Esempio n. 1
0
void pwm_update(uint16_t position, int32_t pwm)
// Update the PWM signal being sent to the motor.  The PWM value should be
// a signed integer in the range of -65535 to -1 for clockwise movement,
// 1 to 65535 for counter-clockwise movement or zero to stop all movement.
// This function provides a sanity check against the servo position and
// will prevent the servo from being driven past a minimum and maximum
// position.
{
    uint16_t pwm_width;


    // Determine if PWM is disabled in the registers.
    if (!(registers_read_byte(REG_FLAGS_LO) & (1<<FLAGS_LO_PWM_ENABLED))) pwm = 0;

    // Determine direction of servo movement or stop.
    if (pwm < 0)
    {
        // Less than zero. Turn clockwise.

        // Get the PWM width from the PWM value.
        pwm_width = (uint16_t) -pwm;

        // Turn clockwise.
#if SWAP_PWM_DIRECTION_ENABLED
        pwm_dir_a(pwm_width);
#else
        pwm_dir_b(pwm_width);
#endif
    }
    else if (pwm > 0)
    {
        // More than zero. Turn counter-clockwise.

        // Get the PWM width from the PWM value.
        pwm_width = (uint16_t) pwm;

        // Turn counter-clockwise.
#if SWAP_PWM_DIRECTION_ENABLED
        pwm_dir_b(pwm_width);
#else
        pwm_dir_a(pwm_width);
#endif

    }
    else
    {
        // Stop all PWM activity to the motor.
        pwm_stop();
    }
}
Esempio n. 2
0
void pwm_update(uint16_t position, int16_t pwm)
// Update the PWM signal being sent to the motor.  The PWM value should be
// a signed integer in the range of -255 to -1 for clockwise movement,
// 1 to 255 for counter-clockwise movement or zero to stop all movement.
// This function provides a sanity check against the servo position and
// will prevent the servo from being driven past a minimum and maximum
// position.
{
    uint8_t pwm_width;
    uint16_t min_position;
    uint16_t max_position;

    // Quick check to see if the frequency divider changed.  If so we need to
    // configure a new top value for timer/counter1.  This value should only
    // change infrequently so we aren't too elegant in how we handle updating
    // the value.  However, we need to be careful that we don't configure the
    // top to a value lower than the counter and compare values.
    if (registers_read_word(REG_PWM_FREQ_DIVIDER_HI, REG_PWM_FREQ_DIVIDER_LO) != pwm_div)
    {
        // Hold EN_A (PD2) and EN_B (PD3) low.
        PORTD &= ~((1<<PD2) | (1<<PD3));

        // Give the H-bridge time to respond to the above, failure to do so or to wait long
        // enough will result in brownouts as the power is "crowbarred" to varying extents.
        // The delay required is also dependant on factors which may affect the speed with
        // which the MOSFETs can respond, such as the impedance of the motor, the supply
        // voltage, etc.
        //
        // Experiments (with an "MG995") have shown that 5microseconds should be sufficient
        // for most purposes.
        //
        delay_loop(DELAYLOOP);

        // Disable OC1A and OC1B outputs.
        TCCR1A &= ~((1<<COM1A1) | (1<<COM1A0));
        TCCR1A &= ~((1<<COM1B1) | (1<<COM1B0));

        // Make sure that PWM_A (PB1/OC1A) and PWM_B (PB2/OC1B) are held low.
        PORTB &= ~((1<<PB1) | (1<<PB2));

        // Reset the A and B direction flags.
        pwm_a = 0;
        pwm_b = 0;

        // Update the pwm frequency divider value.
        pwm_div = registers_read_word(REG_PWM_FREQ_DIVIDER_HI, REG_PWM_FREQ_DIVIDER_LO);

        // Update the timer top value.
        ICR1 = PWM_TOP_VALUE(pwm_div);

        // Reset the counter and compare values to prevent problems with the new top value.
        TCNT1 = 0;
        OCR1A = 0;
        OCR1B = 0;
    }

    // Are we reversing the seek sense?
    if (registers_read_byte(REG_REVERSE_SEEK) != 0)
    {
        // Yes. Swap the minimum and maximum position.

        // Get the minimum and maximum seek position.
        min_position = registers_read_word(REG_MAX_SEEK_HI, REG_MAX_SEEK_LO);
        max_position = registers_read_word(REG_MIN_SEEK_HI, REG_MIN_SEEK_LO);

        // Make sure these values are sane 10-bit values.
        if (min_position > MAX_POSITION) min_position = MAX_POSITION;
        if (max_position > MAX_POSITION) max_position = MAX_POSITION;

        // Adjust the values because of the reverse sense.
        min_position = MAX_POSITION - min_position;
        max_position = MAX_POSITION - max_position;
    }
    else
    {
        // No. Use the minimum and maximum position as is.

        // Get the minimum and maximum seek position.
        min_position = registers_read_word(REG_MIN_SEEK_HI, REG_MIN_SEEK_LO);
        max_position = registers_read_word(REG_MAX_SEEK_HI, REG_MAX_SEEK_LO);

        // Make sure these values are sane 10-bit values.
        if (min_position > MAX_POSITION) min_position = MAX_POSITION;
        if (max_position > MAX_POSITION) max_position = MAX_POSITION;
    }

    // Disable clockwise movements when position is below the minimum position.
    if ((position < min_position) && (pwm < 0)) pwm = 0;

    // Disable counter-clockwise movements when position is above the maximum position.
    if ((position > max_position) && (pwm > 0)) pwm = 0;

    // Determine if PWM is disabled in the registers.
    if (!(registers_read_byte(REG_FLAGS_LO) & (1<<FLAGS_LO_PWM_ENABLED))) pwm = 0;

    // Determine direction of servo movement or stop.
    if (pwm < 0)
    {
        // Less than zero. Turn clockwise.

