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

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

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.