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/* TestTwinPeaks.ino Bob Larkin 26 Feb 2022 1
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* Tests the AlignLR class for finding the relative
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* time order of the Codec ADC L and R channels, and then
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* corrects these offsets.
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*
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* This applies a common analog square wave signal to the L and R inputs.
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* The cross-correlation between the channels is found for
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* the different offsets, showing the identical output.
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*
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* The outputs of the AlignLR object is then corrected, if necessary,
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* by delaying either the L or R channel.
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*
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* This test allows the analog signal to come from either the Codec
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* DAC or from a digital I/O pin on the Teensy.
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*
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*/
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// Beta rev 12 Mar 2022: Added normalized measures and removed threshold. Moved
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// the L-R alignment to setup().
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#include "Audio.h"
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#include "OpenAudio_ArduinoLibrary.h"
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// ******* MINI CONTROL PANEL *******
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//
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// Pick one, based on the analog signal source harware being used:
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//#define SIGNAL_HARDWARE TP_SIGNAL_CODEC
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#define SIGNAL_HARDWARE TP_SIGNAL_IO_PIN
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//
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// Show the Teensy pin used for both Codec and I/O pin signal source methods
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#define PIN_FOR_TP 2
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//
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// Set threshold as needed. Examine 3 output data around update #15
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// and use about half of maximum positive value.
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// #define TP_THRESHOLD 0.001f <<<< No Longer Used
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//
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// End Control Panel
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const float sample_rate_Hz = 44100.0f;
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const int audio_block_samples = 128;
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AudioSettings_F32 audio_settings(sample_rate_Hz, audio_block_samples);
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TPinfo* pData;
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uint32_t timeSquareWave = 0; // Switch every twoPeriods microseconds
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uint32_t twoPeriods;
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AudioInputI2S_F32 i2sIn;
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// BEWARE _ -- The SIGNAL_HARDWARE==TP_SIGNAL_CODEC is likely to be removed and
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// then the constructtion of the object will be *ONLY* the simple cases
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// of TwinPeak(audio_settings) or just TwinPeak
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// Pin or Codec Pin, Invert
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AudioAlignLR_F32 TwinPeak(SIGNAL_HARDWARE, PIN_FOR_TP, false, audio_settings);
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AudioOutputI2S_F32 i2sOut;
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#ifdef PRINT_OUTPUT_DATA
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AudioRecordQueue_F32 q1;
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AudioRecordQueue_F32 q2;
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#endif
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AudioControlSGTL5000 codec;
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AudioConnection_F32 connection1(i2sIn, 0, TwinPeak, 0);
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AudioConnection_F32 connection2(i2sIn, 1, TwinPeak, 1);
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#if SIGNAL_HARDWARE==TP_SIGNAL_CODEC
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// Not realistic for a radio but useful for testing
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AudioConnection_F32 connection3(TwinPeak, 2, i2sOut, 1); // DAC R
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#endif
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#if SIGNAL_HARDWARE==TP_SIGNAL_IO_PIN
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// Not realistic for a radio but useful for testing
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AudioConnection_F32 connection4(TwinPeak, 1, i2sOut, 1); // DAC R
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#endif
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AudioConnection_F32 connection5(TwinPeak, 0, i2sOut, 0); // DAC L
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// For test, send to queue. For real, send to receiver.
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#ifdef PRINT_OUTPUT_DATA
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AudioConnection_F32 connection6(TwinPeak, 0, q1, 0);
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AudioConnection_F32 connection7(TwinPeak, 1, q2, 0);
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#endif
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void setup(void) {
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static uint32_t tMillis = millis();
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AudioMemory_F32(50, audio_settings);
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Serial.begin(100); // Any rate
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delay(500);
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Serial.println("Twin Peaks L-R Synchronizer Test");
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codec.inputSelect(AUDIO_INPUT_LINEIN);
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codec.enable(); // This needs to preceed TwinPeak setup
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#if SIGNAL_HARDWARE==TP_SIGNAL_CODEC
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Serial.println("Using SGTL5000 Codec output for cross-correlation test signal.");
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#endif
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#if SIGNAL_HARDWARE==TP_SIGNAL_IO_PIN
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pinMode (PIN_FOR_TP, OUTPUT); // Digital output pin
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Serial.println("Using I/O pin for cross-correlation test signal.");
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#endif
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//TwinPeak.setThreshold(TP_THRESHOLD); Not used
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TwinPeak.stateAlignLR(TP_MEASURE); // Comes up TP_IDLE
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#if SIGNAL_HARDWARE==TP_SIGNAL_IO_PIN
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twoPeriods = (uint32_t)(0.5f + (2000000.0f / sample_rate_Hz));
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// Note that for this hardware, the INO is 100% in charge of the PIN_FOR_TP
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pData = TwinPeak.read(); // Base data to check error
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while (pData->TPerror < 0 && millis()-tMillis < 2000) // with timeout
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{
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if(micros()-timeSquareWave >= twoPeriods && pData->TPstate==TP_MEASURE)
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{
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static uint16_t squareWave = 0;
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timeSquareWave = micros();
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squareWave = squareWave^1;
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digitalWrite(PIN_FOR_TP, squareWave);
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}
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pData = TwinPeak.read();
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}
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// The update has moved from Measure to Run. Ground the PIN_FOR_TP
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//TwinPeak.stateAlignLR(TP_RUN); // TP is done, not TP_MEASURE
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digitalWrite(PIN_FOR_TP, 0); // Set pin to zero
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Serial.println("");
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Serial.println("Update ------------ Outputs ------------");
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Serial.println("Number xNorm -1 0 1 Shift Error State");// Column headings
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Serial.print(pData->nMeas); Serial.print(", ");
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Serial.print(pData->xNorm, 6); Serial.print(", ");
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Serial.print(pData->xcVal[3], 6); Serial.print(", ");
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Serial.print(pData->xcVal[0], 6); Serial.print(", ");
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Serial.print(pData->xcVal[1], 6); Serial.print(", ");
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Serial.print(pData->neededShift); Serial.print(", ");
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Serial.print(pData->TPerror); Serial.print(", ");
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Serial.println(pData->TPstate);
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// You can see the injected signal level by the printed variable, pData->xNorm
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// It is the sum of the 4 cross-correlation numbers and if it is below 0.0001 the
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// measurement is getting noisy and un-reliable. Raise the injected signal level
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// to solve the problem.
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#endif
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}
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void loop(void) {
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}
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