tjmartin843 / generate-ppm-signal

Automatically exported from code.google.com/p/generate-ppm-signal
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Unable to find stable setting for my DX8 ppm input. #1

Open GoogleCodeExporter opened 8 years ago

GoogleCodeExporter commented 8 years ago
What steps will reproduce the problem?
Out of sync PPM generation.

1. Put Spektrum DX8 in programmable slave on all channel.
2- Connect Arduino pin 10 to Trainer port input.
3- Press Trainer switch when NO SLAVE switches to MASTER.
4- Go to monitoring screen and watch outputs ...All screwed up.

What is the expected output? What do you see instead?
Stable signals as per ISR usage from another code I downloaded.

What version of the product are you using? On what operating system?
Arduino Nano V3.0, pin 10.

Try this one ;)

/*
 PPM Tester (8 channel)
  By Kelly Perreault
INFORMATION:
  See ReadMe.txt for lots of info including I/O allocation.  
*/

#include "EEPROM.h"

char* Version[]={"Version", "  1.0   "};

// User adjustable settings
int pulseMin =420, pulseMid = 1250, pulseMax = 1250;            // PPM Pulse 
widths in uS

// Manual Timer, Interrupt Timer vars
unsigned char TimerStart = 0;    
int secflag = 0, minflag = 0;
int PPM_array[9];
int PPMFreq_uS = 22000;          // PPM frame length total in uS
int Fixed_uS = 400;              // PPM frame padding LOW phase in uS

// Assign analogue & digital I/O pins
int AI_Raw[7] = { 0, 1, 2, 3, 4, 5, 6 };                // actual analog input 
pins
int AI_Val[7];                                          // analogue input vars
int DI_Raw[10] = { 2, 3, 4, 5, 6, 7, 8, 9, 13, 11 };    // actual digital input 
pins
int DI_Val[10];                                         // digital input vars
unsigned char AI_pincount = 7;   // analogue pin count
unsigned char DI_pincount = 10;  // digital pin count
unsigned char outPinPPM = 10;    // PPM output pin (do not change - pin 10 tied 
to ISR

// Sub timing vars
int tick0 = 0, tick1 = 0, tick2 = 0, tick3 = 0, tick4=0, band=0,band2=0, 
currch=1;
unsigned char slowflag;

int ACC_PPM_length = 0;          // Pulse length current total, used to 
calculate sync pulse
int *PPM_pointer = PPM_array;
int PPM_len;

// *********************** Setup **************************
void setup() {

  // Setup Digital I/O
  pinMode(outPinPPM, OUTPUT);   // sets as output
  for(char i=0; i<DI_pincount; i++) { pinMode(DI_Raw[i], INPUT); }      // set digital inputs
  for(char i=0; i<DI_pincount; i++) { digitalWrite(DI_Raw[i], HIGH); }  // turn on pull-up resistors

   // Initialize PPM channel array
  char i=0;
 for(i=0; i<8; i++) { PPM_array[i] = pulseMin; }
 PPM_array[i] = -1;   // Mark end

  // Initialise ISR Timer 1 - PPM generation
  TCCR1A = B00110001;  // Compare register B used in mode 3
  TCCR1B = B00010010;  // WGM13 & CS11 set to 1
  TCCR1C = B00000000;  // All set to 0
  TIMSK1 = B00000010;  // Interrupt on compare B
  TIFR1  = B00000010;  // Interrupt on compare B
  OCR1A = PPMFreq_uS;  // PPM frequency
  OCR1B = Fixed_uS;    // PPM off time (lo padding)

  // Initialise ISR Timer 2 - Subroutine timing
  // Interrupt rate =  16MHz / (prescaler * (255 - TCNT2))
  // period [sec] = (1 / f_clock [sec]) * prescale * (255-count)
  //                (1/16000000)  * 1024 * (255-178) = .004992sec = 4.992mS
  TCCR2B = B00000000;   // Disable Timer2 while we set it up
  TCNT2  = 178;         // Reset Timer Count  (255-"178")
  TIFR2  = B00000000;   // Timer2 INT Flag Reg: Clear Timer Overflow Flag
  TIMSK2 = B00000001;   // Timer2 INT Reg: Timer2 Overflow Interrupt Enable
  TCCR2A = B00000000;   // Timer2 Control Reg A: Wave Gen Mode normal
  TCCR2B = B00000111;   // Timer2 Control Reg B: Timer Prescaler set to 1024

