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I am making a persistence of vision display using an ATTiny85, programmed with Arduino using the arduino-tiny core.

It consists of a stick with 16 LEDs on it which is spun round quickly to 'draw' a picture in the air. The display buffer is represented by an array, the next index of which is output every time the timer fires. It uses a hall sensor wired to INT0 to sense top dead centre, where it zeroes the array index.

It is an 8 bit processor and I have 16 LEDs connected to LED drivers, so I actually use two arrays for the display.

So the weird thing is that when I initialised the display with a cross pattern, it displayed a bunch of broken lines; so I zeroed it first in case memory had some random stuff in it. Now it doesn't display anything (even though I write the cross pattern to it straight after zeroing it). I have no idea what is happening, any ideas?

I had it previously outputting just the index value, and the picture it traces appears to look like counting binary, so I think the hardware is working.

Note that I'm not using digitalWrite because it disables interrupts which might throw the timing off.

Here is the code: (sorry it's quite a lot)

#define COLUMNCOUNT 180

const int datapin = 4;
const int clockpin = 0;
const int latchpin = 1;
const int rxpin = 3;
const int hallpin = 2;

volatile int columns0[COLUMNCOUNT];
volatile int columns1[COLUMNCOUNT];
volatile int counter = 0;

void setup()
{
  pinMode(datapin, OUTPUT);
  pinMode(clockpin, OUTPUT);
  pinMode(latchpin, OUTPUT);
  pinMode(rxpin, INPUT);
  pinMode(hallpin, INPUT);


  //make sure the arrays are all zeroed
  for (int i = 0; i < COLUMNCOUNT; i++)
  {
    columns0[i] = 0;
    columns1[i] = 0;
  }

  //make a cross pattern
  columns0[0] = 255;
  columns1[0] = 255;
  columns0[45] = 255;
  columns1[45] = 255;
  columns0[90] = 255;
  columns1[90] = 255;
  columns0[135] = 255;
  columns1[135] = 255;

  //turn on the timer (prescale CK/16)
  OCR1A = 255;
  OCR1C = 255;
  TCNT1 = 0;
  TIMSK = _BV(OCIE1A);
  TCCR1 = _BV(CTC1) | _BV(CS12) | _BV(CS10);

  GIMSK = _BV(INT0);

  sei();
}

void loop()
{
  //nothing to do here
}


ISR(TIMER1_COMPA_vect)
{
   if (counter < COLUMNCOUNT)
     counter++;

   outputWord(columns0[counter], columns1[counter]);
}


ISR(INT0_vect)
{
  counter = 0;
}


void outputByte(int b)
{
  int currentBit;

  for (int i = 0; i < 8; i++)
  {
    currentBit = (b & 128) == 128;
    PORTB = _BV(clockpin) | (currentBit ? _BV(datapin) : 0);
    PORTB = PORTB ^ _BV(clockpin);

    b <<= 1;
  }
}


void outputWord(int hi, int lo)
{
  outputByte(hi);
  outputByte(lo);
  PORTB = _BV(latchpin);
  PORTB = 0;
}
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3 Answers 3

up vote 1 down vote accepted

Per C standard, global variables are initialised to 0. As such,

//make sure the arrays are all zeroed
for (int i = 0; i < COLUMNCOUNT; i++)
{
  columns0[i] = 0;
  columns1[i] = 0;
}

is not necessary. That action is taken care of automatically when the __do_clear_bss section is executed.

Also, as per C standard, the int type must be at least 16 bits wide. In AVR, the minimum is used. If you are using the free software toolchain, it contains inttypes.h which provides the functionality offered by stdint.h and some extra stuff. This was mentioned in another answer.

The statement:

PORTB = PORTB ^ _BV(clockpin);

can be rewritten as:

PINB = _BV(clockpin);

which compiles to only 1 instruction, as per Atmel's datasheets.

Macros provided by pgmspace.h can read from flash. Notice that you can not change the contents of flash as your program runs in most AVR chips.

Beware local/global variables and stack/heap collisions when handling this much data.

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I've figured it out: it's an SRAM issue. The ATTiny85 only has 512 bytes of SRAM, so it can't hold all that data in memory at the same time. I'm investigating storing the data in flash memory using the PROGMEM directive instead.

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Note that int is 16 bit in avr-gcc so you could reclaim a lot of memory by switching to unsigned char which might fit in 512B. –  Ben Jackson Jan 18 '13 at 23:29
    
Thanks. It's an 8 bit processor though, so I assumed every data type was 8 bits; is this correct? –  stewartml Jan 19 '13 at 1:32
2  
The registers are 8 bits, but you can use 8, 16 and 32 bit types in your C code and the compiler will deal with it for you. In this particular case the type int is 16 bits, but on embedded systems like these I use stdint.h and explicit types like int8_t and int16_t to avoid confusion. –  Ben Jackson Jan 19 '13 at 2:02
    
Thanks very much, I'll give it a go! –  stewartml Jan 19 '13 at 11:53

I am also doing a Persistance of Vision (POV) with the Attiny44. (I am programming it via the Arduino as an ISP)

user Ben Jackson's tip for conserving SRAM memory was spot on: I originally was using "int"'s for my arrays and my Attiny would bug out if I tried to include additional arrays- However when I simply declared all of my arrays as "unsigned char"'s my code worked fabulously as it should!

Next time I will either order attiny45's or similar for more SRAM memory, and continue to use unsigned char's for my array declarations. Thanks for the discussion guys!

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