// Record sound as raw data to a SD card, and play it back. // // Requires the audio shield: // http://www.pjrc.com/store/teensy3_audio.html // // Three pushbuttons need to be connected: // Record Button: pin 0 to GND // Stop Button: pin 1 to GND // Play Button: pin 2 to GND // // This example code is in the public domain. #include #include #include #include #include #include // GUItool: begin automatically generated code AudioInputI2S i2s2; //xy=105,63 AudioAnalyzePeak peak1; //xy=278,108 AudioRecordQueue queue1; //xy=281,63 AudioPlaySdRaw playRaw1; //xy=302,157 AudioOutputI2S i2s1; //xy=470,120 AudioConnection patchCord1(i2s2, 0, queue1, 0); AudioConnection patchCord2(i2s2, 0, peak1, 0); AudioConnection patchCord3(playRaw1, 0, i2s1, 0); AudioConnection patchCord4(playRaw1, 0, i2s1, 1); AudioControlSGTL5000 sgtl5000_1; //xy=265,212 // GUItool: end automatically generated code // For a stereo recording version, see this forum thread: // https://forum.pjrc.com/threads/46150?p=158388&viewfull=1#post158388 // A much more advanced sound recording and data logging project: // https://github.com/WMXZ-EU/microSoundRecorder // https://github.com/WMXZ-EU/microSoundRecorder/wiki/Hardware-setup // https://forum.pjrc.com/threads/52175?p=185386&viewfull=1#post185386 // Bounce objects to easily and reliably read the buttons Bounce buttonRecord = Bounce(0, 8); Bounce buttonStop = Bounce(1, 8); // 8 = 8 ms debounce time Bounce buttonPlay = Bounce(2, 8); // which input on the audio shield will be used? const int myInput = AUDIO_INPUT_LINEIN; //const int myInput = AUDIO_INPUT_MIC; // Use these with the Teensy Audio Shield #define SDCARD_CS_PIN 10 #define SDCARD_MOSI_PIN 7 #define SDCARD_SCK_PIN 14 // Use these with the Teensy 3.5 & 3.6 SD card //#define SDCARD_CS_PIN BUILTIN_SDCARD //#define SDCARD_MOSI_PIN 11 // not actually used //#define SDCARD_SCK_PIN 13 // not actually used // Use these for the SD+Wiz820 or other adaptors //#define SDCARD_CS_PIN 4 //#define SDCARD_MOSI_PIN 11 //#define SDCARD_SCK_PIN 13 // Remember which mode we're doing int mode = 0; // 0=stopped, 1=recording, 2=playing // The file where data is recorded File frec; void setup() { // Configure the pushbutton pins pinMode(0, INPUT_PULLUP); pinMode(1, INPUT_PULLUP); pinMode(2, INPUT_PULLUP); // Audio connections require memory, and the record queue // uses this memory to buffer incoming audio. AudioMemory(60); // Enable the audio shield, select input, and enable output sgtl5000_1.enable(); sgtl5000_1.inputSelect(myInput); sgtl5000_1.volume(0.5); // Initialize the SD card SPI.setMOSI(SDCARD_MOSI_PIN); SPI.setSCK(SDCARD_SCK_PIN); if (!(SD.begin(SDCARD_CS_PIN))) { // stop here if no SD card, but print a message while (1) { Serial.println("Unable to access the SD card"); delay(500); } } } void loop() { // First, read the buttons buttonRecord.update(); buttonStop.update(); buttonPlay.update(); // Respond to button presses if (buttonRecord.fallingEdge()) { Serial.println("Record Button Press"); if (mode == 2) stopPlaying(); if (mode == 0) startRecording(); } if (buttonStop.fallingEdge()) { Serial.println("Stop Button Press"); if (mode == 1) stopRecording(); if (mode == 2) stopPlaying(); } if (buttonPlay.fallingEdge()) { Serial.println("Play Button Press"); if (mode == 1) stopRecording(); if (mode == 0) startPlaying(); } // If we're playing or recording, carry on... if (mode == 1) { continueRecording(); } if (mode == 2) { continuePlaying(); } // when using a microphone, continuously adjust gain if (myInput == AUDIO_INPUT_MIC) adjustMicLevel(); } void startRecording() { Serial.println("startRecording"); if (SD.exists("RECORD.RAW")) { // The SD library writes new data to the end of the // file, so to start a new recording, the old file // must be deleted before new data is written. SD.remove("RECORD.RAW"); } frec = SD.open("RECORD.RAW", FILE_WRITE); if (frec) { queue1.begin(); mode = 1; } } void continueRecording() { if (queue1.available() >= 2) { byte buffer[512]; // Fetch 2 blocks from the audio library and copy // into a 512 byte buffer. The Arduino SD library // is most efficient when full 512 byte sector size // writes are used. memcpy(buffer, queue1.readBuffer(), 256); queue1.freeBuffer(); memcpy(buffer+256, queue1.readBuffer(), 256); queue1.freeBuffer(); // write all 512 bytes to the SD card elapsedMicros usec = 0; frec.write(buffer, 512); // Uncomment these lines to see how long SD writes // are taking. A pair of audio blocks arrives every // 5802 microseconds, so hopefully most of the writes // take well under 5802 us. Some will take more, as // the SD library also must write to the FAT tables // and the SD card controller manages media erase and // wear leveling. The queue1 object can buffer // approximately 301700 us of audio, to allow time // for occasional high SD card latency, as long as // the average write time is under 5802 us. //Serial.print("SD write, us="); //Serial.println(usec); } } void stopRecording() { Serial.println("stopRecording"); queue1.end(); if (mode == 1) { while (queue1.available() > 0) { frec.write((byte*)queue1.readBuffer(), 256); queue1.freeBuffer(); } frec.close(); } mode = 0; } void startPlaying() { Serial.println("startPlaying"); playRaw1.play("RECORD.RAW"); mode = 2; } void continuePlaying() { if (!playRaw1.isPlaying()) { playRaw1.stop(); mode = 0; } } void stopPlaying() { Serial.println("stopPlaying"); if (mode == 2) playRaw1.stop(); mode = 0; } void adjustMicLevel() { // TODO: read the peak1 object and adjust sgtl5000_1.micGain() // if anyone gets this working, please submit a github pull request :-) }