ardupilot/Tools/PPMEncoder/ap_ppm_encoder.c

1287 lines
47 KiB
C
Raw Normal View History

2011-09-09 05:57:09 -03:00
/*********************************************************************************************************
Title : C file for the rc ppm encoder (servo2ppm_v4_2.c)
Author: Chris Efstathiou
E-mail: hendrix at vivodinet dot gr
Homepage: ........................
Date: 3/Aug/2009
Compiler: AVR-GCC with AVR-AS
MCU type: ATmega168
Comments: This software is FREE. Use it at your own risk.
*********************************************************************************************************/
/********************************************************************************************************/
/* PREPROCESSOR DIRECTIVES */
/********************************************************************************************************/
#include <avr/io.h>
#include <avr/interrupt.h>
#include <avr/wdt.h>
#include <avr/eeprom.h>
#include <inttypes.h>
#include "servo2ppm_settings.h"
/********************************************************************************************************/
/* Normaly you shouldn't need to change anything below this line but who knows? */
/********************************************************************************************************/
#define RC_SERVO_PORT D /* The port for the servo pulse input. */
#define RC_LED_PORT B /* The port for the PPM waveform and the led. */
#define RC_LED_PIN 0 /* The led indicator pin. */
#define RC_PPM_PORT B
#define RC_PPM_PIN 2 /* The PPM waveform output pin */
#define RC_MUX_PORT B /* The port for the MUX controller. */
#define RC_MUX_PIN 1 /* The pin to control the MUX. */
#define RC_SETUP_PORT B
#define RC_SETUP_PIN 4
#define RC_TIMER0_TIMSK TIMSK0 /* Timer0 registers */
#define RC_TIMER0_TIFR TIFR0
#define RC_TIMER0_PRESCALER_REG TCCR0B
#define RC_TIMER1_TIMSK TIMSK1 /* Timer1 registers */
#define RC_TIMER1_TIFR TIFR1
#define RC_TIMER1_PRESCALER_REG TCCR1B
#define RC_TIMER1_MODE_REG TCCR1A
#define RC_TIMER1_COMP1_REG OCR1A
#define RC_TIMER1_COMP2_REG OCR1B
#define RC_PIN_INT_EN_REG PCICR
#define RC_PIN_INT_EN_BIT PCIE2
#define RC_PIN_INT_FLAG_REG PCIFR
#define RC_PIN_INT_FLAG_BIT PCIF2
#define RC_PIN_INT_MASK_REG PCMSK2
#define RC_SERVO_INPUT_CHANNELS 8
/*
You can copy the above avr type data and edit them as needed if you plan to use
a different avr type cpu having at least 2k bytes of flash memory.
*/
#define _CONCAT2_(a, b) a ## b
#define CONCAT2(a, b) _CONCAT2_(a, b)
#define RC_SERVO_PORT_OUT_REG CONCAT2(PORT, RC_SERVO_PORT)
#define RC_SERVO_PORT_DDR_REG CONCAT2(DDR, RC_SERVO_PORT)
#define RC_SERVO_PORT_PIN_REG CONCAT2(PIN, RC_SERVO_PORT)
#define RC_LED_PORT_OUT_REG CONCAT2(PORT, RC_LED_PORT)
#define RC_LED_PORT_DDR_REG CONCAT2(DDR, RC_LED_PORT)
#define RC_LED_PORT_PIN_REG CONCAT2(PIN, RC_LED_PORT)
#define RC_MUX_PORT_OUT_REG CONCAT2(PORT, RC_MUX_PORT)
#define RC_MUX_PORT_DDR_REG CONCAT2(DDR, RC_MUX_PORT)
#define RC_MUX_PORT_PIN_REG CONCAT2(PIN, RC_MUX_PORT)
#define RC_PPM_PORT_OUT_REG CONCAT2(PORT, RC_PPM_PORT)
#define RC_PPM_PORT_DDR_REG CONCAT2(DDR, RC_PPM_PORT)
#define RC_PPM_PORT_PIN_REG CONCAT2(PIN, RC_PPM_PORT)
#define RC_SETUP_PORT_OUT_REG CONCAT2(PORT, RC_SETUP_PORT)
#define RC_SETUP_DDR_REG CONCAT2(DDR, RC_SETUP_PORT)
#define RC_SETUP_PIN_REG CONCAT2(PIN, RC_SETUP_PORT)
#if RC_PPM_GEN_CHANNELS > 8
#error PPM generator max number of channels is 8
#endif
#if RC_PPM_GEN_CHANNELS == 0
#error PPM generator channels cannot be zero!
