A finite floating-point number is represented as a sign (+ or −), a fixed number *n*+1 of digits d_{0}, d_{−1}, d_{−2}, d_{−n}, in some base *b*, and an exponent *e*, such that the number represented is *sign* d_{0}.d_{−1}d_{−2}…d_{−n} × *b*^{e}. For this answer, we take the sign as + and *b* as 2.

With this representation:

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

For any normal floating-point number, the ULP is *b*^{e−n}. However, near the lower bounds of the floating-point format, IEEE 754 has subnormal numbers, and the ULP is clamped to a value of *b*^{emin−n}.