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219 lines
9.5 KiB
219 lines
9.5 KiB
// FormantShifter_FD
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//
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// Demonstrate formant shifting via frequency domain processin.
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//
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// Created: Chip Audette (OpenAudio) March 2019
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//
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// Approach:
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// * Take samples in the time domain
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// * Take FFT to convert to frequency domain
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// * Manipulate the frequency bins to do the formant shifting
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// * Take IFFT to convert back to time domain
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// * Send samples back to the audio interface
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//
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// The amount of formant shifting is controled via the Serial link.
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// It defaults to a modest upward shifting of the formants
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//
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// Built for the Tympan library for Teensy 3.6-based hardware
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//
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// MIT License. Use at your own risk.
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//
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#include <Tympan_Library.h>
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#include "AudioEffectFormantShiftFD_F32.h" //the local file holding your custom function
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#include "SerialManager.h"
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//set the sample rate and block size
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const float sample_rate_Hz = 44117.f; ; //24000 or 44117 (or other frequencies in the table in AudioOutputI2S_F32)
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const int audio_block_samples = 128; //for freq domain processing choose a power of 2 (16, 32, 64, 128) but no higher than 128
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AudioSettings_F32 audio_settings(sample_rate_Hz, audio_block_samples);
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//create audio library objects for handling the audio
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Tympan audioHardware(TympanRev::D); //do TympanRev::C or TympanRev::D
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AudioInputI2S_F32 i2s_in(audio_settings); //Digital audio *from* the Tympan AIC.
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AudioEffectFormantShiftFD_F32 formantShift(audio_settings); //create the frequency-domain processing block
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AudioEffectGain_F32 gain1; //Applies digital gain to audio data.
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AudioOutputI2S_F32 i2s_out(audio_settings); //Digital audio out *to* the Tympan AIC.
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//Make all of the audio connections
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AudioConnection_F32 patchCord1(i2s_in, 0, formantShift, 0); //use the Left input
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AudioConnection_F32 patchCord2(formantShift, 0, gain1, 0); //connect to gain
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AudioConnection_F32 patchCord3(gain1, 0, i2s_out, 0); //connect to the left output
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AudioConnection_F32 patchCord4(gain1, 0, i2s_out, 1); //connect to the right output
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//control display and serial interaction
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bool enable_printCPUandMemory = false;
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void togglePrintMemoryAndCPU(void) { enable_printCPUandMemory = !enable_printCPUandMemory; };
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SerialManager serialManager(audioHardware);
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#define mySerial audioHardware //audioHardware is a printable stream!
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//inputs and levels
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float input_gain_dB = 20.0f; //gain on the microphone
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float formant_shift_gain_correction_dB = 0.0; //will be used to adjust for gain in formant shifter
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float vol_knob_gain_dB = 0.0; //will be overridden by volume knob
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void switchToPCBMics(void) {
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mySerial.println("Switching to PCB Mics.");
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audioHardware.inputSelect(TYMPAN_INPUT_ON_BOARD_MIC); // use the microphone jack - defaults to mic bias OFF
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audioHardware.setInputGain_dB(input_gain_dB);
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}
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void switchToLineInOnMicJack(void) {
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mySerial.println("Switching to Line-in on Mic Jack.");
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audioHardware.inputSelect(TYMPAN_INPUT_JACK_AS_LINEIN); // use the microphone jack - defaults to mic bias OFF
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audioHardware.setInputGain_dB(0.0);
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}
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void switchToMicInOnMicJack(void) {
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mySerial.println("Switching to Mic-In on Mic Jack.");
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audioHardware.inputSelect(TYMPAN_INPUT_JACK_AS_MIC); // use the microphone jack - defaults to mic bias OFF
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audioHardware.setInputGain_dB(input_gain_dB);
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}
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// define the setup() function, the function that is called once when the device is booting
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void setup() {
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audioHardware.beginBothSerial(); delay(1000);
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mySerial.println("FormantShifter: starting setup()...");
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mySerial.print(" : sample rate (Hz) = "); mySerial.println(audio_settings.sample_rate_Hz);
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mySerial.print(" : block size (samples) = "); mySerial.println(audio_settings.audio_block_samples);
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// Audio connections require memory to work. For more
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// detailed information, see the MemoryAndCpuUsage example
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AudioMemory_F32(40, audio_settings);
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// Configure the frequency-domain algorithm
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int overlap_factor = 4; //set to 4 or 8 or either 75% overlap (4x) or 87.5% overlap (8x)
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int N_FFT = audio_block_samples * overlap_factor;
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formantShift.setup(audio_settings, N_FFT); //do after AudioMemory_F32();
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formantShift.setScaleFactor(1.5); //1.0 is no formant shifting.
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if (overlap_factor == 4) {
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formant_shift_gain_correction_dB = -3.0;
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} else if (overlap_factor == 8) {
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formant_shift_gain_correction_dB = -9.0;
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}
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//Enable the Tympan to start the audio flowing!
