Add new sketches for the meergranen and led matrix

5 years ago · 407472bb1a
parent 0ce57a5e39
commit 407472bb1a
5 changed files with 2306 additions and 0 deletions
--- a/sketches/damla-sketch/CapacitiveSensorMeerg/CapacitiveSensorMeerg.ino
+++ b/sketches/damla-sketch/CapacitiveSensorMeerg/CapacitiveSensorMeerg.ino
@ -0,0 +1,59 @@
 #include <CapacitiveSensor.h>
 /*
 * CapitiveSense Library Demo Sketch
 * Paul Badger 2008
 * Uses a high value resistor e.g. 10M between send pin and receive pin
 * Resistor effects sensitivity, experiment with values, 50K - 50M. Larger resistor values yield larger sensor values.
 * Receive pin is the sensor pin - try different amounts of foil/metal on this pin
 */
 CapacitiveSensor   cs_4_2 = CapacitiveSensor(4,2);        // 10M resistor between pins 4 & 2, pin 2 is sensor pin, add a wire and or foil if desired
 CapacitiveSensor   cs_4_3 = CapacitiveSensor(4,3);        // 10M resistor between pins 4 & 6, pin 6 is sensor pin, add a wire and or foil
 CapacitiveSensor   cs_4_5 = CapacitiveSensor(4,5);        // 10M resistor between pins 4 & 8, pin 8 is sensor pin, add a wire and or foil
 void setup()                    
 {
   cs_4_2.set_CS_AutocaL_Millis(0xFFFFFFFF);     // turn off autocalibrate on channel 1 - just as an example
   Serial.begin(9600);
 }
 void loop()                    
 {
    long start = millis();
    long total1 =  cs_4_2.capacitiveSensor(30);
    long valCons1 = constrain(total1, 10000, 225000);
    long mappedVal1 = map(valCons1, 10000, 225000, 0, 1024);
    long total2 =  cs_4_3.capacitiveSensor(30);
    long valCons2 = constrain(total2, 10000, 225000);
    long mappedVal2 = map(valCons2, 10000, 225000, 0, 1024);
    long total3 =  cs_4_5.capacitiveSensor(30);
    long valCons3 = constrain(total3, 10000, 225000);
    long mappedVal3 = map(valCons3, 10000, 225000, 0, 1024);
    Serial.print(millis() - start);        // check on performance in milliseconds
    Serial.print("\t");                    // tab character for debug windown spacing
    Serial.print(total1);                  // print sensor output 1
    Serial.print("\t");
    Serial.print(total2);                  // print sensor output 2
    Serial.print("\t");
    Serial.println(total3);                // print sensor output 3
    Serial.print(valCons1);
    Serial.print("\t");
    Serial.print(valCons2);
    Serial.print("\t");
    Serial.println(valCons3);
    Serial.print(mappedVal1);
    Serial.print("\t");
    Serial.print(mappedVal2);
    Serial.print("\t");
    Serial.println(mappedVal3);
    delay(300);                             // arbitrary delay to limit data to serial port 
 }
--- a/sketches/damla-sketch/Drawing2LedMatrix/Drawing2LedMatrix.ino
+++ b/sketches/damla-sketch/Drawing2LedMatrix/Drawing2LedMatrix.ino
@ -0,0 +1,189 @@
 #include <CapacitiveSensor.h>
 CapacitiveSensor   cs_4_2 = CapacitiveSensor(4,2);        // 10M resistor between pins 4 & 2, pin 2 is sensor pin, add a wire and or foil if desired
 int LEDPin1 = 38;
 int LEDPin2 = 39;
 int LEDPin3 = 40;
 int LEDPin5 = 41;
 int LEDPin4 = 42;
 int LEDPin6 = 43;
 int LEDPin7 = 44;
 int LEDPin8 = 45;
