#define CHANNELS 4 // SAMPLE_CACHE_LENGTH must be power of 2 (8, 16, 32, etc.) // See cache.h for implementation #define SAMPLE_CACHE_LENGTH 32 // The thresholds are also dependent on SAMPLE_CACHE_LENGTH, if you // changed SAMPLE_CACHE_LENGTH, you should also adjust thresholds #define HIT_THRES 1750 #define RESET_THRES 200 // Sampling period in μs, e.g., 500μs = 0.5ms = 2000Hz #define SAMPLING_PERIOD 500 // Sensitivity multipliers for each channel, 1.0 as the baseline #define L_DON_SENS 1.0 #define L_KAT_SENS 1.0 #define R_DON_SENS 1.0 #define R_KAT_SENS 1.0 // Input pins for each channel #define L_DON_IN 4 #define L_KAT_IN 5 #define R_DON_IN 6 #define R_KAT_IN 7 // Output LED pins for each channel (just for visualization) #define L_DON_LED 9 #define L_KAT_LED 10 #define R_DON_LED 11 #define R_KAT_LED 12 // Keyboard output for each channel #define L_DON_KEY 'f' #define L_KAT_KEY 'd' #define R_DON_KEY 'j' #define R_KAT_KEY 'k' // Enable debug mode to view analog input values from the Serial // Enabling this also disables the keyboard simulation #define DEBUG 0 #include "USB.h" #include "USBHIDKeyboard.h" #include "cache.h" USBHIDKeyboard Keyboard; Cache inputWindow[CHANNELS]; unsigned long power[CHANNELS]; unsigned long lastPower[CHANNELS]; bool triggered; unsigned long triggeredTime[CHANNELS]; const byte inPins[] = {L_DON_IN, L_KAT_IN, R_DON_IN, R_KAT_IN}; const byte outPins[] = {L_DON_LED, L_KAT_LED, R_DON_LED, R_KAT_LED}; const char outKeys[] = {L_DON_KEY, L_KAT_KEY, R_DON_KEY, R_KAT_KEY}; float sensitivities[] = {L_DON_SENS, L_KAT_SENS, R_DON_SENS, R_KAT_SENS}; short maxIndex; float maxPower; unsigned long lastTime; void setup() { Serial.begin(250000); for (byte i = 0; i < CHANNELS; i++) { power[i] = 0; lastPower[i] = 0; triggered = false; pinMode(inPins[i], INPUT); pinMode(outPins[i], OUTPUT); } maxIndex = -1; maxPower = 0; lastTime = micros(); #if !DEBUG Keyboard.begin(); USB.begin(); #endif } void loop() { if (maxIndex != -1 && lastPower[maxIndex] < RESET_THRES) { triggered = false; digitalWrite(outPins[maxIndex], LOW); maxIndex = -1; maxPower = 0; } for (byte i = 0; i < CHANNELS; i++) { inputWindow[i].put(analogRead(inPins[i])); power[i] = sensitivities[i] * (power[i] - inputWindow[i].get(1) + inputWindow[i].get()); if (lastPower[i] > maxPower && power[i] < lastPower[i]) { maxPower = lastPower[i]; maxIndex = i; } lastPower[i] = power[i]; #if DEBUG Serial.print(power[i]); Serial.print(" "); #endif } if (!triggered && maxPower >= HIT_THRES) { triggered = true; digitalWrite(outPins[maxIndex], HIGH); #if !DEBUG Keyboard.write(outKeys[maxIndex]); #endif } #if DEBUG Serial.print("\n"); #endif unsigned int frameTime = micros() - lastTime; if (frameTime < SAMPLING_PERIOD) { delayMicroseconds(SAMPLING_PERIOD - frameTime); } lastTime = micros(); }