#endif
#if RC_PPM_GEN_CHANNELS < RC_SERVO_INPUT_CHANNELS
#undef RC_SERVO_INPUT_CHANNELS
#define RC_SERVO_INPUT_CHANNELS RC_PPM_GEN_CHANNELS
#warning servo channels = PPM generator channels
#endif
#if RC_PPM_RESET_PW == 0 && RC_PPM_FRAME_LENGTH_MS == 0
#undef RC_PPM_FRAME_LENGTH_MS
#undef RC_PPM_RESET_PW
#define RC_PPM_RESET_PW (23500UL - (8 * RC_SERVO_CENTER_PW))
#define RC_PPM_FRAME_LENGTH_MS (RC_PPM_RESET_PW + (RC_PPM_GEN_CHANNELS * RC_SERVO_CENTER_PW))
#elif RC_PPM_FRAME_LENGTH_MS == 0 && RC_PPM_RESET_PW > 0
#undef RC_PPM_FRAME_LENGTH_MS
#define RC_PPM_FRAME_LENGTH_MS ((RC_PPM_GEN_CHANNELS * RC_SERVO_CENTER_PW)+RC_PPM_RESET_PW)
#elif RC_PPM_FRAME_LENGTH_MS > 0 && RC_PPM_RESET_PW == 0
#undef RC_PPM_RESET_PW
#define RC_PPM_RESET_PW (RC_PPM_FRAME_LENGTH_MS -(RC_PPM_GEN_CHANNELS * RC_SERVO_CENTER_PW))
#endif
#if RC_PPM_FRAME_LENGTH_MS > 25000UL
#warning PPM frame period exceeds 25ms
#endif
#if RC_PPM_RESET_PW <= (5000UL + RC_PPM_CHANNEL_SYNC_PW)
#warning PPM reset period lower than 5ms
#endif
/* Search for a suitable timer prescaler. Both timers must use the same prescaling factor. */
#if ((F_CPU * (RC_MAX_TIMEOUT/1000))/1000) < 0xFFF0
#define TIMER0_PRESCALER 1
#define TIMER0_PRESCALER_BITS ((0<<CS02)|(0<<CS01)|(1<<CS00))
#warning TIMER0 PRESCALER SET TO 1
#elif (((F_CPU * (RC_PPM_FRAME_TIMEOUT/1000))/1000)/8) < 0xFFF0
#define TIMER0_PRESCALER 8
#define TIMER0_PRESCALER_BITS ((0<<CS02)|(1<<CS01)|(0<<CS00))
#warning TIMER0 PRESCALER SET TO 8
#elif (((F_CPU * (RC_PPM_FRAME_TIMEOUT/1000))/1000)/64) < 0xFFF0
#define TIMER0_PRESCALER 64
#define TIMER0_PRESCALER_BITS ((0<<CS02)|(1<<CS01)|(1<<CS00))
#warning TIMER0 PRESCALER SET TO 64
#endif
#define TIMER1_PRESCALER TIMER0_PRESCALER
#if TIMER1_PRESCALER == 1
#define TIMER1_PRESCALER_BITS ((0<<CS12)|(0<<CS11)|(1<<CS10))
#warning TIMER1 PRESCALER SET TO 1
#elif TIMER1_PRESCALER == 8
#define TIMER1_PRESCALER_BITS ((0<<CS12)|(1<<CS11)|(0<<CS10))
#warning TIMER1 PRESCALER SET TO 8
#elif TIMER1_PRESCALER == 64
#define TIMER1_PRESCALER_BITS ((0<<CS12)|(1<<CS11)|(1<<CS10))
#warning TIMER1 PRESCALER SET TO 64
#else
#error NO SUITABLE PRESCALER FOR TIMER1 FOUND!
#endif
/* Now that the timer prescalers are known the conversion of microseconds to timer values follows */
#define RC_SERVO_CENTER_PW_VAL ((((F_CPU/1000) * RC_SERVO_CENTER_PW )/1000)/TIMER0_PRESCALER)
#define RC_SERVO_MIN_PW_VAL ((((F_CPU/1000) * RC_SERVO_MIN_PW)/1000)/TIMER0_PRESCALER)
#define RC_SERVO_MAX_PW_VAL ((((F_CPU/1000) * RC_SERVO_MAX_PW)/1000)/TIMER0_PRESCALER)
#define RC_PPM_FRAME_TIMER_VAL ((((F_CPU/1000) * RC_PPM_FRAME_LENGTH_MS)/1000)/TIMER1_PRESCALER)
#define RC_PPM_SYNC_PW_VAL ((((F_CPU/1000) * RC_PPM_CHANNEL_SYNC_PW)/1000)/TIMER1_PRESCALER)
#define RC_PPM_OFF_THRESHOLD_VAL ((((F_CPU/1000) * RC_LOST_THRESHOLD)/1000)/TIMER1_PRESCALER)
#define RC_PPM_OFF_UPPER_WINDOW_VAL ((((F_CPU/1000) * 1700)/1000)/TIMER1_PRESCALER) //1700 microseconds
#define RC_PPM_OFF_LOWER_WINDOW_VAL ((((F_CPU/1000) * 1300)/1000)/TIMER1_PRESCALER) //1300 microseconds
#define RC_PPM_OFF_OFFSET_VAL ((((F_CPU/1000) * RC_THROTTLE_CH_OFFSET_PW)/1000)/TIMER1_PRESCALER)
#define RC_MAX_TIMEOUT_VAL ((((((F_CPU/1000) * RC_MAX_TIMEOUT)/1000)/TIMER0_PRESCALER)/256)+1)
#define RC_PULSE_TIMEOUT_VAL ((((((F_CPU/1000) * RC_SERVO_MAX_PW)/1000)/TIMER0_PRESCALER)/256)+1)
#define RC_FS_CH_1_TIMER_VAL ((((F_CPU/1000) * RC_FAILSAFE_CHANNEL_1)/1000)/TIMER0_PRESCALER)
#define RC_FS_CH_2_TIMER_VAL ((((F_CPU/1000) * RC_FAILSAFE_CHANNEL_2)/1000)/TIMER0_PRESCALER)
#define RC_FS_CH_3_TIMER_VAL ((((F_CPU/1000) * RC_FAILSAFE_CHANNEL_3)/1000)/TIMER0_PRESCALER)
#define RC_FS_CH_4_TIMER_VAL ((((F_CPU/1000) * RC_FAILSAFE_CHANNEL_4)/1000)/TIMER0_PRESCALER)
#define RC_FS_CH_5_TIMER_VAL ((((F_CPU/1000) * RC_FAILSAFE_CHANNEL_5)/1000)/TIMER0_PRESCALER)
#define RC_FS_CH_6_TIMER_VAL ((((F_CPU/1000) * RC_FAILSAFE_CHANNEL_6)/1000)/TIMER0_PRESCALER)
#define RC_FS_CH_7_TIMER_VAL ((((F_CPU/1000) * RC_FAILSAFE_CHANNEL_7)/1000)/TIMER0_PRESCALER)
#define RC_FS_CH_8_TIMER_VAL ((((F_CPU/1000) * RC_FAILSAFE_CHANNEL_8)/1000)/TIMER0_PRESCALER)
#define RC_RESET_PW_TIMER_VAL ((((F_CPU/1000) * RC_PPM_RESET_PW)/1000)/TIMER1_PRESCALER)
#define RC_MUX_TIMER_VAL ((((F_CPU/1000) * 1500)/1000)/TIMER0_PRESCALER)
//#define RC_TIMER0_VAL_CORRECTION ((RC_SERVO_CENTER_PW_VAL *100)/RC_SERVO_CENTER_PW )
/* Some error checking */
/* The timer can only count up to 65535 so the high byte can go up to 255 */
#if (RC_MAX_TIMEOUT_VAL > 255)
#error RC_MAX_TIMEOUT is set too high!
#endif
#define RC_LED_FREQUENCY_VAL (((1000000/RC_LED_FREQUENCY)/23500)/2) //each frame is 23,5 ms
#if RC_LED_FREQUENCY_VAL <= 0
#undef RC_LED_FREQUENCY_VAL
#define RC_LED_FREQUENCY_VAL 1
#warning LED FREQUENCY set to maximum
#endif
//It is used when there is no servo signals received so the elapsed time is always RC_MAX_TIMEOUT ms.
