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Add DTMF Dial Tone decode + transmit example

dds
PaulStoffregen il y a 10 ans
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révision
aa53af053a
1 fichiers modifiés avec 216 ajouts et 0 suppressions
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      examples/DialTone_DTMF/DialTone_DTMF.ino

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examples/DialTone_DTMF/DialTone_DTMF.ino Voir le fichier

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#include <Audio.h>
#include <Wire.h>
#include <SD.h>

// Create the Audio components. These should be created in the
// order data flows, inputs/sources -> processing -> outputs
//
AudioInputI2S audioIn;
AudioAnalyzeToneDetect row1; // 7 tone detectors are needed
AudioAnalyzeToneDetect row2; // to receive DTMF dial tones
AudioAnalyzeToneDetect row3;
AudioAnalyzeToneDetect row4;
AudioAnalyzeToneDetect column1;
AudioAnalyzeToneDetect column2;
AudioAnalyzeToneDetect column3;
AudioSynthWaveform sine1(AudioWaveformSine); // 2 sine wave
AudioSynthWaveform sine2(AudioWaveformSine); // to create DTMF
AudioMixer4 mixer;
AudioOutputI2S audioOut;

// Create Audio connections between the components
//
AudioConnection c01(audioIn, 0, row1, 0);
AudioConnection c02(audioIn, 0, row2, 0);
AudioConnection c03(audioIn, 0, row3, 0);
AudioConnection c04(audioIn, 0, row4, 0);
AudioConnection c05(audioIn, 0, column1, 0);
AudioConnection c06(audioIn, 0, column2, 0);
AudioConnection c07(audioIn, 0, column3, 0);
AudioConnection c10(sine1, 0, mixer, 0);
AudioConnection c11(sine2, 0, mixer, 1);
AudioConnection c12(mixer, 0, audioOut, 0);
AudioConnection c13(mixer, 0, audioOut, 1);

// Create an object to control the audio shield.
//
AudioControlSGTL5000 audioShield;


void setup() {
// Audio connections require memory to work. For more
// detailed information, see the MemoryAndCpuUsage example
AudioMemory(12);

// Enable the audio shield and set the output volume.
audioShield.enable();
audioShield.volume(82);
while (!Serial) ;
delay(100);
// Configure the tone detectors with the frequency and number
// of cycles to match. These numbers were picked for match
// times of approx 30 ms. Longer times are more precise.
row1.frequency(697, 21);
row2.frequency(770, 23);
row3.frequency(852, 25);
row4.frequency(941, 28);
column1.frequency(1209, 36);
column2.frequency(1336, 40);
column3.frequency(1477, 44);
}

const float row_threshold = 0.2;
const float column_threshold = 0.2;

void loop() {
float r1, r2, r3, r4, c1, c2, c3;
char digit=0;

// read all seven tone detectors
r1 = row1.read();
r2 = row2.read();
r3 = row3.read();
r4 = row4.read();
c1 = column1.read();
c2 = column2.read();
c3 = column3.read();

// print the raw data, for troubleshooting
Serial.print("tones: ");
Serial.print(r1);
Serial.print(", ");
Serial.print(r2);
Serial.print(", ");
Serial.print(r3);
Serial.print(", ");
Serial.print(r4);
Serial.print(", ");
Serial.print(c1);
Serial.print(", ");
Serial.print(c2);
Serial.print(", ");
Serial.print(c3);

// check all 12 combinations for key press
if (r1 >= row_threshold) {
if (c1 > column_threshold) {
digit = '1';
} else if (c2 > column_threshold) {
digit = '2';
} else if (c3 > column_threshold) {
digit = '3';
}
} else if (r2 >= row_threshold) {
if (c1 > column_threshold) {
digit = '4';
} else if (c2 > column_threshold) {
digit = '5';
} else if (c3 > column_threshold) {
digit = '6';
}
} else if (r3 >= row_threshold) {
if (c1 > column_threshold) {
digit = '7';
} else if (c2 > column_threshold) {
digit = '8';
} else if (c3 > column_threshold) {
digit = '9';
}
} else if (r4 >= row_threshold) {
if (c1 > column_threshold) {
digit = '*';
} else if (c2 > column_threshold) {
digit = '0';
} else if (c3 > column_threshold) {
digit = '#';
}
}

// print the key, if any found
if (digit > 0) {
Serial.print(" --> Key: ");
Serial.print(digit);
}
Serial.println();

// uncomment these lines to see how much CPU time
// the tone detectors and audio library are using
//Serial.print("CPU=");
//Serial.print(AudioProcessorUsage());
//Serial.print("%, max=");
//Serial.print(AudioProcessorUsageMax());
//Serial.print("% ");

// check if any data has arrived from the serial monitor
if (Serial.available()) {
char key = Serial.read();
int low=0;
int high=0;
if (key == '1') {
low = 697;
high = 1209;
} else if (key == '2') {
low = 697;
high = 1336;
} else if (key == '3') {
low = 697;
high = 1477;
} else if (key == '4') {
low = 770;
high = 1209;
} else if (key == '5') {
low = 770;
high = 1336;
} else if (key == '6') {
low = 770;
high = 1477;
} else if (key == '7') {
low = 852;
high = 1209;
} else if (key == '8') {
low = 852;
high = 1336;
} else if (key == '9') {
low = 852;
high = 1477;
} else if (key == '*') {
low = 941;
high = 1209;
} else if (key == '0') {
low = 941;
high = 1336;
} else if (key == '#') {
low = 941;
high = 1477;
}

// play the DTMF tones, if characters send from the Arduino Serial Monitor
if (low > 0 && high > 0) {
Serial.print("Output sound for key ");
Serial.print(key);
Serial.print(", low freq=");
Serial.print(low);
Serial.print(", high freq=");
Serial.print(high);
Serial.println();
AudioNoInterrupts(); // disable audio library momentarily
sine1.frequency(low);
sine1.amplitude(0.4);
sine2.frequency(high);
sine2.amplitude(0.45);
AudioInterrupts(); // enable, both tones will start together
delay(100); // let the sound play for 0.1 second
AudioNoInterrupts();
sine1.amplitude(0);
sine2.amplitude(0);
AudioInterrupts();
delay(50); // make sure we have 0.05 second silence after
}
}

delay(25);
}



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