10 년 전 · 9b923a1d35
--- a/examples/Analysis/SpectrumAnalyzerBasic/SpectrumAnalyzerBasic.ino
+++ b/examples/Analysis/SpectrumAnalyzerBasic/SpectrumAnalyzerBasic.ino
@@ -1,51 +1,64 @@
 #include <LiquidCrystal.h>
 #include <Audio.h>
 #include <Wire.h>
 #include <SPI.h>
 #include <SD.h>
 #include <LiquidCrystal.h>

 //const int myInput = AUDIO_INPUT_LINEIN;
 const int myInput = AUDIO_INPUT_MIC;
 // GUItool: begin automatically generated code
 AudioInputI2S            i2s1;           //xy=139,91
 AudioMixer4              mixer1;         //xy=312,134
 AudioOutputI2S           i2s2;           //xy=392,32
 AudioAnalyzeFFT1024      fft1024;        //xy=467,147
 AudioConnection          patchCord1(i2s1, 0, mixer1, 0);
 AudioConnection          patchCord2(i2s1, 0, i2s2, 0);
 AudioConnection          patchCord3(i2s1, 1, mixer1, 1);
 AudioConnection          patchCord4(i2s1, 1, i2s2, 1);
 AudioConnection          patchCord5(mixer1, fft1024);
 AudioControlSGTL5000     audioShield;    //xy=366,225
 // GUItool: end automatically generated code

 // Create the Audio components.  These should be created in the
 // order data flows, inputs/sources -> processing -> outputs
 //
 AudioInputI2S       audioInput;         // audio shield: mic or line-in
 AudioAnalyzeFFT256  myFFT(11);
 AudioOutputI2S      audioOutput;        // audio shield: headphones & line-out

 // Create Audio connections between the components
 //
 AudioConnection c1(audioInput, 0, audioOutput, 0);
 AudioConnection c2(audioInput, 0, myFFT, 0);
 AudioConnection c3(audioInput, 1, audioOutput, 1);
 const int myInput = AUDIO_INPUT_LINEIN;
 //const int myInput = AUDIO_INPUT_MIC;


 // The scale sets how much sound is needed in each frequency range to
 // show all 8 bars.  Higher numbers are more sensitive.
 float scale = 60.0;

 // An array to hold the 16 frequency bands
 float level[16];

 // This array holds the on-screen levels.  When the signal drops quickly,
 // these are used to lower the on-screen level 1 bar per update, which
 // looks more pleasing to corresponds to human sound perception.
 int   shown[16];


 // Create an object to control the audio shield.
 // 
 AudioControlSGTL5000 audioShield;

 // Use the LiquidCrystal library to display the spectrum
 //
 LiquidCrystal lcd(0, 1, 2, 3, 4, 5);
 byte bar1[8] = {0,0,0,0,0,0,0,255};
 byte bar2[8] = {0,0,0,0,0,0,255,255};
 byte bar3[8] = {0,0,0,0,0,255,255,255};
 byte bar4[8] = {0,0,0,0,255,255,255,255};
 byte bar2[8] = {0,0,0,0,0,0,255,255};        // 8 bar graph
 byte bar3[8] = {0,0,0,0,0,255,255,255};      // custom
 byte bar4[8] = {0,0,0,0,255,255,255,255};    // characters
 byte bar5[8] = {0,0,0,255,255,255,255,255};
 byte bar6[8] = {0,0,255,255,255,255,255,255};
 byte bar7[8] = {0,255,255,255,255,255,255,255};
 byte bar8[8] = {255,255,255,255,255,255,255,255};


 void setup() {
  // Audio connections require memory to work.  For more
  // detailed information, see the MemoryAndCpuUsage example
  // Audio requires memory to work.
  AudioMemory(12);

  // Enable the audio shield and set the output volume.
  audioShield.enable();
  audioShield.inputSelect(myInput);
  audioShield.volume(0.6);
  
  audioShield.volume(0.5);

  // turn on the LCD and define the custom characters
  lcd.begin(16, 2);
  lcd.print("Audio Spectrum");
  lcd.createChar(0, bar1);
@@ -57,83 +70,72 @@ void setup() {
  lcd.createChar(6, bar7);
  lcd.createChar(7, bar8);