#define RC_LED_FREQUENCY_VAL_1HZ (((1000000/1)/RC_MAX_TIMEOUT)/2)
/* Macro command definitions. */
#define LED_ON() { RC_LED_PORT_OUT_REG |= (1<<RC_LED_PIN); }
#define LED_OFF() { RC_LED_PORT_OUT_REG &= (~(1<<RC_LED_PIN)); }
#define TOGGLE_LED() { RC_LED_PORT_OUT_REG ^= (1<<RC_LED_PIN); }
#define MUX_ON() { RC_MUX_PORT_OUT_REG |= (1<<RC_MUX_PIN); }
#define MUX_OFF() { RC_MUX_PORT_OUT_REG &= (~(1<<RC_MUX_PIN)); }
#define STOP_TIMER0() { RC_TIMER0_PRESCALER_REG = 0; }
#define START_TIMER0() { RC_TIMER0_PRESCALER_REG = TIMER0_PRESCALER_BITS; }
#define RESET_TIMER0() { RC_TIMER0_TIFR |= (1<<TOIE0); TCNT0=0; timer0.timer0[1]=0; }
#define RESET_START_TIMER0() { STOP_TIMER0(); RESET_TIMER0(); START_TIMER0(); }
#if RC_USE_FAILSAFE > 1
#error RC_USE_FAILSAFE can be 0 or 1
#endif
#if RC_PPM_OUTPUT_TYPE > 1
#error RC_PPM_OUTPUT_TYPE can be 0 or 1
#endif
#if RC_CONSTANT_PPM_FRAME_TIME > 1
#error RC_CONSTANT_PPM_FRAME_TIME can be 0 or 1
#endif
#if RC_REDUCE_LATENCY > 1
#error RC_REDUCE_LATENCY can be 0 or 1
#endif
/********************************************************************************************************/
/* TYPE DEFINITIONS */
/********************************************************************************************************/
/********************************************************************************************************/
/* LOCAL FUNCTION PROTOTYPES */
/********************************************************************************************************/
void initialize_mcu(void);
void wait_for_rx(void);
unsigned char detect_connected_channels(void);
unsigned int get_channel_pw(unsigned char pin);
void check_for_setup_mode(void);
void write_default_values_to_eeprom(void);
void load_failsafe_values(void);
void load_values_from_eeprom(void);
static inline void ppm_off(void);
static inline void ppm_on(void);
/********************************************************************************************************/
/* GLOBAL VARIABLES */
/********************************************************************************************************/
volatile unsigned int isr_channel_pw[(RC_PPM_GEN_CHANNELS +1)]; // +1 is for the reset pulse.
/*
unsigned int fs_channel_pw[8]= { RC_FS_CH_1_TIMER_VAL, RC_FS_CH_2_TIMER_VAL,
RC_FS_CH_3_TIMER_VAL, RC_FS_CH_4_TIMER_VAL,
RC_FS_CH_5_TIMER_VAL, RC_FS_CH_6_TIMER_VAL,
RC_FS_CH_7_TIMER_VAL, RC_FS_CH_8_TIMER_VAL,
};
*/
const char version_info[]="Servo2ppm V4.20";
volatile unsigned char pin_interrupt_detected = 0;
volatile unsigned char isr_channel_number = 0;
volatile unsigned int isr_timer0_16 = 0;
unsigned char channels_in_use = 0;
unsigned char channel_mask = 0;
union word2byte{
volatile unsigned int timer0_16;
volatile unsigned char timer0[2];
} timer0;
volatile unsigned int isr_timer0 = 0;
#if RC_CONSTANT_PPM_FRAME_TIME == 1
volatile unsigned int reset_pw = 0;
#endif
//unsigned char failsafe_mode = 0;
unsigned int ppm_off_threshold = RC_PPM_OFF_THRESHOLD_VAL;
unsigned char rc_lost_channel = (RC_LOST_CHANNEL-1);
//Dummy variable array in order not to use the beggining of the eeprom for usefull data.
//The beggining of the eeprom and especially byte 0 is prone to data corruption.
// "EEMEM" is equal to "__attribute__((section(".eeprom")))"
unsigned int dummy_int[10] __attribute__((section(".eeprom")))= { 1, 1 ,1, 1, 1, 1, 1, 1, 1, 1 };
unsigned int EEMEM ppm_off_threshold_e[11] = { RC_PPM_OFF_THRESHOLD_VAL, RC_PPM_OFF_THRESHOLD_VAL, RC_PPM_OFF_THRESHOLD_VAL,
RC_PPM_OFF_THRESHOLD_VAL, RC_PPM_OFF_THRESHOLD_VAL, RC_PPM_OFF_THRESHOLD_VAL,
RC_PPM_OFF_THRESHOLD_VAL, RC_PPM_OFF_THRESHOLD_VAL, RC_PPM_OFF_THRESHOLD_VAL,
RC_PPM_OFF_THRESHOLD_VAL, RC_PPM_OFF_THRESHOLD_VAL
};
unsigned char EEMEM rc_lost_channel_e[11] = { RC_LOST_CHANNEL-1, RC_LOST_CHANNEL-1, RC_LOST_CHANNEL-1,
RC_LOST_CHANNEL-1, RC_LOST_CHANNEL-1, RC_LOST_CHANNEL-1,
RC_LOST_CHANNEL-1, RC_LOST_CHANNEL-1, RC_LOST_CHANNEL-1,
RC_LOST_CHANNEL-1, RC_LOST_CHANNEL-1
};
//unsigned int EEMEM ch_failsafe_pw_e[RC_PPM_GEN_CHANNELS];
/********************************************************************************************************/
/* LOCAL FUNCTION DEFINITIONS */
/********************************************************************************************************/
/*11111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111*/
void initialize_mcu(void)
{
unsigned char x = 0;
unsigned int eep_address = 0;
asm("cli");
STOP_TIMER0();
RESET_TIMER0();
/* Enable pwm mode 15 (fast pwm with top=OCR1A) and stop the timer. */
/* The timer compare module must be configured before the DDR register. */
// THE PPM GENERATOR IS CONFIGURED HERE !
