-5

We can represent 1.0 as 2^0 x 1.0 and the greatest representable number smaller than 1.0 as k, where k = 2^0 x 0.111.......1 truncated to fit.

Then the difference or ulp for 1.0 - k = 2^0 x 0.00000.....1.

Isn't that the same as machine epsilon, where we have N epsilon = 2^0 x 1.000000....1 - 2^0 x 1.000 = 2^0 x 0.000.....1?

Why is the correct value half?

Also, how would one calculate ulp for values other than 1.0?

  • Your title doesn't agree with your actual question, and asks why a falsehood is true. – user207421 May 10 '18 at 22:08
  • @oldselflearner1959: Your title said the greatest representable value less than one was half an epsilon. It is not. It is one minus half an epsilon. – Eric Postpischil May 10 '18 at 22:17
8

A finite floating-point number is represented as a sign (+ or −), a fixed number n+1 of digits d0, d−1, d−2, dn, in some base b, and an exponent e, such that the number represented is sign d0.d−1d−2…dn × be. For this answer, we take the sign as + and b as 2.

With this representation:

  • 1 is +1.00…0 × 20.
  • The next number higher than 1 is +1.00…1 × 20. Since the dn digit increased by 1, it exceeds 1 by 20−n.
  • The next number lower than 1 is +1.11…1 × 2−1. Note the exponent decreased. This means its dn digit actually has the value 2−1−n. So it differs from 1 only by 2−1−n rather than 20−n.

For any normal floating-point number, the ULP is ben. However, near the lower bounds of the floating-point format, IEEE 754 has subnormal numbers, and the ULP is clamped to a value of beminn.

  • Thanks for the really clear answer - it took me some time to get it but it's clear in the end. Also, what do you mean by the ULP value getting clamped to b^{1-n}? or is it b^{-1-n}? – oldselflearner1959 May 10 '18 at 22:25
  • @oldselflearner1959: Actually, for subnormal values, the exponent is clamped to a minimum value called emin, not 1. I have corrected my answer. For subnormal values, the exponent cannot decrease any further. Instead, the first digit(s) decrease to zero. – Eric Postpischil May 10 '18 at 22:55

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