LED-Mesh/libraries/FastLED/examples/Ports/PJRCSpectrumAnalyzer/PJRCSpectrumAnalyzer.ino

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2019-02-13 22:27:19 +01:00
// LED Audio Spectrum Analyzer Display
//
// Creates an impressive LED light show to music input
// using Teensy 3.1 with the OctoWS2811 adaptor board
// http://www.pjrc.com/store/teensy31.html
// http://www.pjrc.com/store/octo28_adaptor.html
//
// Line Level Audio Input connects to analog pin A3
// Recommended input circuit:
// http://www.pjrc.com/teensy/gui/?info=AudioInputAnalog
//
// This example code is in the public domain.
#define USE_OCTOWS2811
#include <OctoWS2811.h>
#include <FastLED.h>
#include <Audio.h>
#include <Wire.h>
#include <SD.h>
#include <SPI.h>
// The display size and color to use
const unsigned int matrix_width = 60;
const unsigned int matrix_height = 32;
const unsigned int myColor = 0x400020;
// These parameters adjust the vertical thresholds
const float maxLevel = 0.5; // 1.0 = max, lower is more "sensitive"
const float dynamicRange = 40.0; // total range to display, in decibels
const float linearBlend = 0.3; // useful range is 0 to 0.7
CRGB leds[matrix_width * matrix_height];
// Audio library objects
AudioInputAnalog adc1(A3); //xy=99,55
AudioAnalyzeFFT1024 fft; //xy=265,75
AudioConnection patchCord1(adc1, fft);
// This array holds the volume level (0 to 1.0) for each
// vertical pixel to turn on. Computed in setup() using
// the 3 parameters above.
float thresholdVertical[matrix_height];
// This array specifies how many of the FFT frequency bin
// to use for each horizontal pixel. Because humans hear
// in octaves and FFT bins are linear, the low frequencies
// use a small number of bins, higher frequencies use more.
int frequencyBinsHorizontal[matrix_width] = {
1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
2, 2, 2, 2, 2, 2, 2, 2, 2, 3,
3, 3, 3, 3, 4, 4, 4, 4, 4, 5,
5, 5, 6, 6, 6, 7, 7, 7, 8, 8,
9, 9, 10, 10, 11, 12, 12, 13, 14, 15,
15, 16, 17, 18, 19, 20, 22, 23, 24, 25
};
// Run setup once
void setup() {
// the audio library needs to be given memory to start working
AudioMemory(12);
// compute the vertical thresholds before starting
computeVerticalLevels();
// turn on the display
FastLED.addLeds<OCTOWS2811>(leds,(matrix_width * matrix_height) / 8);
}
// A simple xy() function to turn display matrix coordinates
// into the index numbers OctoWS2811 requires. If your LEDs
// are arranged differently, edit this code...
unsigned int xy(unsigned int x, unsigned int y) {
if ((y & 1) == 0) {
// even numbered rows (0, 2, 4...) are left to right
return y * matrix_width + x;
} else {
// odd numbered rows (1, 3, 5...) are right to left
return y * matrix_width + matrix_width - 1 - x;
}
}
// Run repetitively
void loop() {
unsigned int x, y, freqBin;
float level;
if (fft.available()) {
// freqBin counts which FFT frequency data has been used,
// starting at low frequency
freqBin = 0;
for (x=0; x < matrix_width; x++) {
// get the volume for each horizontal pixel position
level = fft.read(freqBin, freqBin + frequencyBinsHorizontal[x] - 1);
// uncomment to see the spectrum in Arduino's Serial Monitor
// Serial.print(level);
// Serial.print(" ");
for (y=0; y < matrix_height; y++) {
// for each vertical pixel, check if above the threshold
// and turn the LED on or off
if (level >= thresholdVertical[y]) {
leds[xy(x,y)] = CRGB(myColor);
} else {
leds[xy(x,y)] = CRGB::Black;
}
}
// increment the frequency bin count, so we display
// low to higher frequency from left to right
freqBin = freqBin + frequencyBinsHorizontal[x];
}
// after all pixels set, show them all at the same instant
FastLED.show();
// Serial.println();
}
}
// Run once from setup, the compute the vertical levels
void computeVerticalLevels() {
unsigned int y;
float n, logLevel, linearLevel;
for (y=0; y < matrix_height; y++) {
n = (float)y / (float)(matrix_height - 1);
logLevel = pow10f(n * -1.0 * (dynamicRange / 20.0));
linearLevel = 1.0 - n;
linearLevel = linearLevel * linearBlend;
logLevel = logLevel * (1.0 - linearBlend);
thresholdVertical[y] = (logLevel + linearLevel) * maxLevel;
}
}