#if RC_PPM_OUTPUT_TYPE == 0 // NEGATIVE PULSES
RC_TIMER1_MODE_REG = (1<<COM1B1) | (1<<COM1B0) | (1<<WGM11) | (1<<WGM10);
#warning PPM output type set to NEGATIVE PULSE
#endif
#if RC_PPM_OUTPUT_TYPE == 1 // POSITIVE PULSES
RC_TIMER1_MODE_REG = (1<<COM1B1) | (0<<COM1B0) | (1<<WGM11) | (1<<WGM10);
#warning PPM output type set to POSITIVE PULSE
#endif
RC_TIMER1_PRESCALER_REG = (1<<WGM13)|(1<<WGM12);
RC_TIMER1_COMP1_REG = RC_RESET_PW_TIMER_VAL;
RC_TIMER1_COMP2_REG = RC_PPM_SYNC_PW_VAL;
RC_TIMER1_TIMSK |= (1<<OCIE1B);
RC_TIMER1_TIFR |= ( (1<<OCIE1B)|(1<<TOIE1) );
/*Enable timer0 overflow interupt and timer1 compare B interrupt */
RC_TIMER0_TIMSK |= (1<<TOIE0);
RC_TIMER0_TIFR |= (1<<TOIE0);
RC_LED_PORT_OUT_REG &= (~(1<<RC_LED_PIN));
RC_LED_PORT_DDR_REG |= (1<<RC_LED_PIN);
LED_ON();
RC_MUX_PORT_OUT_REG &= (~(1<<RC_MUX_PIN));
RC_MUX_PORT_DDR_REG |= (1<<RC_MUX_PIN);
MUX_ON();
// make the setup pin an input and activate the pull up resistor on the setup pin.
RC_SETUP_DDR_REG &= (~(1<<RC_SETUP_PIN));
RC_SETUP_PORT_OUT_REG |= (1<<RC_SETUP_PIN);
/* configure the servo pins as inputs and activate their pull up resistors for noise reduction. */
RC_SERVO_PORT_DDR_REG = 0;
RC_SERVO_PORT_OUT_REG = 0xFF;
isr_channel_number = RC_PPM_GEN_CHANNELS;
rc_lost_channel = (RC_LOST_CHANNEL-1);
ppm_off_threshold = RC_PPM_OFF_THRESHOLD_VAL;
// VERSION CONTROL
x=0;
eep_address = (E2END - (sizeof(version_info)-1));
while(version_info[x])
{
if( (eep_address) < E2END)
{
eeprom_write_byte( (unsigned char*)eep_address, version_info[x]);
}
eep_address++;
x++;
}
eeprom_write_byte((unsigned char*)E2END, '\0'); //Terminate the version control string.
asm("sei");
/* give some time for the pull up resistors to work. ~30 ms * 3 = 90 ms */
LED_OFF();
RESET_START_TIMER0();
for(x=0; x<3; x++)
{
wdt_reset();
RESET_TIMER0();
while(timer0.timer0[1] < RC_MAX_TIMEOUT_VAL );
}
x = 0;
STOP_TIMER0();
RESET_TIMER0();
LED_ON();
/*
The reason i configure the ppm port here is because i want to give some time
to the timer1 compare module to initialize.
The timer1 compare module as the Mega 168 manual states must be initialized before setting the DDR register
of the OCR1X pins.
*/
//RC_PPM_PORT_OUT_REG &= (~(1<<RC_PPM_PIN));
RC_PPM_PORT_DDR_REG |= (1<<RC_PPM_PIN);
return;
}
/*11111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111*/
/*22222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222*/
/*
This function waits untill the receiver has been powered up and running so we can then detect
the connected channels with certainty.
*/
#if defined(RC_RX_READY_CHANNEL) && RC_RX_READY_CHANNEL > 0
void wait_for_rx(void)
{
unsigned int pw=0;
unsigned char x = 0;
unsigned char servo_connected = 0;
RESET_START_TIMER0();
servo_connected = 0;
do{
wdt_reset();
RESET_TIMER0();
x=0;
while(timer0.timer0[1] <= RC_MAX_TIMEOUT_VAL )
{
if( (RC_SERVO_PORT_PIN_REG & (1<<(RC_RX_READY_CHANNEL-1))) ) { x=timer0.timer0[1]; }
if( (timer0.timer0[1] - x) >= RC_PULSE_TIMEOUT_VAL ){ servo_connected = 1; break; }
}
}while(servo_connected < 1);
//Now test the found channel for a proper servo pulse.
x = 0;
while(1)
{
pw=get_channel_pw( (RC_RX_READY_CHANNEL-1) );
if( (pw > RC_SERVO_MIN_PW_VAL) && (pw < RC_SERVO_MAX_PW_VAL) ) { x++; }else{ x=0; }
if(x >= 3) { break; }
}
return;
}
#else
void wait_for_rx(void)
{
unsigned int pw=0;
unsigned char x = 0;
unsigned char servo_connected = 0;
unsigned char channel = 0;
RESET_START_TIMER0();
do{
for(channel=0; channel < RC_SERVO_INPUT_CHANNELS; channel++)
{
wdt_reset();
RESET_TIMER0();
servo_connected = 0;
x=0;
while(timer0.timer0[1] <= RC_MAX_TIMEOUT_VAL )
{
if(RC_SERVO_PORT_PIN_REG & (1<<channel)) { x=timer0.timer0[1]; }
if( (timer0.timer0[1] - x) >= RC_PULSE_TIMEOUT_VAL ){ servo_connected = 1; break; }
}
if(servo_connected >= 1){ break; }
}
}while(servo_connected < 1);
//Now test the found channel for a proper servo pulse.
x = 0;
while(1)
{
pw=get_channel_pw(channel);
if( (pw > RC_SERVO_MIN_PW_VAL) && (pw < RC_SERVO_MAX_PW_VAL) ) { x++; }else{ x=0; }
if(x >= 3) { break; }
}
return;
}
#endif
/*22222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222*/
/*33333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333*/
unsigned char detect_connected_channels(void)
{
unsigned char channel=0;
unsigned char servo_connected = 0;
unsigned char connected_channels = 0;
unsigned char x = 0;
unsigned char y = 0;
#if defined(RC_RX_READY_CHANNEL) && RC_RX_READY_CHANNEL > 0
unsigned int pw = 0;
#endif
/*
There must be no error in which channels are connected to the encoder
because this will have devastating effects later on.
