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Assume a hanging cable has the shape for Determine the length of the cable (in feet).
[T] Find expressions for and Use a calculator to graph these functions and ensure your expression is correct.
From the definitions of and find their antiderivatives.
Use the quotient rule to verify that
Take the derivative of the previous expression to find an expression for
Prove by changing the expression to exponentials.
Answers may vary
Take the derivative of the previous expression to find an expression for
For the following exercises, find the derivatives of the given functions and graph along with the function to ensure your answer is correct.
For the following exercises, find the antiderivatives for the given functions.
For the following exercises, find the derivatives for the functions.
For the following exercises, find the antiderivatives for the functions.
For the following exercises, use the fact that a falling body with friction equal to velocity squared obeys the equation
Derive the previous expression for by integrating
[T] Estimate how far a body has fallen in seconds by finding the area underneath the curve of
For the following exercises, use this scenario: A cable hanging under its own weight has a slope that satisfies The constant is the ratio of cable density to tension.
Show that satisfies this equation.
Sketch the cable and determine how far down it sags at
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