1a1b
§2.1 Derivatives and Rates of Change
Tangent Lines
axes, curve C
Consider a smooth curve C.
A line tangent to C at a point P both intersects C at P and has the same slope as C at P. add line
The Tangent Line Problem
Given point P on curve C, how do you find the tangent line?
Example. Consider
-,-,
What is the equation of the line tangent to the curve at ? add , line
Point-slope form for a straight line passing through
What is the slope ?
What is the slope of the secant passing through and ? add
What is the slope of the secant passing through and ? add
What is the slope of the secant line passing through and ?
this ratio is called a difference quotient
As long as ,
The slope of the tangent line is the limit of the difference quotient as .
The equation of the tangent line is
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Example. Find an equation of the line tangent to the curve at .
Point slope form of the tangent line
where
simplify the difference quotient
multiply by 1 to rationalize the numerator
cancel factors of
true if
Thus
Equation of tangent line
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The Velocity Problem
Drive to Spokane airport (~85 miles)
Start at noon
Drive slowly through Colfax
Have lunch at Harvester
Arrive 2pm
The speedometer 5 miles north of Colfax reads 65 mph. This is the “instantaneous velocity.”
Mathematical definition of instantaneous velocity?
Galileo drops a ball off the leaning Tower of Pisa
sketch ground, tower, coordinate with origin at top
ball falls distance at time after release.
meters, seconds
-,-, curve
What is the average velocity between and ?
Average velocity
What is the average velocity between and a variable ?
Average velocity
as long as .
Table
Define instantaneous velocity at as the limit of average velocities over shorter and shorter time intervals around .
Denote instantaneous velocity .
Derivatives
Define the derivative of a function at a number , denoted
[1]
From the example above .
Alternatively, introduce
and insert in equation [1] to get
[2]
§2.2 The Derivative as a Function
Replace the symbol in [2] by . Regard as a variable.
Regard as a new function.
Example. Let . Find
Simplify the difference quotient
this step assumes
Then
Graph and compare and
-, -,
-, -,
add tangent segments at to graph of
add dots at to graph of ■
Example. Let . Find .
Simplify the difference quotient
rationalize numerator by multiplying by 1
multiply terms in numerator
divide through by (assumes
Then
Show transparency comparing and
?? Transparency: match and
Notations for Derivative
original function:
derivative function:
prime notation emphasizes idea of derivative as a new function
the prime means differentiate with respect to function argument
evaluate at no.
Leibniz notation emphasizes idea of derivative as the limit of a ratio
evaluate at no.
Operator notation for derivative
Sometimes we write
or
view and as operators: machines that convert the functions they operate on into other functions
Differentiability
differentiable at means exists
differentiable on an open interval means is differentiable at every point in
Example (a function not differentiable at a point)
Is differentiable at ?
if so
does this limit exist?
find the limit from the right
find the limit from the left
the right and left hand limit do not agree.
conclude does not exist
Geometrical Idea
axes, graph of |x|, no tangent line here (at origin)
To be differentiable at point, the graph must have a unique tangent line at that point. ■
Three ways that a function can fail to be differentiable
(a)at any discontinuity
, function with dcty at
DNE
(b)at any corner or kink
, function with a kink at
DNE
(c) at a vertical tangent
function w/ a vertical tangent at
, DNE
Relationship between differentiability and continuity
We have shown: if is not continuous then is not differentiable
Let be the statement
is continuous at a no.
Let be the statement
is differentiable at
We have shown
If (not ) then (not )
This is logically equivalent to
If then
If is differentiable at then it is continuous atHigher Derivatives
Consider
First derivative of
Regarded as a function, may itself be differentiable.
Second derivative of
If is differentiable, form the third derivative
If is differentiable, form the fourth derivative
Notation for the derivative, with :
Application of higher derivatives
Let be the position of an object at time .
is the velocity of the object
is the acceleration of the object
First and second derivatives are the most important in applications
Example. Mechanics
momentum = mass velocity
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2.3 Basic Differentiation Rules
We first consider those rules that will enable us to differentiate polynomials.
Derivative of a Constant Function
-,-, line
slope of tangent line?
Derivative of
-, -,
slope of tangent line?
Derivative of
We have seen that
Derivative of
simplify the difference quotient
assumes
thus
The Power Rule.
Let be a positive integer
Example. . ■
Proof.
Preliminary fact:
______
in other words
notice there are terms on the right hand side
Let
Regard as a variable. Replace by .
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The Power Rule (general version)
Let be any real number.
Examples.
recall
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The Constant Multiple Rule
Let be a constant and a differentiable function
a constant passes through the limit symbol
Examples.
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The Sum Rule
If and are both differentiable
In words: “the derivative of a sum is the sum of the derivatives”
prime notation
shorthand
the sum rule applies to the sum of any number of functions
Example
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The Difference Rule
If and are both differentiable
In words: “the derivative of a difference is the difference of the derivatives”
prime notation
shorthand
Example.
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We can now differentiate any polynomial
Example. Let
then
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We can differentiate other functions too.
Example. Let
Find
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Example. Find an equation of the line tangent to the curve
at the point
point slope form for straight line
where
what is ?
answer
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?? Example. A ball is thrown straight up from the ground at 20 meters/second. Its height is given by
(a) Find the velocity at time .
(b) Find the velocity at sec.
(c) When is the ball at rest?
(d) What is the average velocity between and ?
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Economics – Marginal cost
cost to produce widgets
average rate of change of cost
marginal cost
Example. Jeans manufacture.
Let cost of producing pairs of jeans.
where
capital costs (sewing machines)
cost of labor, materials, rent
Cost of producing 100 pairs of jeans
What is the cost of producing one additional pair of jeans?
______
Cost of producing the 101ST pair
Compare with the marginal cost at 100th pair
is often a very good approximation to the cost of producing one additional widget. ■
Derivatives of Sine and Cosine
Recall the limits
Recall the addition formula for cosine
Now use the limit definition of derivative
addition formula for cosine
difference law for limits
constant multiple law of limits
recalling the limits above
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The derivative of may be found using a similar argument (see our text).
In summary:
?? Differentiate the following
1.
2.
§2.4 The Product and Quotient Rules
Product Rule
If and are both differentiable
or alternately (as I personally prefer)
prime notation
shorthand
WARNING: The derivative of a product is not the product of derivatives
This is a common mistake!
Example. By the power rule
Now let and
then and
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Proof of the Product Rule
Suppose and are both differentiable functions.
Let
then
subtract and add the same term in the numerator
algebra
sum and product laws forlimits
continuity of and definition of derivative
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Extension to a Product of Three Functions
If , and are all differentiable
Example. Let
then
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Example. Differentiate .
Law of exponents:
Then
Product rule
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Quotient Rule
If and are differentiable at a point where then
shorthand
terms in numerator in same order as my product rule (but take difference)
Proof of quotient rule.
Let
Then
By product rule
Solve for
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Example. Differentiate .
where is shorthand for
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Example. Find the equations of the tangent lines to the curve
that are parallel to the line
.
Solution. Parallel means same slope. Slope of line?
slope is
where does have slope ?
solve for
or
form of equation for tangent line
Consider .
Consider .
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?? Class practice product and quotient rules