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- /* Example for synchonized measurements using both ADC present in Teensy 3.1
- * You can change the number of averages, bits of resolution and also the comparison value or range.
- */
-
- #ifdef ADC_DUAL_ADCS
-
-
- #include <ADC.h>
- #include <ADC_util.h>
-
- const int readPin = A9;
- const int readPin2 = A3;
-
- ADC *adc = new ADC(); // adc object
-
- elapsedMicros time;
-
- void setup() {
-
- pinMode(LED_BUILTIN, OUTPUT);
- pinMode(readPin, INPUT);
- pinMode(readPin2, INPUT);
-
- Serial.begin(9600);
-
- ///// ADC0 ////
- adc->adc0->setAveraging(1); // set number of averages
- adc->adc0->setResolution(8); // set bits of resolution
- adc->adc0->setConversionSpeed(ADC_CONVERSION_SPEED::HIGH_SPEED); // change the conversion speed
- adc->adc0->setSamplingSpeed(ADC_SAMPLING_SPEED::HIGH_SPEED); // change the sampling speed
-
- ////// ADC1 /////
- adc->adc1->setAveraging(1); // set number of averages
- adc->adc1->setResolution(8); // set bits of resolution
- adc->adc1->setConversionSpeed(ADC_CONVERSION_SPEED::HIGH_SPEED); // change the conversion speed
- adc->adc1->setSamplingSpeed(ADC_SAMPLING_SPEED::HIGH_SPEED); // change the sampling speed
-
-
- adc->startSynchronizedContinuous(readPin, readPin2);
- // You can also try:
- //adc->startSynchronizedContinuousDifferential(A10, A11, A12, A13);
- // Read the values in the loop() with readSynchronizedContinuous()
-
- delay(100);
- Serial.println("end setup");
- }
-
- int value = 0;
- int value2 = 0;
-
- ADC::Sync_result result;
-
- void loop() {
-
- // You can also try:
- //result = adc->analogSynchronizedRead(readPin, readPin2);
- //result = adc->analogSynchronizedReadDifferential(A10, A11, A12, A13);
-
- result = adc->readSynchronizedContinuous();
- // if using 16 bits and single-ended is necessary to typecast to unsigned,
- // otherwise values larger than 3.3/2 will be interpreted as negative
- result.result_adc0 = (uint16_t)result.result_adc0;
- result.result_adc1 = (uint16_t)result.result_adc1;
-
- //digitalWriteFast(LED_BUILTIN, !digitalReadFast(LED_BUILTIN));
-
- //Serial.print("Value ADC0: ");
- Serial.print(time, DEC);
- Serial.print(" ");
- Serial.print(result.result_adc0*3.3/adc->adc0->getMaxValue(), DEC);
- Serial.print(" ");
- Serial.println(result.result_adc1*3.3/adc->adc1->getMaxValue(), DEC);
-
-
- // Print errors, if any.
- if(adc->adc0->fail_flag != ADC_ERROR::CLEAR) {
- Serial.print("ADC0: "); Serial.println(getStringADCError(adc->adc0->fail_flag));
- }
- #ifdef ADC_DUAL_ADCS
- if(adc->adc1->fail_flag != ADC_ERROR::CLEAR) {
- Serial.print("ADC1: "); Serial.println(getStringADCError(adc->adc1->fail_flag));
- }
- #endif
-
- digitalWriteFast(LED_BUILTIN, !digitalReadFast(LED_BUILTIN));
-
-
- //delay(100);
- }
-
- /*
- With a AWG I generated a sine wave of 1 Hz and 2 V amplitude.
- I measure synchronously on pins A0 (ADC0) and A2 (ADC1), sampling at 20 Hz (every 50ms).
- The relative error: mean(value(A0)-value(A2))/mean(value(A0)) is approx 0.02%
-
-
- */
-
- #else // make sure the example can run for any boards (automated testing)
- void setup() {}
- void loop() {}
- #endif // ADC_DUAL_ADCS
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