        // Get the PWM width from the PWM value.
        pwm_width = (uint8_t) -pwm;

        // Turn clockwise.
#if SWAP_PWM_DIRECTION_ENABLED
        pwm_dir_b(pwm_width);
#else
        pwm_dir_a(pwm_width);
#endif
    }
    else if (pwm > 0)
    {
        // More than zero. Turn counter-clockwise.

        // Get the PWM width from the PWM value.
        pwm_width = (uint8_t) pwm;

        // Turn counter-clockwise.
#if SWAP_PWM_DIRECTION_ENABLED
        pwm_dir_a(pwm_width);
#else
        pwm_dir_b(pwm_width);
#endif

    }
    else
    {
        // Stop all PWM activity to the motor.
        pwm_stop();
    }
}
Esempio n. 3
0
void pwm_update(uint16_t position, int16_t pwm)
// Update the PWM signal being sent to the motor.  The PWM value should be
// a signed integer in the range of -255 to -1 for clockwise movement,
// 1 to 255 for counter-clockwise movement or zero to stop all movement.
// This function provides a sanity check against the servo position and
// will prevent the servo from being driven past a minimum and maximum
// position.
{
    uint8_t pwm_width;
    uint16_t min_position;
    uint16_t max_position;

    // Quick check to see if the frequency divider changed.  If so we need to 
    // configure a new top value for timer/counter1.  This value should only 
    // change infrequently so we aren't too elegant in how we handle updating
    // the value.  However, we need to be careful that we don't configure the
    // top to a value lower than the counter and compare values.
    if (registers_read_word(REG_PWM_FREQ_DIVIDER_HI, REG_PWM_FREQ_DIVIDER_LO) != pwm_div)
    {
        // Disable OC1A and OC1B outputs.
        TCCR1A &= ~((1<<COM1A1) | (1<<COM1A0));
        TCCR1A &= ~((1<<COM1B1) | (1<<COM1B0));

        // Clear PB1 and PB2.
        PORTB &= ~((1<<PB1) | (1<<PB2));

        delay_loop(DELAYLOOP);

        // Reset the A and B direction flags.
        pwm_a = 0;
        pwm_b = 0;

        // Update the pwm frequency divider value.
        pwm_div = registers_read_word(REG_PWM_FREQ_DIVIDER_HI, REG_PWM_FREQ_DIVIDER_LO);

        // Update the timer top value.
        ICR1 = PWM_TOP_VALUE(pwm_div);

        // Reset the counter and compare values to prevent problems with the new top value.
        TCNT1 = 0;
        OCR1A = 0;
        OCR1B = 0;
    }

    // Are we reversing the seek sense?
    if (registers_read_byte(REG_REVERSE_SEEK) != 0)
    {
        // Yes. Swap the minimum and maximum position.

        // Get the minimum and maximum seek position.
        min_position = registers_read_word(REG_MAX_SEEK_HI, REG_MAX_SEEK_LO);
        max_position = registers_read_word(REG_MIN_SEEK_HI, REG_MIN_SEEK_LO);

        // Make sure these values are sane 10-bit values.
        if (min_position > 0x3ff) min_position = 0x3ff;
        if (max_position > 0x3ff) max_position = 0x3ff;

        // Adjust the values because of the reverse sense.
        min_position = 0x3ff - min_position;
        max_position = 0x3ff - max_position;
    }
    else
    {
        // No. Use the minimum and maximum position as is.

        // Get the minimum and maximum seek position.
        min_position = registers_read_word(REG_MIN_SEEK_HI, REG_MIN_SEEK_LO);
        max_position = registers_read_word(REG_MAX_SEEK_HI, REG_MAX_SEEK_LO);

        // Make sure these values are sane 10-bit values.
        if (min_position > 0x3ff) min_position = 0x3ff;
        if (max_position > 0x3ff) max_position = 0x3ff;
    }

    // Disable clockwise movements when position is below the minimum position.
    if ((position < min_position) && (pwm < 0)) pwm = 0;

    // Disable counter-clockwise movements when position is above the maximum position.
    if ((position > max_position) && (pwm > 0)) pwm = 0;

    // Determine if PWM is disabled in the registers.
    if (!(registers_read_byte(REG_FLAGS_LO) & (1<<FLAGS_LO_PWM_ENABLED))) pwm = 0;

    // Determine direction of servo movement or stop.
    if (pwm < 0)
    {
        // Less than zero. Turn clockwise.

        // Get the PWM width from the PWM value.
        pwm_width = (uint8_t) -pwm;

        // Turn clockwise.
#if SWAP_PWM_DIRECTION_ENABLED
        pwm_dir_a(pwm_width);
#else
        pwm_dir_b(pwm_width);
#endif
    }
    else if (pwm > 0)
    {
        // More than zero. Turn counter-clockwise.

        // Get the PWM width from the PWM value.
        pwm_width = (uint8_t) pwm;

        // Turn counter-clockwise.
#if SWAP_PWM_DIRECTION_ENABLED
        pwm_dir_b(pwm_width);
#else
        pwm_dir_a(pwm_width);
#endif

    }
    else
    {
        // Stop all PWM activity to the motor.
        pwm_stop();
    }
}