 int LEDPin9 = 46;
 int LEDPin10 = 47;
 int LEDPin11 = 48;
 int LEDPin12 = 49;
 int LEDPin13 = 50;
 int LEDPin14 = 51;
 int LEDPin15 = 52;
 int LEDPin16 = 53;
 void setup()                    
 {
   cs_4_2.set_CS_AutocaL_Millis(0xFFFFFFFF);     // turn off autocalibrate on channel 1 - just as an example
   Serial.begin(9600);
   pinMode(LEDPin1, OUTPUT);
  pinMode(LEDPin2, OUTPUT);
  pinMode(LEDPin3, OUTPUT);
  pinMode(LEDPin4, OUTPUT);
  pinMode(LEDPin5, OUTPUT);
  pinMode(LEDPin6, OUTPUT);
  pinMode(LEDPin7, OUTPUT);
  pinMode(LEDPin8, OUTPUT);
  pinMode(LEDPin9, OUTPUT);
  pinMode(LEDPin10, OUTPUT);
  pinMode(LEDPin11, OUTPUT);
  pinMode(LEDPin12, OUTPUT);
  pinMode(LEDPin13, OUTPUT);
  pinMode(LEDPin14, OUTPUT);
  pinMode(LEDPin15, OUTPUT);
  pinMode(LEDPin16, OUTPUT);
  digitalWrite(LEDPin1, LOW);
  digitalWrite(LEDPin2, LOW);
  digitalWrite(LEDPin3, LOW);
  digitalWrite(LEDPin4, LOW);
  digitalWrite(LEDPin5, LOW);
  digitalWrite(LEDPin6, LOW);
  digitalWrite(LEDPin7, LOW);
  digitalWrite(LEDPin8, LOW);
  digitalWrite(LEDPin9, LOW);
  digitalWrite(LEDPin10, LOW);
  digitalWrite(LEDPin11, LOW);
  digitalWrite(LEDPin12, LOW);
  digitalWrite(LEDPin13, LOW);
  digitalWrite(LEDPin14, LOW);
  digitalWrite(LEDPin15, LOW);
  digitalWrite(LEDPin16, LOW);
 }
 void loop()                    
 {
    long start = millis();
    long total1 =  cs_4_2.capacitiveSensor(30);
    long valCons = constrain(total1, 10000, 280000);
    long mappedVal = map(valCons, 10000, 280000, 0, 1024);
 if (mappedVal >200) {
 digitalWrite(LEDPin1, HIGH);
 }
 else {
 digitalWrite(LEDPin1, LOW);
 }
 if (mappedVal >345) {
 digitalWrite(LEDPin2, HIGH);
 }
 else {
 digitalWrite(LEDPin2, LOW);
 }
 if (mappedVal >400) {
 digitalWrite(LEDPin3, HIGH);
 }
 else {
 digitalWrite(LEDPin3, LOW);
 }
 if (mappedVal >367) {
 digitalWrite(LEDPin4, HIGH);
 }
 else {
 digitalWrite(LEDPin4, LOW);
 }
 if (mappedVal >993) {
 digitalWrite(LEDPin5, HIGH);
 }
 else {
 digitalWrite(LEDPin5, LOW);
 }
 if (mappedVal >398) {
 digitalWrite(LEDPin6, HIGH);
 }
 else {
 digitalWrite(LEDPin6, LOW);
 }
 if (mappedVal >912) {
 digitalWrite(LEDPin7, HIGH);
 }
 else {
 digitalWrite(LEDPin7, LOW);
 }
 if (mappedVal >800) {
 digitalWrite(LEDPin8, HIGH);
 }
 else {
 digitalWrite(LEDPin8, LOW);
 }
 if (mappedVal >622) {
 digitalWrite(LEDPin9, HIGH);
 }
 else {
 digitalWrite(LEDPin9, LOW);
 }
 if (mappedVal >22) {
 digitalWrite(LEDPin10, HIGH);
 }
 else {
 digitalWrite(LEDPin10, LOW);
 }
 if (mappedVal >114) {
 digitalWrite(LEDPin11, HIGH);
 }
 else {
 digitalWrite(LEDPin11, LOW);
 }
 if (mappedVal >112) {
 digitalWrite(LEDPin12, HIGH);
 }
 else {
 digitalWrite(LEDPin12, LOW);
 }
 if (mappedVal >313) {
 digitalWrite(LEDPin13, HIGH);
 }
 else {
 digitalWrite(LEDPin13, LOW);
 }
 if (mappedVal >214) {
 digitalWrite(LEDPin14, HIGH);
 }
 else {
 digitalWrite(LEDPin14, LOW);
 }
 if (mappedVal >315) {
 digitalWrite(LEDPin15, HIGH);
 }
 else {
 digitalWrite(LEDPin15, LOW);
 }
 if (mappedVal >100) {
 digitalWrite(LEDPin16, HIGH);
 }
 else {
 digitalWrite(LEDPin16, LOW);
 }
    Serial.print(total1);
    Serial.print("\t");
    Serial.print(valCons);
    Serial.print("\t");