*/
wdt_reset();
RESET_START_TIMER0();
for(channel=0; channel < RC_SERVO_INPUT_CHANNELS; channel++)
{
servo_connected = 0;
for(y=0; y<5; y++)
{
wdt_reset();
RESET_TIMER0();
x=0;
while(timer0.timer0[1] <= RC_MAX_TIMEOUT_VAL )
{
if(RC_SERVO_PORT_PIN_REG & (1<<channel)) { x=timer0.timer0[1]; }
if( (timer0.timer0[1] - x) >= RC_PULSE_TIMEOUT_VAL ){ servo_connected++; break; }
}
if(servo_connected >= 3){ channel_mask |= (1<<channel); connected_channels++; break; }
}
}
#if defined(RC_RX_READY_CHANNEL) && RC_RX_READY_CHANNEL > 0
connected_channels = 0;
for(channel=0; channel < RC_SERVO_INPUT_CHANNELS; channel++)
{
if(channel_mask & (1<<channel) )
{
pw=get_channel_pw(channel);
if(pw < RC_SERVO_MIN_PW_VAL || pw > RC_SERVO_MAX_PW_VAL)
{
channel_mask &= (~(1<<channel));
}else{ connected_channels++; }
}
}
#endif
return(connected_channels);
}
/*33333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333*/
/*44444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444*/
void write_default_values_to_eeprom(void)
{
unsigned char x = 0;
for(x=0; x<(sizeof(ppm_off_threshold_e)/sizeof(int)); x++)
{
eeprom_write_word(&ppm_off_threshold_e[x], RC_PPM_OFF_THRESHOLD_VAL);
}
for(x=0; x < (sizeof(rc_lost_channel_e)/sizeof(char)); x++)
{
eeprom_write_byte(&rc_lost_channel_e[x], (RC_LOST_CHANNEL - 1));
}
rc_lost_channel = (RC_LOST_CHANNEL - 1);
ppm_off_threshold = RC_PPM_OFF_THRESHOLD_VAL;
return;
}
/*44444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444*/
/*55555555555555555555555555555555555555555555555555555555555555555555555555555555555555555555555555*/
/*
All this code because the Eeprom is prone to data corruption in noisy environments.
11 copies of each variable are read and if more than 50% + 1 values are the same and within limits
this value is taken to be valid.
If not all 11 values are the same then the array is written again with this 50% +1 value.
*/
void load_values_from_eeprom(void)
{
unsigned int eeprom_buf_x = 0;
unsigned int eeprom_buf_y = 0;
unsigned char match = 0;
unsigned char match_upper_limit = 0;
unsigned char match_lower_limit = 0;
unsigned char x = 0;
unsigned char y = 0;
wdt_reset();
/****************************************************************************************************/
/* READ WHICH CHANNEL WILL BE USED AS A RX LOST INDICATOR */
/****************************************************************************************************/
match_upper_limit = (sizeof(rc_lost_channel_e)/sizeof(char));
match_lower_limit = (((sizeof(rc_lost_channel_e)/sizeof(char))/2)+1);
for(x=0; x<match_upper_limit; x++)
{
match = 0;
eeprom_buf_x = eeprom_read_byte(&rc_lost_channel_e[x]);
for(y=0; y<match_upper_limit; y++)
{
eeprom_buf_y = eeprom_read_byte(&rc_lost_channel_e[y]);
if(eeprom_buf_y == eeprom_buf_x){ match++; }
}
// If 50% +1 or more char values in the array are the same a match has been found.
// Now test them to see if they are within limits.
if(match >= match_lower_limit )
{
if( eeprom_buf_x < RC_SERVO_INPUT_CHANNELS )
{
rc_lost_channel = eeprom_buf_x; //Load the stored value to throttle_thershold.
if(match < match_upper_limit)
{
for(x=0; x<match_upper_limit; x++)
{
eeprom_write_byte(&rc_lost_channel_e[x], eeprom_buf_x);
}
}
}else{ match = 0; }
break;
}
}
if( match < match_lower_limit ){ write_default_values_to_eeprom(); return; }
/****************************************************************************************************/
/* NOW READ THE CHANNEL'S PULSE WIDTH SO IT CAN BE USED AS A TRIGGER */
/****************************************************************************************************/
match_upper_limit = (sizeof(ppm_off_threshold_e)/sizeof(int));
match_lower_limit = (((sizeof(ppm_off_threshold_e)/sizeof(int))/2)+1);
for(x=0; x < match_upper_limit; x++)
{
match = 0;
eeprom_buf_x = eeprom_read_word(&ppm_off_threshold_e[x]);
for(y=0; y < match_upper_limit; y++)
{
eeprom_buf_y = eeprom_read_word(&ppm_off_threshold_e[y]);
if(eeprom_buf_y == eeprom_buf_x){ match++; }
}
// If 50% +1 or more integer values in the array are the same a match has been found.
// Now test them to see if they are within limits.
if(match >= match_lower_limit )
{
if( (eeprom_buf_x >= RC_PPM_OFF_UPPER_WINDOW_VAL) && (eeprom_buf_x <= RC_SERVO_MAX_PW_VAL) )
{
ppm_off_threshold = eeprom_buf_x; //Load the stored value to throttle_thershold.
if(match < match_upper_limit)
{
for(x=0; x < match_upper_limit; x++){ eeprom_write_word(&ppm_off_threshold_e[x], eeprom_buf_x); }
}
}else if( (eeprom_buf_x <= RC_PPM_OFF_LOWER_WINDOW_VAL) && (eeprom_buf_x >= RC_SERVO_MIN_PW_VAL) )
{
ppm_off_threshold = eeprom_buf_x; //Load the stored value to throttle_thershold.
if(match < match_upper_limit)
{
for(x=0; x < match_upper_limit; x++){ eeprom_write_word(&ppm_off_threshold_e[x], eeprom_buf_x); }
}
}else{ match = 0; }
break;
}
}
if( match < match_lower_limit ){ write_default_values_to_eeprom(); return; }
return;
}
/*55555555555555555555555555555555555555555555555555555555555555555555555555555555555555555555555555*/
/*66666666666666666666666666666666666666666666666666666666666666666666666666666666666666666666666666*/
unsigned int get_channel_pw(unsigned char pin)
{
unsigned int pw = 0;
unsigned char pw_measurement_started = 0;
wdt_reset();
/* The servo input pins are already configured as inputs with pullup resistors. */
// First we must disable the pin interrupt.
