Difference between revisions of "LED christmas tree"

Project: LED christmas tree
Featured:
State	Completed
Members	Vicarious, Xopr
GitHub	No GitHub project defined. Add your project here.
Description	Blinken lights!
Picture

synopsis

Create a christmas tree out of cartboard, leds, some RJ45 wire, tiny experiment print, headers, solder, Scotch-tape, a brown plastic instant-coffee container and an arduino.

I hereby declare freedom of firmware for the tree; change to whatever you want it; this was just a kick-start.

implementation

Since the tree was already made two years ago, but the code (and/or Arduino) got lost, Xopr took his Andon light arduino, and did an ugly rush job on making the leds identifiable.

After identifying which port pin was which LED, I wrote some shifting logic to be able to call setLed( x, y ) and clearLed( x, y ).

Actually, I think writing about it on the wiki costs more time than actually pimping the tree, so here it is.

pics

Pics (or vid) or it didn't happen!

Since the video plugin still doesn't work, here a direct link: Media:Christmas_tree_and_message_ticker.mov.

code

v3

Latest version, somewhat cleaned, but 100% arduino code instead of avr-gcc compatible

byte g_mappedTree[4][4] = { // (arduino pin) DIGITAL/analog
  { 12,  9, 21, 13 }, // Row 1, blue(2)   ORANGE(1) red(4)   green(3)
  { 11, 29, 28, 27 }, // Row 2, orange(5) red(8)    green(7) blue(6)
  {  6,  4,  5, 30 }, // Row 3, red(12)   green(10) blue(11) orange(9)
  {  7,  7,  7,  7 }, // Top;   orange(13); yes it is only one led, so one pin
};

byte g_arduino[4][4] = {
  {  2,  1,  4,  3 }, // Row 1, blue(2)   ORANGE(1) red(4)   green(3)
  {  5,  8,  7,  6 }, // Row 2, orange(5) red(8)    green(7) blue(6)
  { 12, 10, 11,  9 }, // Row 3, red(12)   green(10) blue(11) orange(9)
  { 13, 13, 13, 13 }, // Top;   orange(13); yes it is only one led, so one pin
};


// Arduino pins
byte g_red[]    = { 4, 8, 12 };
byte g_orange[] = { 1, 5,  9, 13 };
byte g_green[]  = { 3, 7, 10 };
byte g_blue[]   = { 2, 6, 11 };

static const byte s_fadeValues[]      = { 0, 1, 2 ,3, 4, 6, 8, 12, 16, 23, 32, 45, 64, 90, 128, 180, 255 };

byte g_prevFrame[4][4] = {
  { 0, 0, 0, 0 },
  { 0, 0, 0, 0 },
  { 0, 0, 0, 0 },
  { 0, 0, 0, 0 },
};

byte g_analogValues[4][4] = {
  { 0, 0, 0, 0 },
  { 0, 0, 0, 0 },
  { 0, 0, 0, 0 },
  { 0, 0, 0, 0 },
};

byte g_frame = 0;

void setup()
{
    // TODO: define pins as output
}

void loop()
{
  g_frame++;
  if ( g_frame > 16 )
    g_frame = 0;

  colorFade( 2 );

  for ( byte n = 0; n < 2; n++ )
    softLayer();
    
  for ( byte n = 0; n < 2; n++ )
    guirlande();

  for ( byte n = 0; n < 7; n++ )
    horizontalBlink();

  for ( byte n = 0; n < 7; n++ )
    verticalBlink();

  for ( byte n = 0; n < 100; n++ )
    randomBlink();
    
  for ( byte l = 0; l < 4; l++ )
    pinArrayValue( g_arduino[ l ], 4, 0 );

}

void colorFade( byte _amount )
{
  // Cycle all colors slowly
  byte n;
  byte half = sizeof( s_fadeValues ) >> 1;

  // Halfway fade in blue
  for ( n = 0; n < half; n++ )
  {
    pinArrayValue( g_blue, sizeof( g_blue ), s_fadeValues[ n ] );
    delay( 100 );
  }
  
  for ( byte l = 0; l < _amount; l++ )
  {
    // Fade out blue while fade in orange
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_blue, sizeof( g_blue ), s_fadeValues[ half - n - 1] );
      pinArrayValue( g_orange, sizeof( g_orange ), s_fadeValues[ n ] );
      delay( 100 );
    }

