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Calculus Examples
Step 1
Step 1.1
Differentiate.
Step 1.1.1
By the Sum Rule, the derivative of with respect to is .
Step 1.1.2
Differentiate using the Power Rule which states that is where .
Step 1.2
Evaluate .
Step 1.2.1
Since is constant with respect to , the derivative of with respect to is .
Step 1.2.2
Rewrite as .
Step 1.2.3
Differentiate using the Power Rule which states that is where .
Step 1.2.4
Combine and .
Step 1.2.5
Move to the denominator using the negative exponent rule .
Step 1.3
Reorder terms.
Step 2
Step 2.1
By the Sum Rule, the derivative of with respect to is .
Step 2.2
Evaluate .
Step 2.2.1
Since is constant with respect to , the derivative of with respect to is .
Step 2.2.2
Rewrite as .
Step 2.2.3
Differentiate using the chain rule, which states that is where and .
Step 2.2.3.1
To apply the Chain Rule, set as .
Step 2.2.3.2
Differentiate using the Power Rule which states that is where .
Step 2.2.3.3
Replace all occurrences of with .
Step 2.2.4
Differentiate using the Power Rule which states that is where .
Step 2.2.5
Multiply the exponents in .
Step 2.2.5.1
Apply the power rule and multiply exponents, .
Step 2.2.5.2
Multiply by .
Step 2.2.6
Multiply by .
Step 2.2.7
Raise to the power of .
Step 2.2.8
Use the power rule to combine exponents.
Step 2.2.9
Subtract from .
Step 2.2.10
Multiply by .
Step 2.2.11
Combine and .
Step 2.2.12
Combine and .
Step 2.2.13
Move to the denominator using the negative exponent rule .
Step 2.3
Differentiate using the Constant Rule.
Step 2.3.1
Since is constant with respect to , the derivative of with respect to is .
Step 2.3.2
Add and .
Step 3
To find the local maximum and minimum values of the function, set the derivative equal to and solve.
Step 4
Step 4.1
Find the first derivative.
Step 4.1.1
Differentiate.
Step 4.1.1.1
By the Sum Rule, the derivative of with respect to is .
Step 4.1.1.2
Differentiate using the Power Rule which states that is where .
Step 4.1.2
Evaluate .
Step 4.1.2.1
Since is constant with respect to , the derivative of with respect to is .
Step 4.1.2.2
Rewrite as .
Step 4.1.2.3
Differentiate using the Power Rule which states that is where .
Step 4.1.2.4
Combine and .
Step 4.1.2.5
Move to the denominator using the negative exponent rule .
Step 4.1.3
Reorder terms.
Step 4.2
The first derivative of with respect to is .
Step 5
Step 5.1
Set the first derivative equal to .
Step 5.2
Subtract from both sides of the equation.
Step 5.3
Find the LCD of the terms in the equation.
Step 5.3.1
Finding the LCD of a list of values is the same as finding the LCM of the denominators of those values.
Step 5.3.2
The LCM of one and any expression is the expression.
Step 5.4
Multiply each term in by to eliminate the fractions.
Step 5.4.1
Multiply each term in by .
Step 5.4.2
Simplify the left side.
Step 5.4.2.1
Cancel the common factor of .
Step 5.4.2.1.1
Move the leading negative in into the numerator.
Step 5.4.2.1.2
Cancel the common factor.
Step 5.4.2.1.3
Rewrite the expression.
Step 5.4.3
Simplify the right side.
Step 5.4.3.1
Multiply by .
Step 5.5
Solve the equation.
Step 5.5.1
Rewrite the equation as .
Step 5.5.2
Divide each term in by and simplify.
Step 5.5.2.1
Divide each term in by .
Step 5.5.2.2
Simplify the left side.
Step 5.5.2.2.1
Cancel the common factor of .
Step 5.5.2.2.1.1
Cancel the common factor.
Step 5.5.2.2.1.2
Divide by .
Step 5.5.2.3
Simplify the right side.
Step 5.5.2.3.1
Dividing two negative values results in a positive value.
Step 5.5.3
Take the specified root of both sides of the equation to eliminate the exponent on the left side.
Step 5.5.4
Simplify .
Step 5.5.4.1
Rewrite as .
Step 5.5.4.2
Any root of is .
Step 5.5.4.3
Simplify the denominator.
Step 5.5.4.3.1
Rewrite as .
Step 5.5.4.3.2
Pull terms out from under the radical, assuming positive real numbers.
Step 5.5.5
The complete solution is the result of both the positive and negative portions of the solution.
Step 5.5.5.1
First, use the positive value of the to find the first solution.
Step 5.5.5.2
Next, use the negative value of the to find the second solution.
