When plotting two mathematically equivalent expressions very close to zero we get two similar results, but one of the curve has steps instead of being smooth.

1-cosh(x) == -2*sinh(x/2)^2

Zero sum

Now a quick observation reveals that the height of the step is indeed equal to the precision of Matlab, i.e. the variable eps = 2.2204e-16 = 2^-52

This graph was introduced with the name "zero sum", obviously not referencing a zero sum game. But apparently this only occurs with results of additions (or substractions) being very close to zero.

However, to my knowledge calculations with floating point numbers (or doubles) are similar in precision regardless of the scale at which the calculations are being made. So I'd expect error to only creep when something really big is being operated on with something really small, in which case the smaller number gets rounded off.

Matlab code to reproduce this:

x = linspace(-5*10^-8, 5*10^-8, 1001);
y1 = @(x) 1 - cosh(x);
y2 = @(x) -2*(sinh(x/2)).^2;

legend('1-cosh(x)', '-2sinh(x/2)^2')

Can someone explain how this.. works?

  • You are forgetting that cosh and sinh are actually numerical function that approximate the real continuous function – Ander Biguri Mar 6 '18 at 13:37

The rounding happens in the cosh function. If you plot it and zoom in to the graph at the same scale, you'll see the same staircase-like effect, but centered around 1 on the y-axis.

That is because you cannot represent those intermediate values using doubles.

  • But isn't the whole purpose of floating point numbers to be at whatever scale? The IEEE 754 standard defines a bit count for the exponent part of a double to be 11 bits, which is more than enough to represent 16 zeroes in decimal. So why wouldn't the sinh function have the steps as well if doubles cannot differentiate that small numbers? – Felix Mar 6 '18 at 13:40
  • 1
    Indeed, you can represent 1e-100, but you cannot represent 1+1e-100, which is what the result of cosh near 0 is. That one gets rounded to 16 digits, leading to 1.000000000000001 or something like that. Then you subtract the 1. – Cris Luengo Mar 6 '18 at 13:43
  • A-HA! So I was just thinking of it the wrong way! Thank you so much :D – Felix Mar 6 '18 at 13:45
  • @Felix in other words, IEEE 754 standard represents them at whatever scale, not at whatever precision – Ander Biguri Mar 6 '18 at 14:42
  • Yeah, that's what I thought, but somehow I failed to get that of course the 1 is going to determine the scale. – Felix Mar 6 '18 at 17:07

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