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I've distilled an equation down to this:

speed = ( ( rear_wheel_speed_a + front_wheel_speed_a ) << 10 ) +
        ( ( rear_wheel_speed_b + front_wheel_speed_b ) << 2 );

but for some reason I'm getting unexpected results so I must be doing something wrong. This started out like this:

speed = ((((rear_wheel_speed_a * 256 + rear_wheel_speed_b) / 16) +
        ((front_wheel_speed_a * 256 + front_wheel_speed_b) / 16)) / 2) * 128;

That is the completely unsimplified version that does work. Are they not mathematically equivalents?

all values are signed 16 bit integers. An example data set is:

rear_wheel_speed_a = 0x03;
rear_wheel_speed_b = 0x6F; //<-- I originally swapped
front_wheel_speed_a = 0x02; //<-- these two values. Sorry!
front_wheel_speed_b = 0xE2;

That boils down to an answer of 6468. But in the first equation, my application behaves as though it is at least 3% smaller or larger. I say it like that because this is an embedded application where I have no way of confirming the outcome of the calculations other than to test if it is within a certain range of "normal". When I use the 2nd equation it falls within the parameters but with my "simplified" (bit shifted) equation it does not so I think I must be doing the shifts incorrectly (or I simplified wrong but I triple checked it).

Any insight is appreciated, thank you.

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"all values are signed 16-bit integers" mean that read_wheel_speed_a can take the value 0xEFFF for example? Or rear_wheel_speed is stored in the two bytes rear_wheel_speed_a (hi) and read_wheel_speed_b (lo)? –  Eric Bainville Sep 8 '09 at 8:39
Doing bit shifting of signed values won't necessarily deal with the sign bit the way you want. Unless you're prepared to thoroughly test the possible inputs, and are aware you're reducing your code's portability, stick to multiply/divide and let the compiler do the optimisation. en.wikipedia.org/wiki/… –  Craig McQueen Sep 8 '09 at 9:32
the use of signed shouldn't be causing concern. It is only signed for easier integration with other variables in our program. ALL values above are ALWAYS positive and because there is no use of a minus in the equation they are always going to be that way. Eric - yes you are correct, each variable can be from zero to 0xEFFF (zero only by way of they can't be negative in our case) –  Steven Sep 8 '09 at 14:29
I'm a bloody idiot. Sorry everyone! It was in fact overflow as most of you suggested, but not because it overflowed the signed int16 range... its because it overflowed the unsigned int8 range :( You know those times when you overlook the stupidest things? Virtually all the values we're working with were 8 bit and we've upscaled everything and are using 16 bit. Somehow in the change these got missed on the copy I was working with last night. All good now. Thanks everyone. Thanks especially to Xeor for simplifying my equation further! And for tipping me off on my typo which led to the fix –  Steven Sep 8 '09 at 15:24

4 Answers 4

up vote 4 down vote accepted

From the second formula, I assume you operating 2 16bit values separated into their 8bit part a and b:

rear_wheel_speed = 0x0302
front_wheel_speed = 0x6fe2

and the formula you using, can be simplified into speed=(front_speed+rear_speed)*4.

From your values, 0x6fe2*4 just can fit 16bit, so this value can be evaluated in 16-bit arithmetic. But the values look like their parts are arranged wrong, and I have a feeling that real values are 0x036f and 0x02e2 (or 0x03ea and 0x026f) - those values are close to each other, as should be expected from speed of two wheels.

Also it seems your formula is better, because it doesn't introduce loss of precision on divide operations. But keep in mind, that if you're using a good compiler (not always true for embedded applications) it usually converts divide/multiply to shifts itself when possible

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You were right that I mixed up the values. And also right about the further simplification! Not sure how I missed that. Simpler is better :) –  Steven Sep 8 '09 at 14:39

The problem is that you're getting an overflow. While the equation you've transformed is mathematically correct, some of your interim values are higher than the signed 16-bit ints you're storing them in.

To be specific, the problematic part is

( rear_wheel_speed_a + front_wheel_speed_a ) << 10

With your sample input, the resulting value is 0x1C800 - larger than even an unsigned 16-bit integer!

The original equation seems to already take this into account. Some of the values lose precision slightly when downshifting, but that's better than the integer overflowing. So I recommend using the original equation, but you can replace the multiply and divide with shifts, of course:

((((rear_wheel_speed_a << 8) + rear_wheel_speed_b) >> 4) + (((front_wheel_speed_a << 8) + front_wheel_speed_b) >> 4)) << 6;

Another note: Your input front_wheel_speed_b is already overflowing, unless it is supposed to be negative.

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I'm ashamed of myself... in my sample data I posted swapped values for rear_wheel_speed_a and front_wheel_speed_b. I've now corrected them, because I really shouldn't be getting an overflow! The first (problematic) term evaulates to 0x1400, well within signed int16 range. Very sorry for that sample data mix-up. –  Steven Sep 8 '09 at 14:25
"To be specific, the problematic part is ( rear_wheel_speed_a + front_wheel_speed_a ) << 10" When I calculate this, I get: >>> hex(0x03 + 0x02 << 10) '0x1400', which easily fits in a signed 16 bit int. –  recursive Sep 8 '09 at 14:34
Hah. Ok, that inconsistency is explained. –  recursive Sep 8 '09 at 14:35

What you want is the mean of rear_wheel_speed and front_wheel_speed, scaled to fit on 16 bits. Since they are 16-bit values, the sum is on 17 bits, so you have to shift the result to avoid overflow.

Your initial formula takes each speed on 12 bits (xxx/16), then the mean of the values, again on 12 bits, then multiplies by 128. This will require 19 bits: your initial formula will overflow for larger values.

To get the mean on 16 bits without overflow, I suggest the following (assuming the values are positive as you said in your comment):

rear_wheel_speed_h = (rear_wheel_speed_a << 7) | (rear_wheel_speed_b >> 1)
front_wheel_speed_h = (front_wheel_speed_a << 7) | (front_wheel_speed_b >> 1)
speed = rear_wheel_speed_h + front_wheel_speed_h

This will give a result on 16 bits without overflow. Each xxx_wheel_speed_h is on 15 bits.

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In the original expression, the division operators are throwing away low-order bits, but clearly your substitute is not throwing away any low-order bits anywhere, so that alone means they can't be equivalent!

"rear_wheel_speed_b) / 16)" discards the 4 low-order bits of rear_wheel_speed before any operations are done on them, and "front_wheel_speed_b) / 16)" discards the 4 low-order bits of front_wheel_speed. Then the "/ 2)" operator discards the low-order bit of the sum.

You can only get exactly the same result if you put something in your expression to zero-out those same bits:

speed = ((((rear_wheel_speed_a * 256 + rear_wheel_speed_b) / 16) +
        ((front_wheel_speed_a * 256 + front_wheel_speed_b) / 16)) / 2) * 128;


speed = ( ( rear_wheel_speed_a + front_wheel_speed_a ) << 10 ) +
        ( ( ( ( rear_wheel_speed_b & ~0x0F ) + ( front_wheel_speed_b & ~0x0F ) ) & ~1) << 2 );

To put it another way,
yes ((((x * 256) / 16) / 2) * 128) == ((((x << 8) >> 4) >> 1) << 7),
and yes, ((((x << 8) >> 4) >> 1) << 7)== (x << 10),
and yes (((y / 16) / 2 ) * 128 ) == (( y >> 5 ) << 7),
but no (( y >> 5 ) << 7) != (y << 2)!
and no (((a + b) >> 1) << 7) != (((a >> 1) << 7) + (((b >> 1) << 7)!

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