/* SignalNoise_float.ino Bob Larkin 19 June 2020 * * Generate White Noise, Pink Noise, Gaussian White Noise and a Sine Wave * Combine all four in a adding "mixer", send to Codec and to peak/rms. * * Following is for all objects enabled (amplitudes non-zero) * T3.6 Processor load, measured: 10.6% * T4.0 Processor load, measured: 3.2% */ #include "Audio.h" #include "OpenAudio_ArduinoLibrary.h" // To work with T4.0 the I2S routine outputs 16-bit integer (I16). Then // use Audette I16 to F32 convert. Same below for output, in reverse. AudioInputI2S in1; AudioSynthNoisePink_F32 pink1; AudioSynthNoiseWhite_F32 white1; AudioSynthGaussian_F32 gaussian1; AudioSynthWaveformSine_F32 sine1; AudioMixer4_F32 sum1; AudioConvert_F32toI16 cnvrt1; // Left AudioConvert_F32toI16 cnvrt2; // Right AudioOutputI2S i2sOut; AudioAnalyzePeak_F32 peak1; AudioAnalyzeRMS_F32 rms1; AudioControlSGTL5000 codec; AudioConnection_F32 connect1(pink1, 0, sum1, 0); AudioConnection_F32 connect2(white1, 0, sum1, 1); AudioConnection_F32 connect3(gaussian1, 0, sum1, 2); AudioConnection_F32 connect4(sine1, 0, sum1, 3); AudioConnection_F32 connect6(sum1, 0, cnvrt1, 0); // Out to the CODEC left AudioConnection_F32 connect7(sum1, 0, cnvrt2, 0); // and right AudioConnection_F32 connect8(sum1, 0, peak1, 0); AudioConnection_F32 connect9(sum1, 0, rms1, 0); AudioConnection conI16_2(cnvrt1, 0, i2sOut, 0); // DAC L AudioConnection conI16_3(cnvrt2, 0, i2sOut, 1); // DAC R // ********* Mini Control Panel ********* // Off/On switches, 0 for off, 1 for on #define WHITE 0 #define PINK 0 #define GAUSSIAN 1 #define SINE 1 int gainControlDB = -35; // Set gain in dB. // ***************************************** void setup(void) { float32_t gain; AudioMemory(10); AudioMemory_F32(10); for (int i=0; i<4; i++) sum1.gain(i, 0.0); // All off Serial.begin(1); delay(1000); gain = powf( 10.0f, (gainControlDB/20.0f) ); white1.amplitude(0.5f); gaussian1.amplitude(0.5f); sine1.frequency(1000.0f); sine1.amplitude(0.2f); codec.enable(); delay(10); if(PINK) sum1.gain(0, gain); else sum1.gain(0, 0.0f); if(WHITE) sum1.gain(1, gain); else sum1.gain(1, 0.0f); if(GAUSSIAN) sum1.gain(2, gain); else sum1.gain(2, 0.0f); if(SINE) sum1.gain(3, gain); else sum1.gain(3, 0.0f); } void loop(void) { // Here is where the adjustment of the volume control could go. // And anything else that needs regular attention, other // than the audio stream. if (rms1.available() ) {Serial.print("RMS ="); Serial.println(rms1.read(), 6);} if (peak1.available() ) {Serial.print("P-P ="); Serial.println(peak1.readPeakToPeak(), 6);} Serial.print("CPU: Percent Usage, Max: "); Serial.print(AudioProcessorUsage()); Serial.print(", "); Serial.print(AudioProcessorUsageMax()); Serial.print(" "); Serial.print("Int16 Memory: "); Serial.print(AudioMemoryUsage()); Serial.print(", "); Serial.print(AudioMemoryUsageMax()); Serial.print(" "); Serial.print("Float Memory: "); Serial.print(AudioMemoryUsage_F32()); Serial.print(", "); Serial.println(AudioMemoryUsageMax_F32()); Serial.println(); delay(1000); }