    Serial.println(mappedVal);                  // print sensor output 1
    delay(100);                             // arbitrary delay to limit data to serial port 
 }
--- a/sketches/damla-sketch/Drawing2LedMatrix_breathe/Drawing2LedMatrix_breathe.ino
+++ b/sketches/damla-sketch/Drawing2LedMatrix_breathe/Drawing2LedMatrix_breathe.ino
@ -0,0 +1,225 @@
 #include <CapacitiveSensor.h>
 CapacitiveSensor   cs_4_2 = CapacitiveSensor(4,2);        // 10M resistor between pins 4 & 2, pin 2 is sensor pin, add a wire and or foil if desired
 int LEDPin1 = 38;
 int LEDPin2 = 39;
 int LEDPin3 = 40;
 int LEDPin5 = 41;
 int LEDPin4 = 42;
 int LEDPin6 = 43;
 int LEDPin7 = 44;
 int LEDPin8 = 45;
 int LEDPin9 = 46;
 int LEDPin10 = 47;
 int LEDPin11 = 48;
 int LEDPin12 = 49;
 int LEDPin13 = 50;
 int LEDPin14 = 51;
 int LEDPin15 = 52;
 int LEDPin16 = 53;
 void setup()                    
 {
   cs_4_2.set_CS_AutocaL_Millis(0xFFFFFFFF);     // turn off autocalibrate on channel 1 - just as an example
   Serial.begin(9600);
   pinMode(LEDPin1, OUTPUT);
  pinMode(LEDPin2, OUTPUT);
  pinMode(LEDPin3, OUTPUT);
  pinMode(LEDPin4, OUTPUT);
  pinMode(LEDPin5, OUTPUT);
  pinMode(LEDPin6, OUTPUT);
  pinMode(LEDPin7, OUTPUT);
  pinMode(LEDPin8, OUTPUT);
  pinMode(LEDPin9, OUTPUT);
  pinMode(LEDPin10, OUTPUT);
  pinMode(LEDPin11, OUTPUT);
  pinMode(LEDPin12, OUTPUT);
  pinMode(LEDPin13, OUTPUT);
  pinMode(LEDPin14, OUTPUT);
  pinMode(LEDPin15, OUTPUT);
  pinMode(LEDPin16, OUTPUT);
  digitalWrite(LEDPin1, LOW);
  digitalWrite(LEDPin2, LOW);
  digitalWrite(LEDPin3, LOW);
  digitalWrite(LEDPin4, LOW);
  digitalWrite(LEDPin5, LOW);
  digitalWrite(LEDPin6, LOW);
  digitalWrite(LEDPin7, LOW);
  digitalWrite(LEDPin8, LOW);
  digitalWrite(LEDPin9, LOW);
  digitalWrite(LEDPin10, LOW);
  digitalWrite(LEDPin11, LOW);
  digitalWrite(LEDPin12, LOW);
  digitalWrite(LEDPin13, LOW);
  digitalWrite(LEDPin14, LOW);
  digitalWrite(LEDPin15, LOW);
  digitalWrite(LEDPin16, LOW);
 }
 void loop()                    
 {
    long start = millis();
    long rawSensor =  cs_4_2.capacitiveSensor(30);
    constrain(rawSensor, 0, 30000);
    int drawingSensor = map(rawSensor, 0, 30000, 0, 950);
   if (drawingSensor >200) {
  digitalWrite(LEDPin1, HIGH);
  delay(10);
  digitalWrite(LEDPin1, LOW);
 }
 else {
  digitalWrite(LEDPin1, LOW);
 }
  if (drawingSensor >345) {
  digitalWrite(LEDPin2, HIGH);
  delay(10);
  digitalWrite(LEDPin2, LOW);
 }
 else {
  digitalWrite(LEDPin2, LOW);
 }
  if (drawingSensor >543) {
  digitalWrite(LEDPin3, HIGH);
  delay(30);
  digitalWrite(LEDPin3, LOW);
 }
 else {
  digitalWrite(LEDPin3, LOW);
 }
  if (drawingSensor >467) {
  digitalWrite(LEDPin4, HIGH);
  delay(15);
  digitalWrite(LEDPin4, LOW);
 }
 else {
  digitalWrite(LEDPin4, LOW);
 }
  if (drawingSensor >793) {
  digitalWrite(LEDPin5, HIGH);
  delay(20);
  digitalWrite(LEDPin5, LOW);
 }
 else {
  digitalWrite(LEDPin5, LOW);
 }
 if (drawingSensor >398) {
  digitalWrite(LEDPin6, HIGH);
  delay(10);
  digitalWrite(LEDPin6, LOW);
 }
 else {
  digitalWrite(LEDPin6, LOW);
 }
  if (drawingSensor >612) {
  digitalWrite(LEDPin7, HIGH);
  delay(10);