    // fade in orange
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_orange, sizeof( g_orange ), s_fadeValues[ half + n + 1 ] );
      delay( 100 );
    }
    delay( 3000 );
    // fade out orange
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_orange, sizeof( g_orange ), s_fadeValues[ ( half << 1 ) - n ] );
      delay( 100 );
    }

    // Fade out orange while fade in green
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_orange, sizeof( g_orange ), s_fadeValues[ half - n - 1 ] );
      pinArrayValue( g_green, sizeof( g_green ), s_fadeValues[ n ] );
      delay( 100 );
    }

    // fade in green
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_green, sizeof( g_green ), s_fadeValues[ half + n + 1] );
      delay( 100 );
    }
    delay( 3000 );
    // fade out green
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_green, sizeof( g_green ), s_fadeValues[ ( half << 1 ) - n ] );
      delay( 100 );
    }

    // Fade out green while fade in red
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_green, sizeof( g_green ), s_fadeValues[ half - n - 1 ] );
      pinArrayValue( g_red, sizeof( g_red ), s_fadeValues[ n ] );
      delay( 100 );
    }
    
    // fade in red
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_red, sizeof( g_red ), s_fadeValues[ half + n + 1 ] );
      delay( 100 );
    }
    delay( 3000 );
    // fade out red
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_red, sizeof( g_red ), s_fadeValues[ ( half << 1 ) - n ] );
      delay( 100 );
    }

    // Fade out red while fade in blue
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_red, sizeof( g_red ), s_fadeValues[ half - n - 1 ] );
      pinArrayValue( g_blue, sizeof( g_blue ), s_fadeValues[ n ] );
      delay( 100 );
    }
    
    // fade in blue
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_blue, sizeof( g_blue ), s_fadeValues[ half + n + 1 ] );
      delay( 100 );
    }
    delay( 3000 );
    // fade out blue
    for ( n = 0; n < half; n++ )
    {
      pinArrayValue( g_blue, sizeof( g_blue ), s_fadeValues[ ( half << 1 ) - n ] );
      delay( 100 );
    }

  }
  
  // Fade out blue
  for ( n = 0; n < half; n++ )
  {
    pinArrayValue( g_blue, sizeof( g_blue ), s_fadeValues[ half - n - 1 ] );
    delay( 100 );
  }
  
}

void softLayer()
{
  // Fade in per layer bottom to top
  for ( byte l = 0; l < 4; l++ )
  {
    for ( byte b = 0; b < sizeof( s_fadeValues ); b++ )
    {
      pinArrayValue( g_arduino[ l ], 4, s_fadeValues[ b ] );
      delay( 50 );
    }
      delay( 500 );
  }

  delay( 3000 );

  // Fade in per layer top to bottom
  // Fade in per layer bottom to top
  for ( byte l = 0; l < 4; l++ )
  {
    for ( byte b = 0; b < sizeof( s_fadeValues ); b++ )
    {
      pinArrayValue( g_arduino[ 3 - l ], 4, s_fadeValues[ sizeof( s_fadeValues ) - b - 1 ] );
      delay( 50 );
    }
      delay( 500 );
  }

  delay( 2000 );

}

void guirlande()
{
  // Fade in per pixel, slowly to the top
  for ( byte y = 0; y < 4; y++ )
  {
    for ( byte x = 0; x < 4; x++ )
    {
      for ( byte b = 0; b < sizeof( s_fadeValues ); b++ )
      {
        analogWrite( g_arduino[ y ][ ( x + 1 ) % 4 ], s_fadeValues[ b ] );
        delay( 50 );
      }
    }
  }

  // Fade in per pixel, slowly to the top
  for ( byte y = 0; y < 4; y++ )
  {
    for ( byte x = 0; x < 4; x++ )
    {
      for ( byte b = 0; b < sizeof( s_fadeValues ); b++ )
      {
        analogWrite( g_arduino[ y ][ ( x + 1 ) % 4 ], s_fadeValues[ sizeof( s_fadeValues ) - b - 1 ] );
        delay( 50 );
      }
    }
  }

