm_all[i].cfg->speed_dev_id != DC_MOTOR_NO_DEV_SPEED)
dc_motor_setSpeed(i, dc_motor_readTargetSpeed(i));
}
//Wait for next sampling
timer_delay(CONFIG_DC_MOTOR_SAMPLE_PERIOD - CONFIG_DC_MOTOR_SAMPLE_DELAY);
for (int i = 0; i < CONFIG_NUM_DC_MOTOR; i++)
{
if (!dcm_all[i].cfg)
continue;
if (check_timerIsExpired(i))
dc_motor_stop(i);
DC_MOTOR_LOCK;
if (dcm_all[i].status & DC_MOTOR_ACTIVE)
{
DC_MOTOR_DISABLE(dcm_all[i].index);
PWM_ENABLE(&dcm_all[i], false);
}
DC_MOTOR_UNLOCK;
}
//Wait some time to allow signal to stabilize before sampling
timer_delay(CONFIG_DC_MOTOR_SAMPLE_DELAY);
}
}
/**
* Set spin direction of DC motor.
*
* \a index number of DC motor
* \a dir direction of DC motor
*/
void dc_motor_setDir(int index, bool dir)
{
DCMotor *dcm = &dcm_all[index];
DC_MOTOR_LOCK;
DC_MOTOR_SET_STATUS_DIR(dcm->status, dir);
DC_MOTOR_UNLOCK;
}
/**
* Set DC motor speed.
*/
void dc_motor_setSpeed(int index, dc_speed_t speed)
{
DCMotor *dcm = &dcm_all[index];
DC_MOTOR_LOCK;
dcm->tgt_speed = speed;
DC_MOTOR_UNLOCK;
LOG_INFO("DC Motor[%d]: tgt_speed[%d]\n", index, dcm->tgt_speed);
}
/**
* Set among of time that dc motor should run.
*/
void dc_motor_startTimer(int index, mtime_t on_time)
{
DC_MOTOR_LOCK;
dcm_all[index].expire_time = DC_MOTOR_NO_EXPIRE;
if (on_time != DC_MOTOR_NO_EXPIRE)
{
dcm_all[index].expire_time = timer_clock() + ms_to_ticks(on_time);
dc_motor_start(index);
}
DC_MOTOR_UNLOCK;
}
void dc_motor_waitStop(int index)
{
DCMotor *dcm = &dcm_all[index];
bool loop = true;
while (loop)
{
DC_MOTOR_LOCK;
loop = dcm->status & DC_MOTOR_ACTIVE;
DC_MOTOR_UNLOCK;
cpu_relax();
}
}
/**
* Enable or disable dc motor.
*/
void dc_motor_enable(int index, bool state)
{
if (state)
dc_motor_start(index);
else
dc_motor_stop(index);
}
/**
* Apply a confinguration to select DC motor.
*/
void dc_motor_setup(int index, DCMotorConfig *dcm_conf)
{
DCMotor *dcm = &dcm_all[index];
DC_MOTOR_LOCK;
/*
* We are using the same sample period for each
* motor, and so we check if this value is the same
* for all. The sample period time is defined in pid
* configuration.
*
* TODO: Use a different sample period for each motor
* and refactor a module to allow to use a timer interrupt,
* in this way we can controll a DC motor also without a
* kernel, increasing a portability on other target.
*/
pid_control_setPeriod(&dcm_conf->pid_cfg, CONFIG_DC_MOTOR_SAMPLE_PERIOD);
//Init pid control
pid_control_init(&dcm->pid_ctx, &dcm_conf->pid_cfg);
dcm->cfg = dcm_conf;
/*
* Apply config value.
*/
dcm->index = index;
/*
* By default the motor run forever..
*/
dcm->expire_time = DC_MOTOR_NO_EXPIRE;
/*
* By default set target speed.
*/
dcm->tgt_speed = dcm_conf->speed;
/*
* Clear the status.
*/
dcm->status = 0;
#if !CFG_PWM_ENABLE_OLD_API
pwm_init(&dcm->pwm, dcm_conf->pwm_dev);
#endif
PWM_SETFREQ(dcm, dcm->cfg->freq);
PWM_ENABLE(dcm, false);
//Set default direction for DC motor
DC_MOTOR_SET_DIR(dcm->index, dcm->cfg->dir);
DC_MOTOR_SET_STATUS_DIR(dcm->status, dcm->cfg->dir);
DC_MOTOR_UNLOCK;
LOG_INFO("DC motor[%d]:\n", dcm->index);
LOG_INFO("> PID: kp[%f],ki[%f],kd[%f]\n", dcm->cfg->pid_cfg.kp, dcm->cfg->pid_cfg.ki, dcm->cfg->pid_cfg.kd);
LOG_INFO("> PWM: pwm_dev[%d], freq[%ld], sample[%d]\n", dcm->cfg->pwm_dev, dcm->cfg->freq,CONFIG_DC_MOTOR_SAMPLE_DELAY);
LOG_INFO("> ADC: adc_ch[%d], adc_max[%d], adc_min[%d]\n", dcm->cfg->adc_ch, dcm->cfg->adc_max, dcm->cfg->adc_min);
LOG_INFO("> DC: dir[%d], speed[%d]\n", dcm->cfg->dir, dcm->cfg->speed);
}
/**
* If we had enabled the priority scheduling, we can adjust the
* DC motor poll process priority.
*/
void dc_motor_setPriority(int priority)
{
ASSERT(CONFIG_KERN);
ASSERT(dc_motor);
proc_setPri(dc_motor, priority);
}
/**
* Init DC motor.
* \a priority: sets the dc motor process priority.
*/
void dc_motor_init(void)
{
ASSERT(CONFIG_KERN);
MOTOR_DC_INIT();
#if (CONFIG_KERN_PREEMPT && CONFIG_DC_MOTOR_USE_SEM)
sem_init(&dc_motor_sem);
#endif
//Create a dc motor poll process
dc_motor = proc_new_with_name("DC_Motor", dc_motor_poll, NULL, sizeof(dc_motor_poll_stack), dc_motor_poll_stack);
}