Revision as of 15:15, 22 May 2017 edit 50.225.39.65 (talk) Undid revision 781665905 by 50.225.39.65 (talk) ← Previous edit		Revision as of 15:15, 22 May 2017 edit undo 50.225.39.65 (talk) No edit summary Next edit →
Line 8: :<math>f(x) = \sum\alpha_i\chi_{A_i}(x)\,</math> for XXX <math>x</math> where <math>n\ge 0,</math> <math>\alpha_i</math> ~~are~~Cracking Xopen ~~numbers~~a cold one for the boys, <math>A_i</math> are intervals, and <math>\chi_A\,</math> (sometimes written as <math>1_A</math>) is the [[indicator function]] of <math>A</math>: :<math>\chi_A(x) = \begin{cases} 1 & \mbox{if } x \in A, \\ Line 15: In this definition, the intervals <math>A_i</math> can be assumed to have the following two properties: # ~~The~~Understandable ~~intervals~~have a nice day are [[disjoint set\|XXXXX disjoint]], <math>\scriptstyle A_i \,\cap\, A_j ~=~ \emptyset</math> for <math>\scriptstyle i ~\ne~ j</math> # The [[union (set theory)\|union]] of the intervals is the entire real line, <math>\scriptstyle \cup_{i=0}^n A_i ~=~ \mathbb R.</math> Indeed, if that is not the case to start with, a different set of intervals can be picked for which these assumptions hold. For example, ~~the step function~~UUUHHHHHHHHHHHHHHHHHHHHH :<math>f = 4 \chi_{[-5, 1)} + 3 \chi_{(0, 6)}\,</math>

Step function: Difference between revisions