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audioHardware.enable(); // activate AIC
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//setup DC-blocking highpass filter running in the ADC hardware itself
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float cutoff_Hz = 60.0; //set the default cutoff frequency for the highpass filter
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audioHardware.setHPFonADC(true,cutoff_Hz,audio_settings.sample_rate_Hz); //set to false to disble
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//Choose the desired input
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switchToPCBMics(); //use PCB mics as input
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//switchToMicInOnMicJack(); //use Mic jack as mic input (ie, with mic bias)
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//switchToLineInOnMicJack(); //use Mic jack as line input (ie, no mic bias)
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//Set the desired volume levels
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audioHardware.volume_dB(0); // headphone amplifier. -63.6 to +24 dB in 0.5dB steps.
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// configure the blue potentiometer
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servicePotentiometer(millis(),0); //update based on the knob setting the "0" is not relevant here.
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//finish the setup by printing the help menu to the serial connections
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serialManager.printHelp();
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}
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// define the loop() function, the function that is repeated over and over for the life of the device
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void loop() {
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//respond to Serial commands
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while (Serial.available()) serialManager.respondToByte((char)Serial.read()); //USB Serial
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//while (Serial1.available()) serialManager.respondToByte((char)Serial1.read()); //BT Serial
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//check the potentiometer
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servicePotentiometer(millis(), 100); //service the potentiometer every 100 msec
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//check to see whether to print the CPU and Memory Usage
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if (enable_printCPUandMemory) printCPUandMemory(millis(), 3000); //print every 3000 msec
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} //end loop();
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// ///////////////// Servicing routines
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//servicePotentiometer: listens to the blue potentiometer and sends the new pot value
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// to the audio processing algorithm as a control parameter
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void servicePotentiometer(unsigned long curTime_millis, const unsigned long updatePeriod_millis) {
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//static unsigned long updatePeriod_millis = 100; //how many milliseconds between updating the potentiometer reading?
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static unsigned long lastUpdate_millis = 0;
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static float prev_val = -1.0;
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//has enough time passed to update everything?
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if (curTime_millis < lastUpdate_millis) lastUpdate_millis = 0; //handle wrap-around of the clock
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if ((curTime_millis - lastUpdate_millis) > updatePeriod_millis) { //is it time to update the user interface?
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//read potentiometer
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float val = float(audioHardware.readPotentiometer()) / 1023.0; //0.0 to 1.0
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val = (1.0/9.0) * (float)((int)(9.0 * val + 0.5)); //quantize so that it doesn't chatter...0 to 1.0
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//use the potentiometer value to control something interesting
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if (abs(val - prev_val) > 0.05) { //is it different than befor?
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prev_val = val; //save the value for comparison for the next time around
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#if 0
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//set the volume of the system
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setVolKnobGain_dB(val*45.0f - 10.0f - input_gain_dB);
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#else
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//set the amount of formant shifting
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float new_scale_fac = powf(2.0,(val-0.5)*2.0);
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formantShift.setScaleFactor(new_scale_fac);
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#endif
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}
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lastUpdate_millis = curTime_millis;
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} // end if
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} //end servicePotentiometer();
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//This routine prints the current and maximum CPU usage and the current usage of the AudioMemory that has been allocated
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void printCPUandMemory(unsigned long curTime_millis, unsigned long updatePeriod_millis) {
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//static unsigned long updatePeriod_millis = 3000; //how many milliseconds between updating gain reading?
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static unsigned long lastUpdate_millis = 0;
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//has enough time passed to update everything?
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if (curTime_millis < lastUpdate_millis) lastUpdate_millis = 0; //handle wrap-around of the clock
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if ((curTime_millis - lastUpdate_millis) > updatePeriod_millis) { //is it time to update the user interface?
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mySerial.print("printCPUandMemory: ");
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mySerial.print("CPU Cur/Peak: ");
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mySerial.print(audio_settings.processorUsage());
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//mySerial.print(AudioProcessorUsage()); //if not using AudioSettings_F32
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mySerial.print("%/");
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mySerial.print(audio_settings.processorUsageMax());
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//mySerial.print(AudioProcessorUsageMax()); //if not using AudioSettings_F32
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mySerial.print("%, ");
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mySerial.print("Dyn MEM Float32 Cur/Peak: ");
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mySerial.print(AudioMemoryUsage_F32());
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mySerial.print("/");
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mySerial.print(AudioMemoryUsageMax_F32());
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mySerial.println();
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lastUpdate_millis = curTime_millis; //we will use this value the next time around.
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}
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}
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void printGainSettings(void) {
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mySerial.print("Gain (dB): ");
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mySerial.print("Vol Knob = "); mySerial.print(vol_knob_gain_dB,1);
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//mySerial.print(", Input PGA = "); mySerial.print(input_gain_dB,1);
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mySerial.println();
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}
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void incrementKnobGain(float increment_dB) { //"extern" to make it available to other files, such as SerialManager.h
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setVolKnobGain_dB(vol_knob_gain_dB+increment_dB);
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}
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void setVolKnobGain_dB(float gain_dB) {
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vol_knob_gain_dB = gain_dB;
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gain1.setGain_dB(vol_knob_gain_dB+formant_shift_gain_correction_dB);
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printGainSettings();
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}
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float incrementFormantShift(float incr_factor) {
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float cur_scale_factor = formantShift.getScaleFactor();
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return formantShift.setScaleFactor(cur_scale_factor*incr_factor);
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}
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