Step 5.5.5.3
The complete solution is the result of both the positive and negative portions of the solution.
Step 6
Step 6.1
Set the denominator in equal to to find where the expression is undefined.
Step 6.2
Solve for .
Step 6.2.1
Divide each term in by and simplify.
Step 6.2.1.1
Divide each term in by .
Step 6.2.1.2
Simplify the left side.
Step 6.2.1.2.1
Cancel the common factor of .
Step 6.2.1.2.1.1
Cancel the common factor.
Step 6.2.1.2.1.2
Divide by .
Step 6.2.1.3
Simplify the right side.
Step 6.2.1.3.1
Divide by .
Step 6.2.2
Take the specified root of both sides of the equation to eliminate the exponent on the left side.
Step 6.2.3
Simplify .
Step 6.2.3.1
Rewrite as .
Step 6.2.3.2
Pull terms out from under the radical, assuming positive real numbers.
Step 6.2.3.3
Plus or minus is .
Step 7
Critical points to evaluate.
Step 8
Evaluate the second derivative at . If the second derivative is positive, then this is a local minimum. If it is negative, then this is a local maximum.
Step 9
Step 9.1
Simplify the denominator.
Step 9.1.1
Rewrite as .
Step 9.1.2
Rewrite as .
Step 9.1.3
Raise to the power of .
Step 9.1.4
Apply the power rule and multiply exponents, .
Step 9.1.5
Multiply by .
Step 9.1.6
Multiply the exponents in .
Step 9.1.6.1
Apply the power rule and multiply exponents, .
Step 9.1.6.2
Multiply by .
Step 9.1.7
Use the power rule to combine exponents.
Step 9.1.8
Subtract from .
Step 9.2
Rewrite the expression using the negative exponent rule .
Step 9.3
Multiply the numerator by the reciprocal of the denominator.
Step 9.4
Multiply by .
Step 10
is a local minimum because the value of the second derivative is positive. This is referred to as the second derivative test.
is a local minimum
Step 11
Step 11.1
Replace the variable with in the expression.
Step 11.2
Simplify the result.
Step 11.2.1
Simplify each term.
Step 11.2.1.1
Combine and .
Step 11.2.1.2
Divide by .
Step 11.2.2
Combine fractions.
Step 11.2.2.1
Combine the numerators over the common denominator.
Step 11.2.2.2
Add and .
Step 11.2.3
The final answer is .
Step 12
Evaluate the second derivative at . If the second derivative is positive, then this is a local minimum. If it is negative, then this is a local maximum.
Step 13
Step 13.1
Simplify the denominator.
Step 13.1.1
Apply the product rule to .
Step 13.1.2
Combine exponents.
Step 13.1.2.1
Rewrite as .
Step 13.1.2.2
Raise to the power of .
Step 13.1.2.3
Apply the power rule and multiply exponents, .
Step 13.1.2.4
Multiply by .
Step 13.1.2.5
Multiply the exponents in .
Step 13.1.2.5.1
Apply the power rule and multiply exponents, .
Step 13.1.2.5.2
Multiply by .
Step 13.1.2.6
Rewrite as .
Step 13.1.2.7
Use the power rule to combine exponents.
Step 13.1.2.8
Add and .
Step 13.1.3
Rewrite the expression using the negative exponent rule .
Step 13.1.4
Raise to the power of .
Step 13.2
Combine fractions.
Step 13.2.1
Combine and .
Step 13.2.2
Simplify the expression.
Step 13.2.2.1
Move the negative in front of the fraction.
Step 13.2.2.2
Multiply the numerator by the reciprocal of the denominator.
Step 13.3
Multiply .
Step 13.3.1
Multiply by .
Step 13.3.2
Multiply by .
Step 14
is a local maximum because the value of the second derivative is negative. This is referred to as the second derivative test.
is a local maximum
Step 15
Step 15.1
Replace the variable with in the expression.
Step 15.2
Simplify the result.
Step 15.2.1
Simplify each term.
Step 15.2.1.1
Cancel the common factor of and .
Step 15.2.1.1.1
Rewrite as .
Step 15.2.1.1.2
Move the negative in front of the fraction.
Step 15.2.1.2
Combine and .
Step 15.2.1.3
Divide by .
Step 15.2.2
Combine fractions.
Step 15.2.2.1
Combine the numerators over the common denominator.
Step 15.2.2.2
Simplify the expression.
Step 15.2.2.2.1
Subtract from .
Step 15.2.2.2.2
Move the negative in front of the fraction.
Step 15.2.3
The final answer is .
Step 16
These are the local extrema for .
is a local minima
is a local maxima
Step 17