204 lines
5.1 KiB
C++
204 lines
5.1 KiB
C++
#include "zauberstab.h"
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#define SAMPLING_FREQUENCY_BP 40 // number of energy chunks per second
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#define SAMPLING_FREQUENCY_CONTROL 1 // check number of times per second if the current band pass is the best one
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#define Q 20. // quality factor of band pass filters
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#define PI 3.1415926535897932384626433832795
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#define n_BP 30 //number of band pass filters
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static unsigned long sampling_period_bp = 1000000L / SAMPLING_FREQUENCY_BP;
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static unsigned long sampling_period_control = 1000000L / SAMPLING_FREQUENCY_CONTROL;
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static double energy = 0;
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static unsigned long last_us_bp = 0L;
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static unsigned long last_us_control = 0L;
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static float a0[n_BP];
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static float a1[n_BP];
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static float a2[n_BP];
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static float b0[n_BP];
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//static float b1[n_BP];
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static float b2[n_BP];
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static float a[n_BP];
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static float w0[n_BP];
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static float yy1[n_BP];
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static float yy2[n_BP];
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static float yy3[n_BP];
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static float yy4[n_BP];
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static float yy5[n_BP];
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static float yy6[n_BP];
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static float u1[n_BP];
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static float u2[n_BP];
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static float y[n_BP];
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static float y_fil[n_BP];
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static float angle;
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static float angle2;
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static double energy_fil = 800.;
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static float pos_target = NUM_LEDS / 2;
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static float pos_target_filtered = NUM_LEDS / 2;
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static float microphone_offset = 675;
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static long initial_time;
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static int active = 15;
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static int candidate = 15;
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static int rounds = 0;
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static int get_value(int pos, float pos0)
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{
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if (abs(pos0 - pos) > 20)
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{
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return 0;
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}
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else
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{
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return (40 - abs(pos0 - pos) * 2);
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}
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}
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static void set_filter()
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{
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for (int i = 0; i < n_BP; i++)
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{
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float frequency = 1.75 + i * (2.4 - 1.75) / n_BP;
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w0[i] = 2. * PI * frequency / SAMPLING_FREQUENCY_BP;
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a[i] = sin(w0[i] / (2. * Q));
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b0[i] = a[i];
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//b1[i] = 0;
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b2[i] = -a[i];
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a0[i] = 1. + a[i];
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a1[i] = -2. * cos(w0[i]);
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a2[i] = 1. - a[i];
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}
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}
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void setup()
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{
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zauberstab_init();
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Serial.begin(115200);
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set_filter();
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initial_time = micros();
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}
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void loop()
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{
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int sample = int(analogRead(MIC_PIN) - microphone_offset);
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energy += abs(sample) * abs(sample);
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if (micros() - last_us_bp > sampling_period_bp)
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{
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Serial.println(sample);
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microphone_offset += (analogRead(MIC_PIN) - microphone_offset) * 0.001;
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//Serial.println(microphone_offset);
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last_us_bp += sampling_period_bp;
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energy_fil += (energy - energy_fil) * 0.01;
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//Serial.println(energy);
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for (int i = 0; i < n_BP; i++)
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{
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y[i] = (b0[i] / a0[i]) * energy + 0. + (b2[i] / a0[i]) * u2[i] - (a1[i] / a0[i]) * yy1[i] - (a2[i] / a0[i]) * yy2[i];
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u2[i] = u1[i];
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u1[i] = energy;
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yy6[i] = yy5[i];
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yy5[i] = yy4[i];
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yy4[i] = yy3[i];
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yy3[i] = yy2[i];
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yy2[i] = yy1[i];
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yy1[i] = y[i];
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y_fil[i] += (abs(y[i]) - y_fil[i]) * 0.005; //linie der scheitelpunkte
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}
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float delays = constrain(SAMPLING_FREQUENCY_BP * 0.25 / (1.75 + active * (2.4 - 1.75) / n_BP), 4., 6.);
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float delayed = 0;
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if (delays > 5)
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{
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delayed = yy5[active] * (1 - delays + 5) + yy6[active] * (delays - 5);
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}
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else
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{
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delayed = yy4[active] * (1 - delays + 4) + yy5[active] * (delays - 4);
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}
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angle = atan2(delayed, y[active]);
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if (PI < abs(angle - angle2) && abs(angle - angle2) < 3 * PI)
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{
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angle2 = angle + 2 * PI;
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}
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else
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{
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angle2 = angle;
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}
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pos_target = map(angle2, -PI, 3 * PI, -0.3 * NUM_LEDS, NUM_LEDS * 1.5);
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if (pos_target > pos_target_filtered)
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{
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pos_target_filtered += (pos_target - pos_target_filtered) * 0.35;
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}
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else
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{
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pos_target_filtered = pos_target;
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}
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// Serial.print(y_fil[active]);
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// Serial.print(",");
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// Serial.println(y[active]);
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energy = 0;
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for (int i = 0; i < NUM_LEDS; i++)
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{
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int brightness = get_value(i, pos_target_filtered);
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if (brightness >= 1) {
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brightness = 10;
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}
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//leds[i].setRGB(brightness, brightness, brightness);
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leds[i].setHSV(160, (rounds == 6) ? 0xFF : 0, brightness);
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}
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FastLED.show();
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}
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if (micros() - last_us_control > sampling_period_control)
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{
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last_us_control += sampling_period_control;
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int argmax = -1;
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float valuemax = 0;
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for (int i = 0; i < n_BP; i++)
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{
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if (y_fil[i] > valuemax)
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{
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valuemax = y_fil[i];
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argmax = i;
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}
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}
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if (argmax > -1)
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{
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if (argmax == candidate)
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{
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rounds++;
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}
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else
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{
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rounds = 0;
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candidate = argmax;
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}
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if (rounds > 6)
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{
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rounds = 0;
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active = candidate;
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}
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}
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}
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}
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