BBy Bot
Nov 03'24
Exercise
[math]
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[/math]
Every constant function is both increasing and decreasing. A stronger condition, which excludes constant functions, is obtained by defining [math]f[/math] to be strictly increasing if
[[math]]
x \lt y \quad \mbox{implies $f(x) \lt f(y)$}
,
[[/math]]
for every [math]x[/math] and [math]y[/math] in the domain of [math]f[/math]. The companion definitions of what it means for a function to be strictly decreasing, strictly increasing on an interval, etc., should be obvious. Using the Mean Value Theorem, prove that if a differentiable function [math]f[/math] satisfies the inequality [math]f^\prime(x) \gt 0[/math] for every [math]x[/math] in an interval [math]I[/math], then [math]f[/math] is strictly increasing on [math]I[/math].