  digitalWrite(LEDPin7, LOW);
 }
 else {
  digitalWrite(LEDPin7, LOW);
 }
  if (drawingSensor >709) {
  digitalWrite(LEDPin8, HIGH);
  delay(10);
  digitalWrite(LEDPin8, LOW);
 }
 else {
  digitalWrite(LEDPin8, LOW);
 }
  if (drawingSensor >622) {
  digitalWrite(LEDPin9, HIGH);
  delay(10);
  digitalWrite(LEDPin9, LOW);
 }
 else {
  digitalWrite(LEDPin9, LOW);
 }
  if (drawingSensor >22) {
  digitalWrite(LEDPin10, HIGH);
  delay(10);
  digitalWrite(LEDPin10, LOW);
 }
 else {
  digitalWrite(LEDPin10, LOW);
 }
  if (drawingSensor >114) {
  digitalWrite(LEDPin11, HIGH);
  delay(10);
  digitalWrite(LEDPin11, LOW);
 }
 else {
  digitalWrite(LEDPin11, LOW);
 }
  if (drawingSensor >712) {
  digitalWrite(LEDPin12, HIGH);
  delay(10);
  digitalWrite(LEDPin12, LOW);
 }
 else {
  digitalWrite(LEDPin12, LOW);
 }
  if (drawingSensor >313) {
  digitalWrite(LEDPin13, HIGH);
  delay(10);
  digitalWrite(LEDPin13, LOW);
 }
 else {
  digitalWrite(LEDPin13, LOW);
 }
  if (drawingSensor >814) {
  digitalWrite(LEDPin14, HIGH);
  delay(10);
  digitalWrite(LEDPin14, LOW);
 }
 else {
  digitalWrite(LEDPin14, LOW);
 }
  if (drawingSensor >815) {
  digitalWrite(LEDPin15, HIGH);
  delay(10);
  digitalWrite(LEDPin15, LOW);
 }
 else {
  digitalWrite(LEDPin15, LOW);
 }
  if (drawingSensor >800) {
  digitalWrite(LEDPin16, HIGH);
  delay(10);
  digitalWrite(LEDPin16, LOW);
 }
 else {
  digitalWrite(LEDPin16, LOW);
 }
    //Serial.print(millis() - start);        // check on performance in milliseconds
    //Serial.print("\t");                    // tab character for debug windown spacing
    //Serial.print("Raw Sensor Value ");
    //Serial.print("\t");
    //Serial.println(rawSensor);                  // print sensor output 1
    Serial.print("Mapped Sensor Value ");
    Serial.print("\t");
    Serial.println(drawingSensor);
    //delay(1000);                             // arbitrary delay to limit data to serial port 
 }
--- a/sketches/damla-sketch/memphis-drawing/memphis-drawing.ino
+++ b/sketches/damla-sketch/memphis-drawing/memphis-drawing.ino
@ -0,0 +1,159 @@
 #include <CapacitiveSensor.h>
 #include <stdint.h>
 #include <avr/interrupt.h>
 #include <avr/io.h>
 #include <avr/pgmspace.h>
 #include "sample.h"
 #define LED_PIN     13
 #define SPEAKER_PIN 11 
 #define KNOB_1  (0)
 #define KNOB_2  (1)  
 #define KNOB_3  (2)   
 #define INPUT_3 (3)   
 volatile uint16_t sample;
 volatile uint16_t loop_start;
 volatile uint16_t loop_length;
 volatile uint16_t index_bounds;
 volatile uint16_t loop_overflow;
 volatile boolean gate;
 volatile boolean gate_prev;
 byte lastSample;
 CapacitiveSensor   cs_4_2 = CapacitiveSensor(4,2);        // 10M resistor between pins 4 & 2, pin 2 is sensor pin, add a wire and or foil if desired
 CapacitiveSensor   cs_4_3 = CapacitiveSensor(4,3);        // 10M resistor between pins 4 & 6, pin 6 is sensor pin, add a wire and or foil
 CapacitiveSensor   cs_4_5 = CapacitiveSensor(4,5);        // 10M resistor between pins 4 & 8, pin 8 is sensor pin, add a wire and or foil
 void startPlayback()
 {
    pinMode(SPEAKER_PIN, OUTPUT);
    // Set up Timer 2 to do pulse width modulation on the speaker pin.
