勃爆，不做二五仔

sanro/sanro.ino

@@ -12,40 +12,41 @@
 // ceramic sensors (the same sensors used in electirc drum kit).
 // No longer need microphones.
 
-#define MODE_DEBUG 0
-
 #define CHANNELS 2
 
-// Caches for the soundwave and power
 #define SAMPLE_CACHE_LENGTH 12
 #define POWER_CACHE_LENGTH 3
 
-// Light and heacy hit thresholds
-#define LIGHT_THRES 5000
+#define LIGHT_THRES 8000
 #define HEAVY_THRES 20000
 
-// Forced sampling frequency
 #define FORCED_FREQ 1000
 
 #include "cache.h"
 
 unsigned long int lastTime;
 
-int channelSample [CHANNELS];
-int lastChannelSample [CHANNELS];
-Cache <int, SAMPLE_CACHE_LENGTH> sampleCache [CHANNELS];
+float channelSample [CHANNELS];
+float lastChannelSample [CHANNELS];
+Cache <float, SAMPLE_CACHE_LENGTH> sampleCache [CHANNELS];
 
-long int power [CHANNELS];
-Cache <long int, POWER_CACHE_LENGTH> powerCache [CHANNELS];
+float power [CHANNELS];
+Cache <float, POWER_CACHE_LENGTH> powerCache [CHANNELS];
 
 bool triggered [CHANNELS];
 
-int pins[] = {A0, A1}; // Don, Kat
+int input_pins[] = {A0, A1}; // Don, Kat
+int output_pins[] = {A2, A3, A4, A5}; // Left Don, Left Kat, Right Don, Right Kat
 
 void setup() {
+  pinMode(A0, INPUT);
+  pinMode(A1, INPUT);
+  pinMode(A2, OUTPUT);
+  pinMode(A3, OUTPUT);
+  pinMode(A4, OUTPUT);
+  pinMode(A5, OUTPUT);
   Serial.begin (9600);
-  Keyboard.begin ();
-  analogReference (DEFAULT);
+  analogReference (INTERNAL);
   for (short int i = 0; i < CHANNELS; i++) {
     power [i] = 0;
     lastChannelSample [i] = 0;
@@ -58,22 +59,22 @@ void loop() {
   
   for (short int i = 0; i < CHANNELS; i++) {
     
-    channelSample[i] = analogRead (pins [i]);
-    sampleCache [i].put (channelSample [i] - lastChannelSample [i]);
+    channelSample[i] = analogRead(input_pins[i]);
+    sampleCache[i].put(channelSample [i]);
     
     long int tempInt;
-    tempInt = sampleCache [i].get (1);
-    power [i] -= tempInt * tempInt;
-    tempInt = sampleCache [i].get ();
-    power [i] += tempInt * tempInt;
-    if (power [i] < LIGHT_THRES) {
-      power [i] = 0;
-    }
+    tempInt = sampleCache[i].get(1);
+    power[i] -= tempInt * tempInt;
+    tempInt = sampleCache[i].get();
+    power[i] += tempInt * tempInt;
     
-    powerCache [i].put (power [i]);
-    lastChannelSample [i] = channelSample [i];
-    if (powerCache [i].get (1) == 0) {
-      triggered [i] = false;
+    powerCache[i].put(power[i]);
+    lastChannelSample[i] = channelSample[i];
+    if (powerCache[i].get(1) < LIGHT_THRES) {
+      triggered[i] = false;
+      digitalWrite(output_pins[i], HIGH);
+      digitalWrite(output_pins[i] + 2, HIGH);
+      digitalWrite(LED_BUILTIN, LOW);
     }
 
     if (!triggered [i]) {
@@ -82,38 +83,21 @@ void loop() {
           break;
         } else if (powerCache [i].get (1) >= HEAVY_THRES) {
           triggered [i] = true;
-          Keyboard.print (heavyKeys [i]);
+          digitalWrite(output_pins[i], LOW);
+          digitalWrite(output_pins[i] + 2, LOW);
+          digitalWrite(LED_BUILTIN, HIGH);
         } else if (powerCache [i].get (1) >= LIGHT_THRES) {
           triggered [i] = true;
-          Keyboard.print (lightKeys [i]);
+          digitalWrite(output_pins[i], LOW);
+          digitalWrite(LED_BUILTIN, HIGH);
         }
       }
     }
-    
-#if MODE_DEBUG
-    Serial.print (power [i]);
-    Serial.print ("\t");
-#endif
 
-// End of each channel
-  }
-
-#if MODE_DEBUG
-  Serial.print (50000);
-  Serial.print ("\t");
-  Serial.print (0);
-  Serial.print ("\t");
-
-  Serial.println ("");
-#endif
-
-// Force the sample frequency to be less than 1000Hz
-  unsigned int frameTime = micros () - lastTime;
-  lastTime = micros ();
-  if (frameTime < FORCED_FREQ) {
-    delayMicroseconds (FORCED_FREQ - frameTime);
-  } else {
-    // Performance bottleneck;
-    Serial.print ("Exception: forced frequency is too high for the microprocessor to catch up.");
+    unsigned int frameTime = micros () - lastTime;
+    lastTime = micros ();
+    if (frameTime < FORCED_FREQ) {
+      delayMicroseconds (FORCED_FREQ - frameTime);
+    }
   }
 }