RC_PIN_INT_EN_REG &= (~(1<<RC_PIN_INT_EN_BIT));
//Now we must load the pin interrupt mask register.
RC_PIN_INT_MASK_REG = (1<<pin);
//Clear any pin interrupt flag set.
RC_PIN_INT_FLAG_REG |= (1<<RC_PIN_INT_FLAG_BIT);
// Clear the pin interrupt ISR detection variable
pin_interrupt_detected = 0;
// Finally we can enable the pin interrupt again.
RC_PIN_INT_EN_REG |= (1<<RC_PIN_INT_EN_BIT);
// Set and start timer1
RESET_START_TIMER0();
while(1)
{
/* Wait until the pin change state. */
do{
if( timer0.timer0[1] >= RC_MAX_TIMEOUT_VAL )
{
return(0);
}
}while( pin_interrupt_detected == 0 );
pin_interrupt_detected = 0;
if( RC_SERVO_PORT_PIN_REG & (1<<pin) ) /* if the pin is high then give it a time stamp */
{
pw = isr_timer0_16;
pw_measurement_started = 1; /* signal that this channel got it's timer stamp.*/
}else{
// If the pin is low and it already has a time stamp then we are done.
if( pw_measurement_started )
{
pw = isr_timer0_16 - pw;
break;
}
}
}
/*Stop the timer */
STOP_TIMER0();
RESET_TIMER0();
return((unsigned int)pw);
}
/*66666666666666666666666666666666666666666666666666666666666666666666666666666666666666666666666666*/
/*77777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777*/
void check_for_setup_mode(void)
{
unsigned int pw_buffer = 0;
unsigned int pw = 0;
unsigned char setup_mode = 0;
unsigned char success = 0;
unsigned char x = 0;
unsigned char y = 0;
//We have to make sure that the setup mode is requested.
wdt_reset();
x=0;
y=0;
setup_mode = 1;
RESET_START_TIMER0();
do{
if( (RC_SETUP_PIN_REG & (1<<RC_SETUP_PIN)) == 0){ x++; }else{ x=0; }
{
if(timer0.timer0[1] > RC_MAX_TIMEOUT_VAL ){setup_mode = 0; break; }
}
}while(x < 100);
if(setup_mode)
{
/****************************************************************************************************/
/* FIRST WE MUST FIND WHICH CHANNEL WILL BE USED AS A TX SIGNAL LOST INDICATOR */
/****************************************************************************************************/
wdt_reset();
success = 0;
if(channels_in_use > 1 )
{
if( channel_mask & (1<<(RC_LOST_CHANNEL - 1)) )
{
rc_lost_channel = (RC_LOST_CHANNEL - 1);
for(x=0; x < (sizeof(rc_lost_channel_e)/sizeof(char)); x++)
{
eeprom_write_byte(&rc_lost_channel_e[x], rc_lost_channel);
}
success += 1;
}
}else if(channels_in_use == 1)
{
for(x=0; x < RC_SERVO_INPUT_CHANNELS; x++)
{
if(channel_mask & (1<<x))
{
rc_lost_channel = x;
for(x=0; x < (sizeof(rc_lost_channel_e)/sizeof(char)); x++)
{
eeprom_write_byte(&rc_lost_channel_e[x], rc_lost_channel);
}
success += 1;
break;
}
}
}
/****************************************************************************************************/
/* NOW WE NEED TO FIND THE THRESHOLD PULSE WIDTH THAT WILL BE USED AN A TX SIGNAL LOST TRIGGER */
/****************************************************************************************************/
if(success == 1)
{
wdt_reset();
y = 0;
pw_buffer = 0;
for(x=0; x < 10; x++)
{
pw=get_channel_pw(rc_lost_channel);
if(pw >= RC_SERVO_MIN_PW_VAL && pw <= RC_SERVO_MAX_PW_VAL)
{
pw_buffer += pw;
y++;
}
}
pw_buffer /= y;
wdt_reset();
if( (pw_buffer >= RC_PPM_OFF_UPPER_WINDOW_VAL) && (pw_buffer <= RC_SERVO_MAX_PW_VAL) )
{
for(x=0; x<(sizeof(ppm_off_threshold_e)/sizeof(int)); x++)
{
eeprom_write_word(&ppm_off_threshold_e[x], (pw_buffer+RC_PPM_OFF_OFFSET_VAL));
}
success += 1;
}else if( (pw_buffer <= RC_PPM_OFF_LOWER_WINDOW_VAL) && (pw_buffer >= RC_SERVO_MIN_PW_VAL) )
{
for(x=0; x<(sizeof(ppm_off_threshold_e)/sizeof(int)); x++)
{
eeprom_write_word(&ppm_off_threshold_e[x], (pw_buffer-RC_PPM_OFF_OFFSET_VAL));
}
success += 1;
}
}
/****************************************************************************************************/
/* LASTLY WE MUST INDICATE TO THE USER IF THE SETUP PROCEDURE WAS SUCCESSFUL */
/****************************************************************************************************/
if(success == 2)
{
RC_SETUP_PORT_OUT_REG &= (~(1<<RC_SETUP_PIN));
while(1)
{
LED_ON();
for(x=0; x<3; x++)
{
wdt_reset();
RESET_START_TIMER0();
/* delay ~30 ms * 3 = 100 milliseconds */
while(timer0.timer0[1] < RC_MAX_TIMEOUT_VAL );
}
LED_OFF();
for(x=0; x<30; x++)
{
wdt_reset();
RESET_START_TIMER0();
/* delay ~30 ms * 30 = 900 milliseconds */
while(timer0.timer0[1] < RC_MAX_TIMEOUT_VAL );
}
}
}else{
write_default_values_to_eeprom();
while(1)
{
LED_ON();
for(x=0; x<30; x++)
{
wdt_reset();
RESET_START_TIMER0();
/* delay ~30 ms * 30 = 900 milliseconds */
while(timer0.timer0[1] < RC_MAX_TIMEOUT_VAL );
}
LED_OFF();
for(x=0; x<3; x++)
{
wdt_reset();
RESET_START_TIMER0();
/* delay ~30 ms * 3 = 100 milliseconds */
while(timer0.timer0[1] < RC_MAX_TIMEOUT_VAL );
}
}
}
} // End of "if(setup_mode)" statement.