  // configure the mixer to equally add left & right
  mixer1.gain(0, 0.5);
  mixer1.gain(1, 0.5);

  // pin 21 will select rapid vs animated display
  pinMode(21, INPUT_PULLUP);
 }

 int count=0;

 const int nsum[16] = {1, 1, 2, 2, 3, 4, 5, 6, 6, 8, 12, 14, 16, 20, 28, 24};

 int maximum[16];

 void loop() {
  if (myFFT.available()) {
    // convert the 128 FFT frequency bins
    // to only 16 sums, for a 16 character LCD
    int sum[16];
    int i;
    for (i=0; i<16; i++) {
      sum[i] = 0;
    }
    int n=0;
    int count=0;
    for (i=0; i<128; i++) {
      sum[n] = sum[n] + myFFT.output[i];
      count = count + 1;
      if (count >= nsum[n]) {
        Serial.print(count);
        Serial.print(" ");
        n = n + 1;
        if (n >= 16) break;
        count = 0;
      }
    }

    // The range is set by the audio shield's
    // knob, which connects to analog pin A1.
    int scale;
    scale = 2 + (1023 - analogRead(A1)) / 7;
    Serial.print(" - ");
    Serial.print(scale);
    Serial.print("  ");
  if (fft1024.available()) {
    // read the 512 FFT frequencies into 16 levels
    // music is heard in octaves, but the FFT data
    // is linear, so for the higher octaves, read
    // many FFT bins together.
    level[0] =  fft1024.read(0);
    level[1] =  fft1024.read(1);
    level[2] =  fft1024.read(2, 3);
    level[3] =  fft1024.read(4, 6);
    level[4] =  fft1024.read(7, 10);
    level[5] =  fft1024.read(11, 15);
    level[6] =  fft1024.read(16, 22);
    level[7] =  fft1024.read(23, 32);
    level[8] =  fft1024.read(33, 46);
    level[9] =  fft1024.read(47, 66);
    level[10] = fft1024.read(67, 93);
    level[11] = fft1024.read(94, 131);
    level[12] = fft1024.read(132, 184);
    level[13] = fft1024.read(185, 257);
    level[14] = fft1024.read(258, 359);
    level[15] = fft1024.read(360, 511);

    // if you have the volume pot soldered to your audio shield
    // uncomment this line to make it adjust the full scale signal
    //scale = 8.0 + analogRead(A1) / 5.0;

    // begin drawing at the first character on the 2nd row
    lcd.setCursor(0, 1);
 
    for (int i=0; i<16; i++) {
      // Reduce the range to 0-8
      int val = sum[i] / scale;
      Serial.print(level[i]);

      // TODO: conversion from FFT data to display bars should be
      // exponentially scaled.  But how keep it a simple example?
      int val = level[i] * scale;
      if (val > 8) val = 8;

      // Compute an animated maximum, where increases
      // show instantly, but if the number is less that
      // the last displayed value, decrease it by 1 for
      // a slow decay (looks pretty)
      if (val >= maximum[i]) {
        maximum[i] = val;
      if (val >= shown[i]) {
        shown[i] = val;
      } else {
        if (maximum[i] > 0) maximum[i] = maximum[i] - 1;
        if (shown[i] > 0) shown[i] = shown[i] - 1;
        val = shown[i];
      }

      // a switch on pin 22 select whether we show the
      // slower animation or the direct/fast data
      if (digitalRead(21) == HIGH) {
        val = maximum[i];
      }
      //Serial.print(shown[i]);
      Serial.print(" ");

      // print each custom digit
      if (val == 0) {
      if (shown[i] == 0) {
        lcd.write(' ');
      } else {
        lcd.write(val - 1);
        lcd.write(shown[i] - 1);
      }
      
      Serial.print(sum[i]);
      Serial.print("=");
      Serial.print(val);
      Serial.print(",");
    }
    Serial.println();
    count = 0;
    Serial.print(" cpu:");
    Serial.println(AudioProcessorUsageMax());
  }
 }