Difference between revisions of "Derivatives Rates of Change"

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Rate of Change is used to describe the ratio of a change in one variable compare to a change of another variable
 
Rate of Change is used to describe the ratio of a change in one variable compare to a change of another variable
  
If there is a function <math>f(x)=y</math> then the rate of change of the function <math>f(x)</math> correspond to the rate of change of variable z is
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If there is a function <math>f(x)=y</math> then the rate of change of the function <math>f(x)</math> correspond to the rate of change of variable x is
 
:<math>\frac{\Delta y}{\Delta x}=\frac{\Delta f(x)}{\Delta x}</math>
 
:<math>\frac{\Delta y}{\Delta x}=\frac{\Delta f(x)}{\Delta x}</math>
  
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(Note that the letter <math>s</math> is often used to denote distance, which would yield <math>\frac{ds}{dt}</math> . The letter <math>d</math> is often avoided in denoting distance due to the potential confusion resulting from the expression <math>\frac{dd}{dt}</math>.)
 
(Note that the letter <math>s</math> is often used to denote distance, which would yield <math>\frac{ds}{dt}</math> . The letter <math>d</math> is often avoided in denoting distance due to the potential confusion resulting from the expression <math>\frac{dd}{dt}</math>.)
  
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==Definition of Instantaneous Rate of Change (Derivative)==
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Let <math>f(x)</math> be a function. Then <math>f'(x)=\lim_{h\to 0}\frac{f(x+h)-f(x)}{h}</math> wherever this limit exists. In this case we say that <math>f</math> is '''differentiable''' at <math>x</math> and its '''derivative''' at <math>x</math> is <math>f'(x)</math>.
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[[image:Tangent_as_Secant_Limit.svg|center]]
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Think of <math> h </math> as being the distance between the points <math> (x_0, f(x_0)) </math> and <math> (x_0 + h, f(x_0 + h)) </math>. Then, the average rate of change between these two points is
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: <math> \frac{\Delta f(x)}{\Delta x} = \frac{f(x_0+h)-f(x_0)}{(x_0 + h) - x_0} = \frac{f(x_0+h)-f(x_0)}{h}</math>.
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As the distance between the points goes to 0, we approach the instantaneous rate of change (slope) of <math> f(x) </math> at the point <math> x = x_0 </math>. This is how we derive (no pun intended) the definition of the derivative.
  
 
==Resources==
 
==Resources==
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* [https://youtu.be/jlihNi_Mkos Finding Instantaneous Rates of Change Using Def'n of Derivative] by patrickJMT
 
* [https://youtu.be/jlihNi_Mkos Finding Instantaneous Rates of Change Using Def'n of Derivative] by patrickJMT
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==Licensing==
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Content obtained and/or adapted from:
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* [https://en.wikibooks.org/wiki/Calculus/Differentiation/Differentiation_Defined Differentiation Defined, Wikibooks: Calculus/Differentiation] under a CC BY-SA license

Latest revision as of 09:26, 28 October 2021

Average Rate of Change

Rate of Change is used to describe the ratio of a change in one variable compare to a change of another variable

If there is a function then the rate of change of the function correspond to the rate of change of variable x is

For example, if there are two points and , then

The Rate of Change of a Function at a Point

Consider the formula for average velocity in the direction, , where is the change in over the time interval . This formula gives the average velocity over a period of time, but suppose we want to define the instantaneous velocity. To this end we look at the change in position as the change in time approaches 0. Mathematically this is written as: , which we abbreviate by the symbol . (The idea of this notation is that the letter denotes change.) Compare the symbol with . The idea is that both indicate a difference between two numbers, but denotes a finite difference while denotes an infinitesimal difference. Please note that the symbols and have no rigorous meaning on their own, since , and we can't divide by 0.

(Note that the letter is often used to denote distance, which would yield . The letter is often avoided in denoting distance due to the potential confusion resulting from the expression .)

Definition of Instantaneous Rate of Change (Derivative)

Let be a function. Then wherever this limit exists. In this case we say that is differentiable at and its derivative at is .

Tangent as Secant Limit.svg

Think of as being the distance between the points and . Then, the average rate of change between these two points is

.

As the distance between the points goes to 0, we approach the instantaneous rate of change (slope) of at the point . This is how we derive (no pun intended) the definition of the derivative.

Resources

Licensing

Content obtained and/or adapted from: