Test examples added for WAV files from microSD cards

pull/16/merge
boblark 2 years ago
parent 624f14283e
commit 3319cfa8cb
  1. 177
      examples/WavFilePlayer/WavFilePlayer.ino
  2. 133
      examples/WavFilePlayer2/WavFilePlayer2.ino

@ -0,0 +1,177 @@
// WavFilePlayer.ino
//
// WAV file player, mono, multi-rate example
// Output is Digital I2S - Used with the audio shield:
//
// The SD card may connect to different pins, depending on the
// hardware you are using. Configure the SD card
// pins to match your hardware. It is set for T4.x Rev D PJRC
// Teensy Audio Adaptor card here.
//
// Your microSD card must have the WAV files loaded to it:
// W9GR48.WAV
// W9GR12.WAV
// These are at
// https://github.com/chipaudette/OpenAudio_ArduinoLibrary/blob/master/utility/
//
// INO based on PJRC file of the same name, but converted to work with the
// OpenAudio_ArduinoLibrary with floating point F32 audio.
// Provision has been added for
// WAV files with sub-multiple sampling rates, relative to Audio rate.
// The latter adds an optional .INO defined FIR filter just before the
// audio is transmitted from the AudioSDPlayer_F32 update function. This
// filter is needed for sub-multiple WAV rates, but is available for any
// place it is helpful. Comments to Bob Larkin. Jan 2023
//
// This example is monoraural only, but demonstrates 12 ksps sampling
// in the WAV file. See the other example, wavPlayerStereo.ino
// that uses stereo files, like the original I16 library
// example did.
// This example code is in the public domain.
#include <Audio.h>
#include <Wire.h>
#include <SPI.h>
#include <SD.h>
#include "OpenAudio_ArduinoLibrary.h"
// This INO is setup to run audio sample rate at 48 ksps but the WAV file
// can be either 48 ksps or 12 ksps. There are multiple W9GR files at different
// sample rates. Select by SUB_MULT of 1 or 4.
#define SUB_MULT 1
// T3.x supported sample rates: 2000, 8000, 11025, 16000, 22050, 24000, 32000, 44100, 44117, 48000,
// 88200, 88235 (44117*2), 95680, 96000, 176400, 176470, 192000
// T4.x supports any sample rate the codec will hanedle.
const float sample_rate_Hz = 48000.0f;
const int audio_block_samples = 128; // Always 128, which is AUDIO_BLOCK_SAMPLES from AudioStream.h
AudioSettings_F32 audio_settings(sample_rate_Hz, audio_block_samples);
AudioSDPlayer_F32 playWav1(audio_settings);
AudioAnalyzeRMS_F32 rms1;
AudioAnalyzeRMS_F32 rms2;
AudioOutputI2S_F32 audioOutput(audio_settings);
AudioConnection_F32 patchCord1(playWav1, 0, audioOutput, 0);
AudioConnection_F32 patchCord3(playWav1, 0, rms1, 0);
AudioConnection_F32 patchCord4(playWav1, 1, rms2, 0);
AudioConnection_F32 patchCord2(playWav1, 1, audioOutput, 1);
AudioControlSGTL5000 sgtl5000_1;
// Use these with the Teensy 4.x Rev D Audio Shield (NOT for T3.x)
#define SDCARD_CS_PIN 10
#define SDCARD_MOSI_PIN 11
#define SDCARD_SCK_PIN 13
#if SUB_MULT==4
/* This filter is a LPF to smooth out the zero data added for interpolation
* of the sample rate. It is a
* FIR filter designed with http://t-filter.appspot.com
* Sampling frequency: 48000 Hz
* 0 Hz - 3000 Hz ripple = 0.12 dB
* 6000 Hz - 24000 Hz atten min = -62.17 dB */
static float32_t fir3k48k[45] = {
-0.00111325f,-0.00202997f,-0.00306939f,-0.00351866f,-0.00274389f,-0.00035614f,
0.00346572f, 0.00778335f, 0.01098197f, 0.01119770f, 0.00702222f,-0.00172373f,
-0.01344104f,-0.02471188f,-0.03091211f,-0.02741134f,-0.01105157f, 0.01854769f,
0.05833902f, 0.10214361f, 0.14192191f, 0.16971322f, 0.17968923f, 0.16971322f,
0.14192191f, 0.10214361f, 0.05833902f, 0.01854769f,-0.01105157f,-0.02741134f,
-0.03091211f,-0.02471188f,-0.01344104f,-0.00172373f, 0.00702222f, 0.01119770f,
0.01098197f, 0.00778335f, 0.00346572f,-0.00035614f,-0.00274389f,-0.00351866f,
-0.00306939f,-0.00202997f,-0.00111325f};
// CMSIS FIR requires the following buffers
float32_t firBufferL[128+45-1];
float32_t firBufferR[128+45-1];
#endif
/* subMult is a global struct definition from AudioSDPlayer_F32.h
* struct subMult {
* uint16_t rateRatio; // Should be 1 for no rate change, else 2, 4, 8
* uint16_t numCoeffs; // FIR filter for interpolation
* float32_t* firCoeffs; // FIR Filter Coeffs
* float32_t* firBufferL; // pointer to 127 + numCoeffs float32_t, left ch
* float32_t* firBufferR; // pointer to 127 + numCoeffs float32_t, right ch
* };
*/
#if SUB_MULT==4
// Both buffers are left for mono.
