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Suppose we want to calculate (a + b)2 in two different ways, that is

  1. (a + b) * (a + b)

  2. a2 + 2 a b + b2

Now, suppose a = 1.4 and b = -2.7. If we plug those two numbers in the formulas with format long we obtain in both cases 1.690000000000001, that is, if I run the following script:

a = 1.4; 
b = -2.7;

format long

r = (a + b) * (a + b)

r2 = a^2 + 2*a*b + b^2

abs_diff = abs(r - r2)

I obtain

r = 1.690000000000001

r2 = 1.690000000000001

abs_diff = 6.661338147750939e-16

What's going on here? I could preview different results for r or r2 (because Matlab would be executing different floating-point operations), but not for the absolute value of their difference.

I also noticed that the relative error of r and r2 are different, that is, if I do

rel_err1 = abs(1.69 - r) / 1.69
rel_err2 = abs(1.69 - r2) / 1.69

I obtain

rel_err1 = 3.941620205769786e-16

rel_err2 = 7.883240411539573e-16

This only makes me think that r are not actually the same r2. Is there a way to see them completely then, if they are really different? If not, what's happening?

Also, both relative errors are not less than eps / 2, does this mean that an overflow has happened? If yes, where?


Note: This is a specific case. I understood that we're dealing with floating-point numbers and rounding errors. But I would like a to understand better them by going through this example.

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  • 1
    It's likely due to the fact that floating point errors depends on the order, type and number of operations. Your two methods have different number and types of operations. The one with more additions theoretically introduces more floating point errors. Also more operations causes more propagation of the error.
    – Suever
    Mar 18, 2016 at 17:58
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    Simple answer: your two numbers are not equal. The long format is only giving you 16 significant digits, which isn't enough to distinguish these two numbers. Their exact values are 1.6900000000000006128431095930864103138446807861328125 and 1.690000000000001278976924368180334568023681640625, both of which are exactly representable as IEEE 754 binary floats, and both of which display as 1.690000000000001 when rounded to 16 significant (decimal) digits. Mar 18, 2016 at 18:05
  • 2
    format hex will show you the actual binary representation of the numbers. In this case, they are 3ffb0a3d70a3d70d and 3ffb0a3d70a3d710 for r and r2 respectively. Mar 18, 2016 at 18:14
  • 1
    @beaker Ok, maybe I will give an answer that englobes what you guys have been saying if nobody decides to do it ;)
    – nbro
    Mar 18, 2016 at 18:22
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    To track floating point issues, format long is not sufficient. You must print 17 digits stackoverflow.com/a/35626253/2732801 . Maybe that helps to understand the behaviour.
    – Daniel
    Mar 18, 2016 at 18:24

2 Answers 2

3

Don't rely on the output of format long to conclude that two numbers are equal...

a = 1.4;
b = -2.7
r1 = (a + b) * (a + b);
r2 = a^2 + 2*a*b + b^2;
r3 = (a+b)^2;

Instead you can check their hex representation using:

>> num2hex([r1 r2 r3])
ans =
3ffb0a3d70a3d70d
3ffb0a3d70a3d710
3ffb0a3d70a3d70d

or the printf family of functions:

>> fprintf('%bx\n', r1, r2, r3)
3ffb0a3d70a3d70d
3ffb0a3d70a3d710
3ffb0a3d70a3d70d

or even:

>> format hex
>> disp([r1; r2; r3])
   3ffb0a3d70a3d70d
   3ffb0a3d70a3d710
   3ffb0a3d70a3d70d
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  • What about the suggestion of using fprintf to print a floating-point number with as many decimal digits as we want, e.g., fprintf('%.60f', my_float);?
    – nbro
    Mar 19, 2016 at 1:22
  • I would always trust the hex representation more because that's the actual 1's and 0's stored, no rounding involved... Not to mention, how far will you go with fprintf if my_float = realmin for example?
    – Amro
    Mar 19, 2016 at 1:23
1

Floating point arithmetic is not associative.

While mathematically these two are equal, they are not in floating point maths.

r = (a + b) * (a + b)

r2 = a^2 + 2*a*b + b^2

The order operations are executed in floating point maths is very relevant. That is why when you do floating point maths you need to be very careful of the order of you r multiplications/divisions, specially when working with very big numbers together with really small numbers.

1
  • Ok, but if r and r2 are represent in memory apparently with the same number, their absolute difference would be equal to zero...
    – nbro
    Mar 18, 2016 at 18:04

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