}


void pinArrayValue( byte* _arrPin, byte _nLength, byte _nValue )
{
  for ( byte n = 0; n < _nLength; n++ )
    analogWrite( _arrPin[ n ], _nValue );
}


void applyValues()
{
  for ( byte x = 0; x < 4; x++ )
  {
    for ( byte y = 0; y < 4; y++ )
    {
      if ( g_analogValues[ y][ x ] > g_frame )
        setLed( x, y );
      else
        clearLed( x, y );
    }
  }
}

void horizontalBlink()
{
  for ( byte x = 0; x < 4; x++ )
  {
    for ( byte y = 0; y < 4; y++ )
    {
      setLed( x, y );
    }
    delay( 100 );
  }
  for ( byte x = 0; x < 4; x++ )
  {
    for ( byte y = 0; y < 4; y++ )
    {
      clearLed( x, y );
    }
    delay( 100 );
  }
 
}

void verticalBlink()
{
  for ( byte y = 0; y < 4; y++ )
  {
    for ( byte x = 0; x < 4; x++ )
    {
      setLed( x, y );
    }
    delay( 100 );
  }
  for ( byte y = 0; y < 4; y++ )
  {
    for ( byte x = 0; x < 4; x++ )
    {
      clearLed( x, y );
    }
    delay( 100 );
  }
 
}

void randomBlink()
{
  byte x = random( 4 );
  byte y = random( 4 );
  if ( random( 2 ) )
    setLed( x, y );
  else
    clearLed( x, y );
  delay( 100 );
}


void setLed( byte _x, byte _y )
{
  byte mappedPort = g_mappedTree[ _y ][ _x ];
  byte shiftBit = mappedPort % 8;

  // Find which port it is
  switch ( mappedPort >> 3 )
  {
    case 0:
      PORTB |= (1 << shiftBit);
      break;
      
    case 1:
      PORTE |= (1 << shiftBit);
      break;
      
    case 2:
      PORTG |= (1 << shiftBit);
      break;

    case 3:
      PORTH |= (1 << shiftBit);
      break;
  }
}

void clearLed( byte _x, byte _y )
{
  byte mappedPort = g_mappedTree[ _y ][ _x ];
  byte shiftBit = mappedPort % 8;

  // Find which port it is
  switch ( mappedPort >> 3 )
  {
    case 0:
      PORTB &= ~(1 << shiftBit);
      break;
      
    case 1:
      PORTE &= ~(1 << shiftBit);
      break;
      
    case 2:
      PORTG &= ~(1 << shiftBit);
      break;

    case 3:
      PORTH &= ~(1 << shiftBit);
      break;

  }
}

void ledValue( byte _x, byte _y, byte _value )
{
  g_analogValues[ _y][ _x ] = _value;
}

v2

This code running is the one pasted here (with some preparations on doing PWM) Arduino code (portable to plain avr-gcc):

void setup()
{
  // Set tree pins as output
  DDRB = B11110000;
  DDRH = B01111000;
  DDRE = B00111010;
  DDRG = B00100000;

  // All lights on
  PORTB = B11110000;
  PORTE = B00111010;
  PORTG = B00100000;
  PORTH = B01111000;
  delay( 2000 );

  // All lights off
  PORTB = 0;
  PORTE = 0;
  PORTG = 0;
  PORTH = 0;
  delay( 1000 );
}

/*
  // Mapping of the pins on the tree are as followed (reverse-lookup pins from Arduino mega 1280):
  // {Port-and-pin-number}: {light-on-the-tree} {port-as-index-number,pin-number}: {resulting-mapping-index}
  PORTB7: top  0,7: 7
  PORTB6: 3a   0,6: 6
  PORTB5: 3c   0,5: 5
  PORTB4: 3b   0,4: 4

