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I've been playing with LEDs a lot recently, powered by 8-bit micro controllers. Sometimes it's necessary to use purely software implementations of Pulse Width Modulation to control LED brightness - that is turning the light on and off rapidly varying the ratio of time on and off. This works great until I get down to about 5% brightness, where the strobing starts looking uncomfortably flickery to the eye.

Implementing the PWM as a loop, it steps through each number from 0-255 setting the light on or off for that moment. A light which is set at the 20 value will be on for the first 20 loops then turned off.

I'm looking for a good function which will shuffle around those numbers, so instead of looping through 0, 1, 2, 3... my loop could sample semi-randomly from the pool of possibilities. The aggregate brightness over time is the same, but a light at 20 brightness value may switch on and off a dozen or so times spread across 256 loops instead of just lighting once then turning off for most of the loop. This reduces the flickering effect even if the loop runs slightly slower.

A good dithering function would need to return every number in the 8-bit range when called with every 8-bit number. It would therefore also need to produce no duplicate numbers - not random, just shuffled. It's best if it tends not to put similar numbers together in sequence - the difference between each number aught to be high - ideally about 64-127 I figure.

The limitations are also interesting - it's a time critical application. Addition, subtraction, and bitwise operations cost 1 arbitrary unit of time, multiplication costs 2 units, and division costs 4 units. Floats are out of the questions, and the costs roughly double for every multiple of 8 bits used in an intermediate number. Lookup tables are possible, but would use roughly half of the total memory capacity of the device - so fast algorithms are best for reusability, but good quality slow algorithms are also very useful when there's space to precompute.

Thanks for helping me out with any ideas or musings. :)

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Missing homework tag... ;-) Sorry but the second-to-last paragraph with the silly made-up time unit costs gave you away. –  R.. Apr 6 '12 at 3:27
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Actually not homework. I'm just not sure strictly how many cycles those operations take in avr-libc. That's just my general understanding of how the timing works. It seemed best not to be more specific than I am confident lest someone critique incorrectness. :) –  blixxy Apr 6 '12 at 3:35
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Gosh you guys. I sometimes tutor highschoolers and first years who're doing first year compsci courses. I guess my writing style for these sorts of problems has been a bit affected by that. :P –  blixxy Apr 6 '12 at 3:38
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Dont you have a frequency tuner that can increase the Modulation frequency so that the flickering reduces? –  uDaY Apr 6 '12 at 4:01
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Damn. I'm a bit new to this site, thought that little up arrow was like a 'reply to' button. @uDaY: There is that. We used about 15 little micro controllers in a recent installation, and if we were to hook up external frequency clocks best case cost would have been $20 more or so at the time, as well as dozens more little things to solder together - pretty substantial for two unemployed artists. Some of the better chips you can overclock in software, but they cost a fair bit more too. :) –  blixxy Apr 6 '12 at 4:18

1 Answer 1

up vote 3 down vote accepted

Not 100% sure I understand correctly, but basically I think that any numbers that doesn't divide 256 will generate the group of numbers 0..255 if you just keep adding it to itself modulo 256. Some flashbacks from the abstract algebra class...

like this:

s = {}

n = 157
for i in range(0, 256):
   s[n] = True
   print n
   n += 157
   n %= 256

print "check: has to be 256: ", len(s) 

EDIT: replaced small generator with a larger one to make the distribution more "random".

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Aw man you totally win! This thing looks like just the ticket. No more flickery desk ornaments for me! :D –  blixxy Apr 6 '12 at 3:57
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@blixxy every time I get to actually use any of the math I remember, it makes me so insanely happy. –  MK. Apr 6 '12 at 12:38

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