All AP Calculus BC Resources
Example Questions
Example Question #372 : Ap Calculus Bc
Give .
, and the derivative of a constant is 0, so
Example Question #373 : Ap Calculus Bc
Give .
First, find the derivative of .
, and the derivative of a constant is 0, so
Now, differentiate to get .
Example Question #374 : Ap Calculus Bc
Differentiate .
, so
Example Question #375 : Ap Calculus Bc
Give the second derivative of .
Find the derivative of , then find the derivative of that expression.
, so
Example Question #376 : Ap Calculus Bc
Give .
, and the derivative of a constant is 0, so
Example Question #377 : Ap Calculus Bc
Give .
First, find the derivative of .
Recall that , and the derivative of a constant is 0.
Now, differentiate to get .
Example Question #1 : Computation Of Derivatives
Find the derivative of the function
None of the other answers.
We can use the (first part of) the Fundemental Theorem of Calculus to "cancel out" the integral.
. Start
. Take the derivative of both sides with respect to .
To "cancel out" the integral and the derivative sign, verify that the lower bound on the integral is a constant (It's in this case), and that the upper limit of the integral is a function of , (it's in this case).
Afterward, plug in for , and ultilize the Chain Rule to complete using the Fundemental Theorem of Calculus.
.
Example Question #378 : Ap Calculus Bc
Find the derivative of:
The derivative of inverse cosine is:
The derivative of cosine is:
Combine the two terms into one term.
Example Question #379 : Ap Calculus Bc
Find the derivative of the function
Does not exist
None of the other answers
To find the derivative of this function, we need to use the Fundemental Theorem of Calculus Part 1 (As opposed to the 2nd part, which is what's usually used to evaluate definite integrals)
. Start
. Take derivatives of both sides.
. "Cancel" the integral and the derivative. (Make sure that the upper bound on the integral is a function of , and that the lower bound is a constant before you cancel, otherwise you may need to use some manipulation of the bounds to make it so.)
Example Question #10 : Rules Of Basic Functions: Power, Exponential Rule, Logarithmic, Trigonometric, And Inverse Trigonometric
What is the rate of change of the function at the point ?
The rate of change of a function at a point is the value of the derivative at that point. First, take the derivative of f(x) using the power rule for each term.
Remember that the power rule is
, and that the derivative of a constant is zero.
Next, notice that the x-value of the point (1,6) is 1, so substitute 1 for x in the derivative.
Therefore, the rate of change of f(x) at the point (1,6) is 14.