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oscilloscope burst mode test

timer1
Youen Toupin 10 years ago
parent
commit
3359c244eb
  1. 90
      OneWireIO.ino

90
OneWireIO.ino

@ -8,14 +8,20 @@
// how many samples we want to skip between two samples we keep (can be used to lower the sampling frequency) // how many samples we want to skip between two samples we keep (can be used to lower the sampling frequency)
#define SkipSamples 0 #define SkipSamples 0
byte regularEncodedFrequency; byte regularEncodedFrequency;
byte burstEncodedFrequency;
const int BufferSize = 512; int regularADCSRA;
int burstADCSRA;
const int BufferSize = 128;
const int BurstBufferSize = 1024;
byte buffer1[BufferSize]; byte buffer1[BufferSize];
byte buffer2[BufferSize]; byte buffer2[BufferSize];
byte* backBuffer = buffer1; byte burstBuffer[BurstBufferSize];
volatile byte* backBuffer = buffer1;
volatile short backBufferPos = 0; volatile short backBufferPos = 0;
byte samplesSkipped = SkipSamples; byte samplesSkipped = SkipSamples;
unsigned long backBufferStartTime = micros(); volatile unsigned long backBufferStartTime = micros();
SerialChannel oscilloscope("oscilloscope"); SerialChannel oscilloscope("oscilloscope");
SerialChannel debug("debug"); SerialChannel debug("debug");
@ -39,19 +45,34 @@ void setup()
ADMUX |= (1 << REFS0); //set reference voltage ADMUX |= (1 << REFS0); //set reference voltage
ADMUX |= (1 << ADLAR); //left align the ADC value- so we can read highest 8 bits from ADCH register only ADMUX |= (1 << ADLAR); //left align the ADC value- so we can read highest 8 bits from ADCH register only
int ADPS = (1 << ADPS2) | (0 << ADPS1) | (1 << ADPS0); byte skipSamples = 0;
ADCSRA |= ADPS; //set ADC clock with 32 prescaler- 16mHz/32=500KHz ; 13 cycles for a conversion which means 38000 samples per second #if SkipSamples > 0
ADCSRA |= (1 << ADATE); //enabble auto trigger skipSamples = SkipSamples;
ADCSRA |= (1 << ADIE); //enable interrupts when measurement complete #endif
ADCSRA |= (1 << ADEN); //enable ADC
ADCSRA |= (1 << ADSC); //start ADC measurements int ADPS = (1 << ADPS2) | (0 << ADPS1) | (1 << ADPS0);
regularADCSRA = 0;
regularADCSRA |= ADPS; //set ADC clock with 32 prescaler- 16mHz/32=500KHz ; 13 cycles for a conversion which means 38000 samples per second
regularADCSRA |= (1 << ADATE); //enabble auto trigger
regularADCSRA |= (1 << ADIE); //enable interrupts when measurement complete
regularADCSRA |= (1 << ADEN); //enable ADC
regularADCSRA |= (1 << ADSC); //start ADC measurements
regularEncodedFrequency = (byte)ADPS;
regularEncodedFrequency |= skipSamples << 3;
ADCSRA = regularADCSRA;
ADPS = (0 << ADPS2) | (1 << ADPS1) | (1 << ADPS0);
burstADCSRA = 0;
burstADCSRA |= ADPS; //set ADC clock with 32 prescaler- 16mHz/32=500KHz ; 13 cycles for a conversion which means 38000 samples per second
burstADCSRA |= (1 << ADATE); //enabble auto trigger
burstADCSRA |= (1 << ADIE); //enable interrupts when measurement complete
burstADCSRA |= (1 << ADEN); //enable ADC
burstADCSRA |= (1 << ADSC); //start ADC measurements
regularEncodedFrequency = (byte)ADPS; burstEncodedFrequency = (byte)ADPS;
byte skipSamples = 0; burstEncodedFrequency |= skipSamples << 3;
#if SkipSamples > 0
skipSamples = SkipSamples;
#endif
regularEncodedFrequency |= skipSamples << 3;
sei();//enable interrupts sei();//enable interrupts
@ -60,20 +81,26 @@ void setup()
void loop() void loop()
{ {
while(backBufferPos < BufferSize / 2) ; while(backBufferPos < BufferSize / 2 || (backBuffer == burstBuffer && backBufferPos < BurstBufferSize - 1)) ;
cli();//disable interrupts cli();//disable interrupts
byte* currentBuffer = backBuffer; byte* currentBuffer = (byte*)backBuffer;
short currentBufferSize = backBufferPos; short currentBufferSize = backBufferPos;
backBuffer = (backBuffer == buffer1 ? buffer2 : buffer1); backBuffer = (backBuffer == buffer1 ? buffer2 : buffer1);
backBufferPos = 0; backBufferPos = 0;
if(currentBuffer == burstBuffer)
{
ADCSRA = regularADCSRA;
}
sei();//enable interrupts sei();//enable interrupts
unsigned long currentBufferStartTime = backBufferStartTime; unsigned long currentBufferStartTime = backBufferStartTime;
backBufferStartTime = micros(); backBufferStartTime = micros();
digitalWrite(LEDPin, LOW); digitalWrite(LEDPin, LOW);
byte encodedFrequency = currentBuffer == burstBuffer ? burstEncodedFrequency : regularEncodedFrequency;
//Serial.write(currentBuffer, currentBufferSize); //Serial.write(currentBuffer, currentBufferSize);
oscilloscope.beginWrite(currentBufferSize + 1, currentBufferStartTime); oscilloscope.beginWrite(currentBufferSize + 1, currentBufferStartTime);
oscilloscope.continueWrite(&regularEncodedFrequency, 1); oscilloscope.continueWrite(&encodedFrequency, 1);
oscilloscope.continueWrite(currentBuffer, currentBufferSize); oscilloscope.continueWrite(currentBuffer, currentBufferSize);
} }
@ -87,12 +114,31 @@ ISR(ADC_vect) {//when new ADC value ready
#endif #endif
backBuffer[backBufferPos++] = sample; backBuffer[backBufferPos++] = sample;
if(backBufferPos >= BufferSize) if(backBuffer == burstBuffer)
{ {
// overflow of back buffer, we loose the current sample if(backBufferPos >= BurstBufferSize)
digitalWrite(LEDPin, HIGH); {
backBufferPos = BufferSize - 1; backBufferPos = BurstBufferSize - 1;
}
} }
else
{
if(backBufferPos >= BufferSize)
{
// overflow of back buffer, we loose the current sample
digitalWrite(LEDPin, HIGH);
backBufferPos = BufferSize - 1;
}
}
// switch to burst mode if the trigger condition is met
/*if(backBuffer != burstBuffer && sample < 127)
{
backBuffer = burstBuffer;
ADCSRA = burstADCSRA;
backBufferPos = 0;
backBufferStartTime = micros();
}*/
} }
void onewireInterrupt(void) void onewireInterrupt(void)

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