struct subMult wavQuarter = {4, 45, fir3k48k, firBufferL, firBufferL};
// Next a sample of subMult for no interpolation and no FIR filter
#else
struct subMult wavQuarter = {1, 0, NULL, NULL, NULL};
#endif
// And next is a sample of no interpolation, but borrowing the FIR filter
// for some non-interpolation reason.
// struct subMult wavQuarter = {1, 45, fir3k48k, firBufferL, firBufferL};
// wavData is a global struct, definined in AudioSDPlayer_F32.h
// This provides information about the current WAV file to this .INO
struct wavData* pCurrentWavData;
void setup() { // ********** SETUP **********
Serial.begin(9600); delay(1000);
Serial.println("*** F32 WAV from SD Card ***");
AudioMemory_F32(30, audio_settings);
pCurrentWavData = playWav1.getCurrentWavData();
sgtl5000_1.enable();
audioOutput.setGain(0.05); // <<< Output volume control
SPI.setMOSI(SDCARD_MOSI_PIN);
SPI.setSCK(SDCARD_SCK_PIN);
Serial.print("SD.begin() returns "); Serial.println(SD.begin(SDCARD_CS_PIN));
}
void playFile(const char *filename)
{
Serial.println("");
Serial.print("Playing file: ");
Serial.println(filename);
// Allow for running the WAV file at a sub-rate from the Audio rate
// Two of these are defined above for 1 and 4 sub rates.
playWav1.setSubMult(&wavQuarter);
// Start playing the file. This sketch continues to
// run while the file plays.
playWav1.play(filename);
// A brief delay for the library read WAV info
delay(25);
Serial.print("WAV file format = "); Serial.println(pCurrentWavData->audio_format);
Serial.print("WAV number channels = "); Serial.println(pCurrentWavData->num_channels);
Serial.print("WAV File Sample Rate = "); Serial.println(pCurrentWavData->sample_rate);
Serial.print("Number of bits per Sample = "); Serial.println(pCurrentWavData->bits);
Serial.print("File length, seconds = ");
Serial.println(0.001f*(float32_t)playWav1.lengthMillis(), 3);
// Simply wait for the file to finish playing.
while (playWav1.isPlaying())
{
Serial.print("RMS ");
delay(1000);
if(rms1.available())
Serial.print(rms1.read(),5);
Serial.print(" L R ");
if(rms2.available())
Serial.print(rms2.read(),5);
// Time in seconds
Serial.print(" t=");
Serial.println(0.001f*(float32_t)playWav1.positionMillis(), 3);
}
Serial.println("");
}
void loop() {
#if SUB_MULT==4
playFile("W9GR12.WAV"); // filenames are always uppercase 8.3 format
#elif SUB_MULT==1
playFile("W9GR48.WAV");
#else
Serial.println("**** Non-used SUB_MULT. Use 1 or 4. ****");
#endif
delay(500);
}

@ -0,0 +1,133 @@
// WavFilePlayer2.ino
//
// WAV file player, stereo, 44.1 ksps example
// Output is Digital I2S - Used with the audio shield:
//
// The SD card may connect to different pins, depending on the
// hardware you are using. Configure the SD card
// pins to match your hardware. It is set for T4.x Rev D PJRC
// Teensy Audio Adaptor card here.
//
// Your microSD card must have the WAV files loaded to it:
// SDTEST1.WAV
// SDTEST2.WAV
// SDTEST3.WAV
// SDTEST4.WAV
// These are PJRC Teensy I16 library test files and are at
// http://www.pjrc.com/teensy/td_libs_AudioDataFiles.html
//
// INO based on PJRC file of the same name, but converted to work with the
// OpenAudio_ArduinoLibrary with floating point F32 audio.
