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//
// motor.cc
//
#include "motors.h"
#include "config.h"
#include <Arduino.h>
#include <limits.h>
static int channels_[ NUM_MOTORS ];
void Motors::setup()
{
// setup outputs
for( int pin = FIRST_PIN; pin < FIRST_PIN + NUM_MOTORS; pin++ ) {
pinMode( pin, OUTPUT );
digitalWrite( pin, LOW );
}
// reset channel values
for( int a = 0; a < NUM_MOTORS; a++ )
channels_[ a ] = 0;
}
void Motors::set_values( int channel_values[] )
{
for( int a = 0; a < NUM_MOTORS; a++ )
channels_[ a ] = channel_values[ a ];
}
void Motors::update()
{
static int event = NUM_MOTORS * 2;
unsigned long now = micros();
static unsigned long frame_start = now - FRAME_DURATION;
static unsigned long next_event_at = 0;
if( now >= next_event_at )
{
// action event
if( event < NUM_MOTORS * 2 )
digitalWrite( FIRST_PIN + ( event / 2 ),
( event & 1 )? LOW : HIGH );
// move to next event
if( ++event >= NUM_MOTORS * 2 ) {
event = 0;
frame_start += FRAME_DURATION;
}
// calculate the time that the next event will occur
next_event_at = frame_start + ( event / 2 ) * CHANNEL_INTERVAL;
if( event & 1 )
next_event_at += MIN_PULSE_WIDTH + channels_[ event / 2 ] *
( MAX_PULSE_WIDTH - MIN_PULSE_WIDTH ) / MAX_CHANNEL_VALUE;
// Serial.print( event / 2 );
// Serial.print( ( event & 1 )? 'v' : '^' );
// Serial.print( " " );
// Serial.println( next_event_at );
// if( event == 1 ) {
// unsigned long width = MIN_PULSE_WIDTH +
// (unsigned long)channels_[ event / 2 ] *
// ( MAX_PULSE_WIDTH - MIN_PULSE_WIDTH ) / MAX_CHANNEL_VALUE;
// Serial.print( channels_[ event / 2 ] );
// Serial.print( " " );
// Serial.println( width );
// }
}
}
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