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I am doing some floating point calculations and the results are not as accurate as I want them to be.

This is the algorithm:

center = (max_x + min_x) / 2
distance = old_x - center
new_x = center + (distance * factor)

return new_x

min_x, max_x, and old_x are all floats. I believe that the greatest error is introduced when I'm taking the average of the max and the min, and then the error is multiplied by the factor (which can be a float).

How can I minimize the error due to FP computation so that new_x is as precise as it can be?

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Generally you should add floats in order from smallest to largest (in absolute value), so you could expand the expression, sort and then sum. –  Kerrek SB Jun 24 '11 at 17:24
Increasing the precisions (e.g. from a float to a double or something unbound, etc.) for intermediate calculations can also minimize errors. –  user166390 Jun 24 '11 at 17:26
I bet this is not what you're looking for. But according to my experience the error should be really small... Have you tried replacing the 2 with a 2.0? –  iolo Jun 24 '11 at 17:26
Error depends on range of all values if you are referring screen coordinates then error would be minimal as iolo said, still depends on factor. if coordinates in floating point 0-1 space then avoid smaller or bigger intermediate results. –  user641719 Jun 24 '11 at 17:35
In a typical floating-point representation, dividing by 2 does not decrease precission at all, unless you are at denormalised values, very close to 0 (for floats its around 1e-38). I don't think your problem comes from there. –  CygnusX1 Jun 24 '11 at 18:53

5 Answers 5

up vote 4 down vote accepted

If old_x and center are close then you're losing precision.

It's called Loss of significance

You could change the calculation so the subtraction happenS in the end:

center = (max_x + min_x) / 2
new_x = (center + (old_x * factor)) - (center * factor)
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Can you tell us why is this better? –  Karoly Horvath Jun 24 '11 at 17:36
I've added a link –  Yochai Timmer Jun 24 '11 at 17:41
the precision losing was clear to me.. I'm asking why your solution is any better? –  Karoly Horvath Jun 24 '11 at 17:45
probably could do some more manipulations with the devision... have you tried it ? –  Yochai Timmer Jun 24 '11 at 17:45
It's supposed to be better because you're not multiplying the error by the factor. This way you're calculating both sides of the subtraction, and then doing it once... so you only have the subtraction error once –  Yochai Timmer Jun 24 '11 at 17:48

Depending on your language, there is probably a fixed/arbitrary precision numeric type you can use such as decimal in python or BigDecimal in Java.

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Or, perhaps, just a wider type, such as a double -- which has quite a bit more relative precision than a float. (C# has decimal, which while still a relative floating point type, makes a double look like a tiny little inaccurate type.) Fixed precision numeric types often happen to be ... quite slow. –  user166390 Jun 24 '11 at 17:32
Fixed precision types are indeed slow, but you can specify exactly how you want them to work, and they will work that way cross-platform with no issues. This is really a language dependent question, because float type precision is cross-platform for some languages (JVM, CLR), but not others. –  limscoder Jun 24 '11 at 17:47

All the previous implementations do not use rounding and thus have a large error: Here's how to do this in fixed point math: I'm using X.1u prevision (1 LSB is used for fraction part).

//center = (max_x + min_x) / 2
center = max_x + min_x // zero error here

// distance = old_x - center
distance = (old_x << 1) - center // zero error here

//new_x = center + (distance * factor)
new_x = (**1** + center + (distance * factor)) >> 1

return new_x

If factor is a fixed point (integer) too with N bits describing the fraction then new_x can be calculated as:

new_x = ( (1 << N) + (center << N) + (distance * factor) ) >> (N + 1)
  • (center << N) has N+1 fraction bits
  • distance * factor has N+1 fraction bits
  • (1 << N) is a 'half' as 1 << (N+1) is 'one' in the above fixed point precision.

After understanding each part, the above line can be compacted:

new_x = ( ((1 + center) << N) + (distance * factor) ) >> (N + 1)

The used integer type should be large enough, off course. If the valid range is unknown, one should check the input to this function and something else. In most cases this isn't needed.

This is as good as it get in fixed point math. This is how HW circuits perform integer math operations.

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This eliminates at least one source of error from your original algorithm:

# Adding min and max can produce a value of larger magnitude, losing some low-order bits
center = min_x + (max_x - min_x)/2
distance = old_x - center
new_x = center + (distance * factor)

return new_x

If you have more knowledge of the relationship between old_x, min_x andmax_x, you can probably do better than this.

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As Yochai says, your problem is probably caused by the subtraction old_x - center. If old_x and center are close to each other then you lose precision.

The simple solution would be do to the computation using double instead of float, but I guess that's not possible. In that case, you need to get rid of the subtraction. One possibility is

distance_max = max_x - center
distance_min = min_x - center
distance = (distance_max + distance_min) / 2
new_x = center + factor * distance

This helps if max_x, min_x and center are quite far apart while the average of max_x and min_x is close to center. If that does not help, perhaps you can adapt the computation of max_x so that you actually compute max_x - center but that needs changes in the part you did not show us.

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max_x is computed using max(x1, x2, x3, ..., xn). –  MxyL Jun 27 '11 at 1:17
Don't take the average of the two distances that way. Add half their difference to the minimum of the pair, so that the low-order bits have a chance of making it through. –  Novelocrat Jun 30 '11 at 3:46

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