/* BasicGain Created: Chip Audette, Nov 2016 Purpose: Process audio by applying gain. Demonstrates audio processing using floating point data type. Uses Teensy Audio Adapter. Assumes microphones (or whatever) are attached to the LINE IN (stereo) Use potentiometer mounted to Audio Board to control the amount of gain. MIT License. use at your own risk. */ //These are the includes from the Teensy Audio Library #include //Teensy Audio Library #include #include #include #include #include //for AudioConvert_I16toF32, AudioConvert_F32toI16, and AudioEffectGain_F32 //create audio library objects for handling the audio AudioControlSGTL5000 sgtl5000_1; //controller for the Teensy Audio Board AudioInputI2S i2s_in; //Digital audio *from* the Teensy Audio Board ADC. Sends Int16. Stereo. AudioOutputI2S i2s_out; //Digital audio *to* the Teensy Audio Board DAC. Expects Int16. Stereo AudioConvert_I16toF32 int2Float1, int2Float2; //Converts Int16 to Float. See class in AudioStream_F32.h AudioEffectGain_F32 gain1, gain2; //Applies digital gain to audio data. Expected Float data. AudioConvert_F32toI16 float2Int1, float2Int2; //Converts Float to Int16. See class in AudioStream_F32.h //Make all of the audio connections AudioConnection patchCord1(i2s_in, 0, int2Float1, 0); //connect the Left input to the Left Int->Float converter AudioConnection patchCord2(i2s_in, 1, int2Float2, 0); //connect the Right input to the Right Int->Float converter AudioConnection_F32 patchCord10(int2Float1, 0, gain1, 0); //Left. makes Float connections between objects AudioConnection_F32 patchCord11(int2Float2, 0, gain2, 0); //Right. makes Float connections between objects AudioConnection_F32 patchCord12(gain1, 0, float2Int1, 0); //Left. makes Float connections between objects AudioConnection_F32 patchCord13(gain2, 0, float2Int2, 0); //Right. makes Float connections between objects AudioConnection patchCord20(float2Int1, 0, i2s_out, 0); //connect the Left float processor to the Left output AudioConnection patchCord21(float2Int2, 0, i2s_out, 1); //connect the Right float processor to the Right output // which input on the audio shield will be used? const int myInput = AUDIO_INPUT_LINEIN; //const int myInput = AUDIO_INPUT_MIC; //I have a potentiometer on the Teensy Audio Board #define POT_PIN A1 //potentiometer is tied to this pin // define the setup() function, the function that is called once when the device is booting void setup() { Serial.begin(115200); //open the USB serial link to enable debugging messages delay(500); //give the computer's USB serial system a moment to catch up. Serial.println("OpenAudio_ArduinoLibrary BasicGain_Float..."); // Audio connections require memory AudioMemory(10); //allocate Int16 audio data blocks AudioMemory_F32(10); //allocate Float32 audio data blocks // Enable the audio shield, select input, and enable output sgtl5000_1.enable(); //start the audio board sgtl5000_1.inputSelect(myInput); //choose line-in or mic-in sgtl5000_1.volume(0.8); //volume can be 0.0 to 1.0. 0.5 seems to be the usual default. sgtl5000_1.lineInLevel(10,10); //level can be 0 to 15. 5 is the Teensy Audio Library's default sgtl5000_1.adcHighPassFilterDisable(); //reduces noise. https://forum.pjrc.com/threads/27215-24-bit-audio-boards?p=78831&viewfull=1#post78831 // setup any other other features pinMode(POT_PIN, INPUT); //set the potentiometer's input pin as an INPUT } //end setup() // define the loop() function, the function that is repeated over and over for the life of the device unsigned long updatePeriod_millis = 100; //how many milliseconds between updating gain reading? unsigned long lastUpdate_millis = 0; unsigned long curTime_millis = 0; int prev_gain_dB = 0; void loop() { //choose to sleep ("wait for interrupt") instead of spinning our wheels doing nothing but consuming power asm(" WFI"); //ARM-specific. Will wake on next interrupt. The audio library issues tons of interrupts, so we wake up often. //has enough time passed to try updating the GUI? curTime_millis = millis(); //what time is it right now if (curTime_millis < lastUpdate_millis) lastUpdate_millis = 0; //handle wrap-around of the clock if ((curTime_millis - lastUpdate_millis) > updatePeriod_millis) { //is it time to update the user interface? //read potentiometer float val = float(analogRead(POT_PIN)) / 1024.0; //0.0 to 1.0 val = 0.1*(float)((int)(10.0*val + 0.5)); //quantize so that it doesn't chatter //compute desired digital gain const float min_gain_dB = -20.0, max_gain_dB = 40.0; //set desired gain range float gain_dB = min_gain_dB + (max_gain_dB - min_gain_dB)*val; //computed desired gain value in dB //if the gain is different than before, set the new gain value if (abs(gain_dB - prev_gain_dB) > 1.0) { //is it different than before gain1.setGain_dB(gain_dB); //set the gain of the Left-channel gain processor gain2.setGain_dB(gain_dB); //set the gain of the Right-channel gain processor Serial.print("Digital Gain dB = "); Serial.println(gain_dB); //print text to Serial port for debugging prev_gain_dB = gain_dB; //we will use this value the next time around } lastUpdate_millis = curTime_millis; //we will use this value the next time around. } // end if } //end loop();