return;
}
/*77777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777*/
/*88888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888*/
void load_failsafe_values(void)
{
wdt_reset();
isr_channel_pw[0] = RC_FS_CH_1_TIMER_VAL;
#if RC_PPM_GEN_CHANNELS >= 2
isr_channel_pw[1] = RC_FS_CH_2_TIMER_VAL;
#endif
#if RC_PPM_GEN_CHANNELS >= 3
isr_channel_pw[2] = RC_FS_CH_3_TIMER_VAL;
#endif
#if RC_PPM_GEN_CHANNELS >= 4
isr_channel_pw[3] = RC_FS_CH_4_TIMER_VAL;
#endif
#if RC_PPM_GEN_CHANNELS >= 5
isr_channel_pw[4] = RC_FS_CH_5_TIMER_VAL;
#endif
#if RC_PPM_GEN_CHANNELS >= 6
isr_channel_pw[5] = RC_FS_CH_6_TIMER_VAL;
#endif
#if RC_PPM_GEN_CHANNELS >= 7
isr_channel_pw[6] = RC_FS_CH_7_TIMER_VAL;
#endif
#if RC_PPM_GEN_CHANNELS >= 8
isr_channel_pw[7] = RC_FS_CH_8_TIMER_VAL;
#endif
#if RC_PPM_GEN_CHANNELS >= 9
isr_channel_pw[8] = RC_FS_CH_8_TIMER_VAL;
#endif
isr_channel_pw[RC_PPM_GEN_CHANNELS] = RC_RESET_PW_TIMER_VAL;
return;
}
/*
void load_failsafe_values(void)
{
unsigned char x = 0;
for(x=0; x< RC_PPM_GEN_CHANNELS; x++)
{
isr_channel_pw[x] = fs_channel_pw[x];
}
// LOAD THE PPM FRAME RESET PULSE WIDTH.
isr_channel_pw[RC_PPM_GEN_CHANNELS] = RC_RESET_PW_TIMER_VAL;
return;
}
*/
/*88888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888*/
/*99999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999*/
static inline void ppm_on(void)
{
RC_TIMER1_PRESCALER_REG &= (~(TIMER1_PRESCALER_BITS));
TCNT1 = 0;
isr_channel_number = RC_PPM_GEN_CHANNELS;
RC_TIMER1_COMP1_REG = RC_RESET_PW_TIMER_VAL;
RC_TIMER1_COMP2_REG = RC_PPM_SYNC_PW_VAL;
RC_TIMER1_TIFR |= ( (1<<OCIE1B)|(1<<TOIE1) );
RC_TIMER1_PRESCALER_REG |= TIMER1_PRESCALER_BITS;
return;
}
/*99999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999*/
/*10101010101010101010101010101010101010101010101010101010101010101010101010101010101010101010101010*/
static inline void ppm_off(void)
{
if(RC_TIMER1_PRESCALER_REG & TIMER1_PRESCALER_BITS)
{
while( TCNT1 <= (RC_PPM_SYNC_PW_VAL+(RC_PPM_SYNC_PW_VAL / 10)) );
}
RC_TIMER1_PRESCALER_REG &= (~(TIMER1_PRESCALER_BITS));
RC_TIMER1_TIFR |= ( (1<<OCIE1B)|(1<<TOIE1) );
return;
}
/*11111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111*/
/*12121212121212121212121212121212121212121212121212121212121212121212121212121212121212121212121212*/
void mux_control(void)
{
long PULSE_WIDTH = isr_channel_pw[RC_MUX_CHANNEL-1];
#if RC_MUX_REVERSE == 0
if((PULSE_WIDTH>RC_MUX_MIN)&&(PULSE_WIDTH<RC_MUX_MAX))
{
MUX_ON();
}
else
{
MUX_OFF();
}
#else
if((PULSE_WIDTH>RC_MUX_MIN)&&(PULSE_WIDTH<RC_MUX_MAX))
{
MUX_OFF();
}
else
{
MUX_ON();
}
#endif
}
/********************************************************************************************************/
/* MAIN FUNCTION */
/********************************************************************************************************/
__attribute__((noreturn)) void main(void)
{
//Variables for the servo channel measuring code.
unsigned short pw_of_channel[RC_SERVO_INPUT_CHANNELS];
unsigned char channel_mask_buffer = 0;
unsigned char pin_reg_buffer0 = 0;
unsigned char pin_reg_buffer1 = 0;
unsigned char channels_to_check=0;
unsigned char channel_status = 0;
unsigned short timer0_buffer = 0;
unsigned char x = 0;
unsigned char y = 0;
//Variables for the PPM control code.
unsigned char tx_signal_lost = 0;
unsigned char tx_signal_detected = 0;
unsigned char servo_signals_lost = 0;
unsigned char led_frequency = 0;
unsigned char led_counter = 0;
wdt_disable();
wdt_enable(WDTO_120MS);
wdt_reset();
initialize_mcu();
/*Load the values stored in the eeprom like the throttle channel threshold etc. */
load_values_from_eeprom();
//Load the ISR array. This way if a channel is not connected it will have the failsafe value.
load_failsafe_values();
/*
The "wait_for_rx(): function waits untill the receiver has been powered up and running
so we can then detect the connected channels with certainty.
*/
wait_for_rx();
channels_in_use = detect_connected_channels();
check_for_setup_mode();
servo_signals_lost = 1; //Signal that the servo signals have gone missing(no rx signal).
led_frequency = RC_LED_FREQUENCY_VAL_1HZ; //load the defined led frequency.
/**************************** SETUP THE PIN INTERRUPT *************************************************/
// Now we must disable the pin interrupt.
RC_PIN_INT_EN_REG &= (~(1<<RC_PIN_INT_EN_BIT));
//Now we must load the pin interrupt mask register.
RC_PIN_INT_MASK_REG = channel_mask;
//Clear any pin interrupt flag set.
RC_PIN_INT_FLAG_REG |= (1<<RC_PIN_INT_FLAG_BIT);
// Clear the pin interrupt ISR detection variable
pin_interrupt_detected = 0;
// Finally we can enable the pin interrupt again.