// Provision has been added for
// WAV files with sub-multiple sampling rates, relative to Audio rate.
// The latter adds an optional .INO defined FIR filter just before the
// audio is transmitted from the AudioSDPlayer_F32 update function. This
// filter is needed for sub-multiple WAV rates, but is available for any
// place it is helpful. Comments to Bob Larkin. Jan 2023
//
// This example is stereo only, but demonstrates 12 ksps sampling
// in the WAV file. See the other example, wavPlayer.ino
// that uses monaural files with 2 different sample rates.
//
// This example code is in the public domain.
#include <Audio.h>
#include <Wire.h>
#include <SPI.h>
#include <SD.h>
#include "OpenAudio_ArduinoLibrary.h"
// This INO is setup to run audio sample rate at 44.1 ksps
// T3.x supported sample rates: 2000, 8000, 11025, 16000, 22050, 24000, 32000, 44100, 44117, 48000,
// 88200, 88235 (44117*2), 95680, 96000, 176400, 176470, 192000
// T4.x supports any sample rate the codec will hanedle.
const float sample_rate_Hz = 44100.0f;
const int audio_block_samples = 128; // Always 128, which is AUDIO_BLOCK_SAMPLES from AudioStream.h
AudioSettings_F32 audio_settings(sample_rate_Hz, audio_block_samples);
AudioSDPlayer_F32 playWav1(audio_settings);
AudioAnalyzeRMS_F32 rms1;
AudioAnalyzeRMS_F32 rms2;
AudioOutputI2S_F32 audioOutput(audio_settings);
AudioConnection_F32 patchCord1(playWav1, 0, audioOutput, 0);
AudioConnection_F32 patchCord3(playWav1, 0, rms1, 0);
AudioConnection_F32 patchCord4(playWav1, 1, rms2, 0);
AudioConnection_F32 patchCord2(playWav1, 1, audioOutput, 1);
AudioControlSGTL5000 sgtl5000_1;
// Use these with the Teensy 4.x Rev D Audio Shield (NOT for T3.x)
#define SDCARD_CS_PIN 10
#define SDCARD_MOSI_PIN 11
#define SDCARD_SCK_PIN 13
// subMult allows slower rates for the WAV files. Not used here
//struct subMult wavNormal = {1, 0, NULL, NULL, NULL};
// wavData is a global struct, definined in AudioSDPlayer_F32.h
// This provides information about the current WAV file to this .INO
struct wavData* pCurrentWavData;
void setup() { // ********** SETUP **********
Serial.begin(9600); delay(1000);
Serial.println("*** F32 WAV from SD Card ***");
AudioMemory_F32(30, audio_settings);
pCurrentWavData = playWav1.getCurrentWavData();
sgtl5000_1.enable();
audioOutput.setGain(0.05); // <<< Output volume control
SPI.setMOSI(SDCARD_MOSI_PIN);
SPI.setSCK(SDCARD_SCK_PIN);
Serial.print("SD.begin() returns ");
Serial.println(SD.begin(SDCARD_CS_PIN)); // Opens the microSD card
}
void playFile(const char *filename) {
Serial.println("");
Serial.print("Playing file: ");
Serial.println(filename);
// Start playing the file. This sketch continues to
// run while the file plays.
playWav1.play(filename);
// A brief delay for the library read WAV info
delay(25);
Serial.print("WAV file format = "); Serial.println(pCurrentWavData->audio_format);
Serial.print("WAV number channels = "); Serial.println(pCurrentWavData->num_channels);
Serial.print("WAV File Sample Rate = "); Serial.println(pCurrentWavData->sample_rate);
Serial.print("Number of bits per Sample = "); Serial.println(pCurrentWavData->bits);
Serial.print("File length, seconds = ");
Serial.println(0.001f*(float32_t)playWav1.lengthMillis(), 3);
// Simply wait for the file to finish playing.
while (playWav1.isPlaying())
{
Serial.print("RMS ");
delay(1000);
if(rms1.available())
Serial.print(rms1.read(),5);
Serial.print(" L R ");
if(rms2.available())
Serial.print(rms2.read(),5);
// Time in seconds
Serial.print(" t=");
Serial.println(0.001f*(float32_t)playWav1.positionMillis(), 3);
}
Serial.println("");
}
void loop() {
playFile("SDTEST1.WAV"); // filenames are always uppercase 8.3 format
delay(500);
playFile("SDTEST2.WAV");
delay(500);
playFile("SDTEST3.WAV");
delay(500);
playFile("SDTEST4.WAV");
delay(500);
}
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