    // Use internal clock (datasheet p.160)
    ASSR &= ~(_BV(EXCLK) | _BV(AS2));
    // Set fast PWM mode  (p.157)
    TCCR2A |= _BV(WGM21) | _BV(WGM20);
    TCCR2B &= ~_BV(WGM22);
    // Do non-inverting PWM on pin OC2A (p.155)
    // On the Arduino this is pin 11.
    TCCR2A = (TCCR2A | _BV(COM2A1)) & ~_BV(COM2A0);
    TCCR2A &= ~(_BV(COM2B1) | _BV(COM2B0));
    // No prescaler (p.158)
    TCCR2B = (TCCR2B & ~(_BV(CS12) | _BV(CS11))) | _BV(CS10);
    // Set initial pulse width to the first sample.
    OCR2A = pgm_read_byte(&sound_data[0]);
    // Set up Timer 1 to send a sample every interrupt.
    cli();
    // Set CTC mode (Clear Timer on Compare Match) (p.133)
    // Have to set OCR1A *after*, otherwise it gets reset to 0!
    TCCR1B = (TCCR1B & ~_BV(WGM13)) | _BV(WGM12);
    TCCR1A = TCCR1A & ~(_BV(WGM11) | _BV(WGM10));
    // No prescaler (p.134)
    TCCR1B = (TCCR1B & ~(_BV(CS12) | _BV(CS11))) | _BV(CS10);
    // Set the compare register (OCR1A).
    // OCR1A is a 16-bit register, so we have to do this with
    // interrupts disabled to be safe.
    OCR1A = F_CPU / SAMPLE_RATE; // 16e6 / 8000 = 2000
    // Enable interrupt when TCNT1 == OCR1A (p.136)
    TIMSK1 |= _BV(OCIE1A);
    lastSample = pgm_read_byte(&sound_data[sound_length - 1]);
    sample = 0;
    sei();
 }
 void stopPlayback()
 {
    TIMSK1 &= ~_BV(OCIE1A); // Disable playback per-sample interrupt.
    TCCR1B &= ~_BV(CS10);   // Disable the per-sample timer completely.
    TCCR2B &= ~_BV(CS10);   // Disable the PWM timer.
    digitalWrite(SPEAKER_PIN, LOW);
 }
 void setup()
 {
    pinMode(LED_PIN, OUTPUT);
    digitalWrite(LED_PIN, HIGH);
    startPlayback();
    loop_start  = 0; 
    loop_length = sound_length;
    gate = false;
    gate_prev = false;
 }
 // This is called at 8000 Hz to load the next sample.
 ISR(TIMER1_COMPA_vect)
 {
    if(sample >= index_bounds)
    {
        sample = loop_start;
    }
    else if((sample < loop_start) &&
            (sample >= loop_overflow))
    {
        sample = loop_start;
    }
    else if((gate == true) &&
            (gate_prev == false))
    {
        sample = loop_start;
    }
    else
    {
        OCR2A = pgm_read_byte(&sound_data[sample % sound_length]);
    }
    gate_prev = gate;
    sample++;
 }
 void loop()
 {
 long start = millis();
    long total1 =  cs_4_2.capacitiveSensor(30);
    long valCons1 = constrain(total1, 10000, 225000);
    long mappedVal1 = map(valCons1, 10000, 225000, 0, 1024);
    long total2 =  cs_4_3.capacitiveSensor(30);
    long valCons2 = constrain(total2, 10000, 225000);
    long mappedVal2 = map(valCons2, 10000, 225000, 0, 1024);
    long total3 =  cs_4_5.capacitiveSensor(30);
    long valCons3 = constrain(total3, 10000, 225000);
    long mappedVal3 = map(valCons3, 10000, 225000, 0, 1024);
    loop_start = mappedVal3 / 1024.0 * sound_length;
    loop_length = (mappedVal2 + 1) / 1024.0 * sound_length;
    OCR1A = (512.0 / (mappedVal1 + 1)) * (F_CPU / SAMPLE_RATE);
    gate = analogRead(3) >> 9;  // 10 bits in. gate < 512 == off, gate >= 512 == on
 //  can be up to 2x sound length. the more you know.
    index_bounds = loop_start + loop_length;
 //  this will set the overflow length. take the loop overflow into account when checking the loop boundaries
    if(index_bounds > sound_length)
    {
        loop_overflow = index_bounds - sound_length;
    }
    else
    {
        loop_overflow = 0;
    }
 }
--- a/sketches/damla-sketch/memphis-drawing/sample.h
+++ b/sketches/damla-sketch/memphis-drawing/sample.h