RC_PIN_INT_EN_REG |= (1<<RC_PIN_INT_EN_BIT);
// Set and start timer1
RESET_START_TIMER0();
// Take a snapshot of the servo pins in order to establish a starting point.
pin_reg_buffer1 = (RC_SERVO_PORT_PIN_REG & channel_mask);
RESET_START_TIMER0();
//Main endless loop.
while(1)
{
wdt_reset();
channel_mask_buffer = channel_mask;
RESET_TIMER0();
while(channel_mask_buffer)
{
/* Wait until a pin change state. */
do{
if( timer0.timer0[1] >= RC_MAX_TIMEOUT_VAL )
{
goto PPM_CONTROL;
}
}while( pin_interrupt_detected == 0 );
x=0;
y=1;
//Only pins that changed their state will be tested for a high or low level
pin_reg_buffer0 = (RC_SERVO_PORT_PIN_REG & channel_mask_buffer);
pin_interrupt_detected = 0;
channels_to_check = pin_reg_buffer1 ^ pin_reg_buffer0;
pin_reg_buffer1 = pin_reg_buffer0;
while(x<RC_SERVO_INPUT_CHANNELS)
{
if(channels_to_check & y)
{
if( (pin_reg_buffer0 & y) ) /* if the pin is high then... */
{
pw_of_channel[x] = isr_timer0_16;
channel_status |= y; /* signal that this channel got it's timer stamp. */
}else{
if( channel_status & y )
{
channel_mask_buffer &= (~y);
timer0_buffer = isr_timer0_16 - pw_of_channel[x];
if( (timer0_buffer > RC_SERVO_MIN_PW_VAL) && (timer0_buffer < RC_SERVO_MAX_PW_VAL) )
{
#if defined(RC_LOST_CHANNEL) && RC_LOST_CHANNEL > 0
if(x == rc_lost_channel)
{
if(ppm_off_threshold > RC_SERVO_CENTER_PW_VAL)
{
if(timer0_buffer >= ppm_off_threshold)
{
channel_mask_buffer = 0xFF;
goto PPM_CONTROL;
}
}else{
if(timer0_buffer <= ppm_off_threshold)
{
channel_mask_buffer = 0xFF;
goto PPM_CONTROL;
}
}
}
#endif
if(servo_signals_lost == 0)
{
asm("cli"); //Atomic operation needed here.
isr_channel_pw[x] = timer0_buffer;
asm("sei");
}
} // End of " if( (timer0_buffer > RC_SERVO_MIN_PW_VAL) && ..." statement.
} // End of "if( channel_status & y )" statement.
} // End of "if( (pin_reg_buffer0 & y) )...else..." statement
} // End of "if(channels_to_check & y)" statement.
x++;
y=(y<<1);
}
} // End of "while(channel_mask_buffer)" loop.
PPM_CONTROL:
led_counter++;
if( led_counter >= led_frequency ){ led_counter = 0; TOGGLE_LED(); }
//We need 'RC_MAX_BAD_PPM_FRAMES" consecutive readings in order to change the PPM generator's status.
if( channel_mask_buffer == 0 ) //IF ALL CHANNELS HAVE BEEN MEASURED...
{
tx_signal_lost = 0;
if(servo_signals_lost == 1) //IF PREVIOUSLY THE SERVO SIGNAL WAS LOST...
{
tx_signal_detected++;
if(tx_signal_detected > RC_MAX_BAD_PPM_FRAMES)
{
ppm_on();
servo_signals_lost = 0;
LED_ON();
led_counter = 0;
led_frequency = RC_LED_FREQUENCY_VAL;
}
}
}
else{ //IF NOT ALL CHANNELS HAVE BEEN MEASURED...
pin_reg_buffer1 = (RC_SERVO_PORT_PIN_REG & channel_mask);
tx_signal_detected = 0;
if(servo_signals_lost == 0)
{
tx_signal_lost++;
if(tx_signal_lost > RC_MAX_BAD_PPM_FRAMES)
{
servo_signals_lost = 1;
led_counter = 0;
led_frequency = RC_LED_FREQUENCY_VAL_1HZ;
#if defined(RC_USE_FAILSAFE) && RC_USE_FAILSAFE == 1
load_failsafe_values();
#else
ppm_off();
#endif
}
} //end of if(servo_signals_lost == 0) statement.
} //end of if( x > (channels_in_use/2) ){...}else{...} statement.
mux_control();
} //end of while(1) loop.
}
/********************************************************************************************************/
/* INTERRUPT SERVICE ROUTINES */
/********************************************************************************************************/
//ISR(TIMER0_OVF_vect, ISR_NAKED)
ISR(TIMER0_OVF_vect)
{
timer0.timer0[1]++;
return;
}
/********************************************************************************************************/
/*
By using the fast pwm mode 15 which uses the OCR1A value as TOP value and changing the values within the
OCR1B interrupt, timing is very accurate because the OCR1A and OCR1B registers are double buffered.
This means that although it looks like we modify both registers within the OCR1B interrupt we are actually
modifying their buffers and not the actual registers.
Both actual registers are updated when the timer reaches the OCR1A (TOP) value automatically.
This way the OCR1B interrupt can be delayed as needed without any loss of timing accuracy.
*/
ISR(TIMER1_COMPB_vect)
{
asm("sei");
#if RC_CONSTANT_PPM_FRAME_TIME == 1
isr_channel_number++;
if( isr_channel_number >= (RC_PPM_GEN_CHANNELS + 1) ) {isr_channel_number = 0; reset_pw = RC_PPM_FRAME_TIMER_VAL; }
if(isr_channel_number < RC_PPM_GEN_CHANNELS)
{
RC_TIMER1_COMP1_REG = isr_channel_pw[isr_channel_number];
reset_pw -= RC_TIMER1_COMP1_REG;
}else{
RC_TIMER1_COMP1_REG = reset_pw;
}
#endif
#if RC_CONSTANT_PPM_FRAME_TIME == 0
isr_channel_number++;
if( isr_channel_number >= (RC_PPM_GEN_CHANNELS + 1) ) {isr_channel_number = 0; }
RC_TIMER1_COMP1_REG = isr_channel_pw[isr_channel_number];
#endif
return;
}
/********************************************************************************************************/
ISR(PCINT2_vect)
{
timer0.timer0[0]= TCNT0;
if( RC_TIMER0_TIFR & (1<<TOIE0) ){RC_TIMER0_TIFR |= (1<<TOIE0); timer0.timer0[1]++; timer0.timer0[0]= 0; }
isr_timer0_16 = timer0.timer0_16;
pin_interrupt_detected = 1;
return;
}
/********************************************************************************************************/
/*
ISR(TIMER1_OVF_vect)
{
return;
}
*/
/*######################################################################################################*/
/* T H E E N D */
/*######################################################################################################*/