  // INFO ********************************************
  //1150 all except 1 for start at -108% to 38% (thr at 60%), 400 for array 1, band 250 , skip  1 
  //1170 all except 1 for start at -92% to 32%, 680 for array 1, band 250 , skip  1 
  //1150 all except 1 for start at -108% to 38% (thr at 45%), 600 for array 1, band 250 , skip  1
  //1139 all except 1 for start at -100% to 32%, 500 for array 1, band 250 , skip  1
  //940 all except 1 for start at -150% to 0% , 700 for array 1, band 230 , skip  1
  //940 all except 1 for start at -150% to 40% , 420 for array 1, band 100/2=50 , skip 1
 PPM_array[0] =  940; //Ax3 CH1
 PPM_array[1] =  420; //Ax2 CH2 default put to 1000=NO SYNC , 900=40%, 800=40% 700= 34%, 600=34% , 500=39%,  400=39% , 300=NO SYNC(toggle min or max) ,varies with AX1
 PPM_array[2] =  940; //THR  CH3
 PPM_array[3] =  940; //AIL  CH4
 PPM_array[4] =  940; //ELE  CH5
 PPM_array[5] =  940; //RUD  CH6
 PPM_array[6] =  940; //GER  CH7
 PPM_array[7] =  940; //AX1  CH8

}

// *********************** Main Loop **************************
void loop() { // Main loop

     // Read all input pins into AI var array 1
   for(byte i=0; i<AI_pincount; i++) {  
      AI_Val[i] = analogRead(AI_Raw[i]);
   } 

 if (tick0 >= 25) {             // Run these subs every 124.8mS
      tick0 = 0;
  }

  band=103; band2=band*2;

  // Generate slow changing flag
  if (tick4 <= band) {

    PPM_array[currch] = PPM_array[currch]+ 1; //ELE
  if ( currch <> 0 currch < 7  ) {
    PPM_array[currch+1] = PPM_array[currch+1]+ 1; //ELE
      }
  }
  if (tick4 > band && tick4 <= band2) {

     PPM_array[currch] = PPM_array[currch]- 1; //ELE
 if ( currch <> 0 && currch < 7  ) {
     PPM_array[currch+1] = PPM_array[currch+1]- 1; //ELE
  }

  if (tick4 > band2) 
  {
       PPM_array[currch]=PPM_array[currch]-7;
        currch= currch +1;
        tick4 = 0;  
  } 

  if (currch == 1) 
  {
      currch=2; //skip ch 2 - Ax2 - array 1
  }   

  if (currch >= 8) 
  {

       currch=0;
  } 

  if (tick1 <= 50) {
      slowflag = 0;     
  }

  if (tick1 >= 50 && tick1 <=100) 
  {
      slowflag = 1;

  }

  if (tick1 == 100)
  {
      tick1 = 0; 
  }

  // generate 1sec tick
  if (TimerStart == 0) {
      if (tick2 >= 160) {  // 1000mS
          secflag++;
          tick2 = 0;
      }

      if (secflag >= 60) {
          secflag = 0;
          minflag++;
      }  

      if (minflag >= 100) {
          minflag = 0;
      }
  }  

}

// *********************** TIMER 1 **************************
ISR(TIMER1_COMPA_vect) {
  PPM_len = *(PPM_pointer++);
  if(PPM_len > -1) {
    OCR1A = PPM_len;                        // Set pulse length
    ACC_PPM_length += PPM_len;              // Add pulse length to accumulator
  } else {
    PPM_pointer = PPM_array;                // Reset table position pointer
    OCR1A = PPMFreq_uS - ACC_PPM_length;    // Calculate final sync pulse length
    ACC_PPM_length = 0;                     // Reset accumulator
  }
}

// *********************** TIMER 2 **************************
ISR(TIMER2_OVF_vect) {
  tick0 = tick0 + 1;                        // update timing tick
  tick1 = tick1 + 1;                        // update timing tick
  tick2 = tick2 + 1;                        // update timing tick
  tick3 = tick3 + 1;                        // update timing tick
  tick4 = tick4 + 1;                        // update timing tick
  TCNT2 = 155;                              // reset timer cnt to 155 out of 255
  TIFR2 = 0x00;                             // timer2 int flag reg: clear timer overflow flag
}

Original issue reported on code.google.com by clearchr...@gmail.com on 25 Jan 2015 at 9:07

GoogleCodeExporter commented 8 years ago
Oups , step 1 should be programmable MASTER ...not Programmable Slave.

Original comment by clearchr...@gmail.com on 25 Jan 2015 at 9:08