bit_cnt = 0;
if(bit_defs[current_word[bit_cnt]][chunk_cnt].state)
- digitalWrite(RF_DATA_OUT_PIN, HIGH);
+ digitalWrite(RF_DATA_OUT_PIN, LOW); //neue 12V MosFET Verstärkung invertiert Logik !
else
- digitalWrite(RF_DATA_OUT_PIN, LOW);
+ digitalWrite(RF_DATA_OUT_PIN, HIGH);
start_timer();
}
chunk_cnt++;
if(bit_defs[current_word[bit_cnt]][chunk_cnt].offset != 0) {
if(bit_defs[current_word[bit_cnt]][chunk_cnt].state)
- digitalWrite(RF_DATA_OUT_PIN, HIGH);
+ digitalWrite(RF_DATA_OUT_PIN, LOW); //neue 12V MosFET Verstärkung invertiert Logik !
else
- digitalWrite(RF_DATA_OUT_PIN, LOW);
+ digitalWrite(RF_DATA_OUT_PIN, HIGH);
return;
}
alpha_cnt = 0;
chunk_cnt = 0;
if(bit_defs[current_word[bit_cnt]][chunk_cnt].state)
- digitalWrite(RF_DATA_OUT_PIN, HIGH);
+ digitalWrite(RF_DATA_OUT_PIN, LOW); //neue 12V MosFET Verstärkung invertiert Logik !
else
- digitalWrite(RF_DATA_OUT_PIN, LOW);
+ digitalWrite(RF_DATA_OUT_PIN, HIGH);
return;
}
stop_timer();
- digitalWrite(RF_DATA_OUT_PIN, LOW);
+ digitalWrite(RF_DATA_OUT_PIN, HIGH);
word_cnt++;
if(word_cnt < FRAME_LEN)
return;
unsigned int diff = abs(value - light_level_mean_);
- if (light_level_mean_ < 6 || diff > 250)
+ if (diff > 100)
light_level_mean_ = value;
else
- light_level_mean_=(unsigned int) ( ((float) light_level_mean_) * 0.98 + ((float)value)*0.02 );
+ light_level_mean_=(unsigned int) ( ((float) light_level_mean_) * 0.90 + ((float)value)*0.10 );
}
void printLightLevel()
void setup()
{
pinMode(RF_DATA_OUT_PIN, OUTPUT);
- digitalWrite(RF_DATA_OUT_PIN, LOW);
+ digitalWrite(RF_DATA_OUT_PIN, HIGH);
pinMode(IR_MOVEMENT_PIN, INPUT); // set pin to input
digitalWrite(IR_MOVEMENT_PIN, LOW); // turn off pullup resistors
pinMode(PANIC_BUTTON_PIN, INPUT); // set pin to input