All AP Calculus AB Resources
Example Questions
Example Question #3 : Derivative Defined As The Limit Of The Difference Quotient
What is the derivative of ?
To find the first derivative, we can use the power rule. We lower the exponent on all the variables by one and multiply by the original variable.
We're going to treat as since anything to the zero power is one.
For this problem that would look like this:
Notice that since anything times zero is zero.
Example Question #21 : Derivatives
What is the derivative of ?
To find the first derivative, we can use the power rule. To do that, we lower the exponent on the variables by one and multiply by the original exponent.
We're going to treat as since anything to the zero power is one.
Notice that since anything times zero is zero.
Example Question #21 : Finding Derivatives
Find the derivative of the following function:
We use the power rule on each term of the function.
The first term
becomes
.
The second term
becomes
.
The final term, 7, is a constant, so its derivative is simply zero.
Example Question #632 : Derivatives
Evaluate:
The notation is alluding to the fact that the limit is a function of , not necessarily a "number."
We are not going to evaluate this directly. Looking at the function, it seems very similar to the definition of a derivative of some kind of trigonometric function. We will look at the definition of a derivative to find a function that would have a derivative defined by this limit.
In otherwords, we wish to identify a function such that its' derivative is the function .
Let's find such that:
Compare corresponding terms in the numerators in the above expressions.
By inspection, these terms clearly indicate that our function must be of the form:
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Side note
If your confused by the inclusion of the arbitrary constant , note that when we differentiate this function the constant term will vanish since the derivative of a constant is zero. You can also see that in applying the definition of a derivative, if I included the constant in the two terms in the numerator,
the constant "C" would vanish when we subtract the latter from the former, .
Therefore, even if you didn't consider the constant when working out the function, it would not have changed the result
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Because we know that
,
Simply differentiate to find ,
Therefore,
Or to put it another way,
Example Question #12 : Concept Of The Derivative
Evaluate .
Does not exist
Not enough information is given to solve the problem.
This limit can't be evaluated by conventional limit laws. To see why the answer is , we have to recognize that the limit looks like
, with .
This new limit is a conventional expression for , with substituted in for
We can find with the power rule, and substituting gives .
To summarize, since
, we have
.
Example Question #13 : Concept Of The Derivative
Calculate the limit by interpreting it as the definition of the derivative of a function.
There are two commonly used formulations of the difference quotient used to compute derviatives. Both definitions are equivalent and should always give the same derivative for a given function .
The limit in this particular problem resembles the first difference quotient listed above.
By inspection, it's clear that the in our case must be . We are being asked to evaluate the limit by interpreting it as the definition of the derivative of a function. We must therefore identify the function, which is clearly , and then differentiate it using known rules of differentiation.
First rewrite the function to apply the rule for :
This means
Example Question #11 : Derivative Defined As The Limit Of The Difference Quotient
Give the difference quotient of the function
The difference quotient of a function is the expression
.
If , this expression is
Example Question #21 : Concept Of The Derivative
Find the derivative of the following function:
The derivative of a function can be defined according to the following:
Using this for our function - and not forgetting to write the limit for every step! - we get
Example Question #637 : Derivatives
Find the derivative of the function using the limit of the difference quotient:
The limit does not exist
The derivative of a function as defined by the limit of the difference quotient is
Evaluating the limit using our function - and always writing the limit symbol! - we get
Example Question #14 : Derivative Defined As The Limit Of The Difference Quotient
Find the derivative of the function using the limit of the difference quotient
To find the derivative using the limit of the difference quotient, we use the formula: