Positive derivative implies increasing: Difference between revisions

Latest revision as of 02:11, 25 September 2021

Statement

On an open interval

Suppose $f$ is a function on an open interval $I$ that may be infinite in one or both directions (i..e, $I$ is of the form $(a, b)$ , $(a, \infty)$ , $(- \infty, b)$ , or $(- \infty, \infty)$ ). Suppose the derivative of $f$ exists and is positive everywhere on $I$ , i.e., $f^{'} (x) > 0$ for all $x \in I$ . Then, $f$ is an increasing function on $I$ , i.e.:

$x_{1}, x_{2} \in I, x_{1} < x_{2} ⟹ f (x_{1}) < f (x_{2})$

On a general interval

Suppose $f$ is a function on an interval $I$ that may be infinite in one or both directions and may be open or closed at either end. Suppose $f$ is a continuous function on all of $I$ and that the derivative of $f$ exists and is positive everywhere on the interior of $I$ , i.e., $f^{'} (x) > 0$ for all $x \in I$ other than the endpoints of $I$ (if they exist). Then, $f$ is an increasing function on $I$ , i.e.:

$x_{1}, x_{2} \in I, x_{1} < x_{2} ⟹ f (x_{1}) < f (x_{2})$

Related facts

Similar facts

Opposite facts

Positive derivative at a point not implies increasing around the point

Facts used

Lagrange mean value theorem

Proof

General version

Given: A function $f$ on interval $I$ such that $f^{'} (x) > 0$ for all $x$ in the interior of $I$ and $f$ is continuous on $I$ . Numbers $x_{1} < x_{2}$ with $x_{1}, x_{2} \in I$ .

To prove: $f (x_{1}) < f (x_{2})$

Proof:

Step no.	Assertion/construction	Facts used	Given data used	Previous steps used	Explanation
1	Consider the difference quotient $\frac{f (x_{2}) - f (x_{1})}{x_{2} - x_{1}}$ . There exists $x_{3}$ such that $x_{1} < x_{3} < x_{2}$ and $f^{'} (x_{3})$ equals this difference quotient.	Fact (1)	$x_{1} < x_{2}$ , $f$ is defined and continuous on an interval $I$ containing $x_{1}, x_{2}$ , differentiable on the interior of the interval.		[SHOW MORE] Since $f$ is defined and continuous on an interval containing both $x_{1}$ and $x_{2}$ , it is in particular defined and on $[x_{1}, x_{2}]$ , which lies inside the open interval. Further, $f$ is differentiable on the interior of $I$ , and hence on the open interval $(x_{1}, x_{2})$ , which is contained in the interior of $I$ . Thus, the conditions needed to apply Fact (1) are available. Using Fact (1) gives the existence of $x_{3}$ such that $f^{'} (x_{3})$ equals the difference quotient.
2	The difference quotient $\frac{f (x_{2}) - f (x_{1})}{x_{2} - x_{1}}$ is positive.		$f^{'} (x)$ is positive for all $x$ in the interior of $I$ .	Step (1)	[SHOW MORE] By Step (1), there exists $x_{3}$ such that $f^{'} (x_{3})$ equals the difference quotient. From the given data, $f^{'} (x_{3})$ is positive. Combining, we obtain that the difference quotient itself is positive.
3	$f (x_{1}) < f (x_{2})$		$x_{1} < x_{2}$	Step (2)	[SHOW MORE] In Step (2), we obtained that the difference quotient is positive. The denominator of the expression is positive because $x_{1} < x_{2}$ . Thus, the numerator must also be positive, giving $f (x_{1}) < f (x_{2})$ upon rearrangement.

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 ===Similar facts===
-* [[Positive derivative at a point implies increasing around the point]]
 * [[Zero derivative implies locally constant]]
 * [[Negative derivative implies decreasing]]
 * [[Nonnegative derivative that is zero only at isolated points implies increasing]]
 * [[Increasing and differentiable implies nonnegative derivative]]
+===Opposite facts===
+* [[Positive derivative at a point not implies increasing around the point]]
 ==Facts used==