  PORTH6: 3d   3,6: 30
  PORTH5: 2b   3,5: 29
  PORTH4: 2c   3,4: 28
  PORTH3: 2d   3,3: 27

  PORTE5: 1d   1,5: 13
  PORTE4: 1a   1,4: 12
  PORTE3: 2a   1,3: 11
  PORTE2: 1b   1,1: 9

  PORTG5: 1c   2,5: 19
*/

// Mapping
byte g_mappedTree[4][4] = {
  { 12,  9, 21, 13 }, // Row 1, Da Syntax helped me calculating the number 21 ;)
  { 11, 29, 28, 27 }, // Row 2
  {  6,  4,  5, 30 }, // Row 3
  {  7,  7,  7,  7 }, // Top; yes it is only one led, so one pin
};

void loop()
{
  for ( byte n = 0; n < 10; n++ )
    horizontalBlink();
  for ( byte n = 0; n < 10; n++ )
    verticalBlink();
  for ( byte n = 0; n < 100; n++ )
    randomBlink();
}

void horizontalBlink()
{
  // Add vertical strips of light: switch on clock wise
  // When all lights are on, switch them off clock wise

  // Horizontal
  for ( byte x = 0; x < 4; x++ )
  {
    // Vertical
    for ( byte y = 0; y < 4; y++ )
    {
      setLed( x, y );
    }
    delay( 100 );
  }
  // Horizontal
  for ( byte x = 0; x < 4; x++ )
  {
    // Vertical
    for ( byte y = 0; y < 4; y++ )
    {
      clearLed( x, y );
    }
    delay( 100 );
  }
 
}

void verticalBlink()
{
  // In four steps, light a ring from bottom to top
  // When all lights are on, switch them off bottom to top

  // Vertical
  for ( byte y = 0; y < 4; y++ )
  {
   // Horizontal
    for ( byte x = 0; x < 4; x++ )
    {
      setLed( x, y );
    }
    delay( 100 );
  }
  // Vertical
  for ( byte y = 0; y < 4; y++ )
  {
   // Horizontal
    for ( byte x = 0; x < 4; x++ )
    {
      //setLed( x, y );
      clearLed( x, y );
    }
    delay( 100 );
  }
 
}

void randomBlink()
{
  // Pick a random row and column, a random state,
  // and apply that state to the indexed led
  // This is somewhat similar as the original tree had

  byte x = random( 4 );
  byte y = random( 4 );
  if ( random( 2 ) )
    setLed( x, y );
  else
    clearLed( x, y );
  delay( 100 );
}


void setLed( byte _x, byte _y )
{
  // This function does the led magic: it deduces the bit and port index from the mapping number
  // like this: xxxppbbb, there the lowest 3 bits are values 0-7, indicating the bit we're after
  // and the two bits after that determine the port

  // Yes, I could use the arduino port index, but this is faster

  // Fetch the mapping index for the given coordinate
  byte mappedPort = g_mappedTree[ _y ][ _x ];
  // Determine the bit index (lower three bits)
  byte shiftBit = mappedPort & 7;

  // Find which port it is (shift out the lower three bits and get the index)
  // And set the given bit
  switch ( mappedPort >> 3 )
  {
    case 0:
      PORTB |= (1 << shiftBit);
      break;
      
    case 1:
      PORTE |= (1 << shiftBit);
      break;
      
    case 2:
      PORTG |= (1 << shiftBit);
      break;

    case 3:
      PORTH |= (1 << shiftBit);
      break;
  }
}

void clearLed( byte _x, byte _y )
{
  // Same as setLed, except for the port bit banging
  // Yes, these functions can be combined, but the whole program was a quick hack

  // Fetch the mapping index for the given coordinate
  byte mappedPort = g_mappedTree[ _y ][ _x ];
  // Determine the bit index (lower three bits)
  byte shiftBit = mappedPort & 7;

  // Find which port it is (shift out the lower three bits and get the index)
  // And clear the given bit
  switch ( mappedPort >> 3 )
  {
    case 0:
      PORTB &= ~(1 << shiftBit);
      break;
      
    case 1:
      PORTE &= ~(1 << shiftBit);
      break;
      
    case 2:
      PORTG &= ~(1 << shiftBit);
      break;

    case 3:
      PORTH &= ~(1 << shiftBit);
      break;

  }
}