All Calculus 1 Resources
Example Questions
Example Question #1211 : Functions
Find the area under the curve between and .
In order to find the area underneath a curve for a specific range of values, we need to set up a definite integral expression. To do this, we plug our specific information into the following skeleton:
We plug in the equation of the curve in for , the smaller of our x-values for , and the larger of our x-values for . For this problem, our set-up looks like this:
Next, we integrate our expression, ignoring our and values for now. We get:
Now, to find the area under the part of the curve we're looking for, we plug our and values into our integrated expression and find the difference, using the following skeleton:
In this problem, this looks like:
Which plugged into our integrated expression is:
With our final answer being:
Example Question #161 : Equations
First, integrate the expression. Remember, when integrating, raise the exponent by 1 and then put that result on the denominator as well: . Then, evaluate that expression by plugging in 2 and then subtract from that the result from plugging in 0: .
Example Question #163 : Integral Expressions
The first step I'd recommend is to chop up the expression into 3 terms since we have one denominator: . Now, integrate each term, remembering to add one to the exponent and then putting that result in the denominator as well: Tack on a "+C" at the end because it is an indefinite integral.
Example Question #163 : Integral Expressions
The first step I'd recommend is to chop up the expression into 3 terms since we have one denominator: . Now, integrate each term, remembering to add one to the exponent and then putting that result in the denominator as well: Tack on a "+C" at the end because it is an indefinite integral.
Example Question #162 : How To Find Integral Expressions
Evaluate the following integral:
The integral is equal to
and was found using the following rules:
Note that all of the constants of integration added up to a single C.
Example Question #165 : Integral Expressions
Evaluate the following integral:
To evaluate the integral, we can split the integral into the sum of two integrals:
The first integral can be solved using a substitution:
and the integral rewritten in terms of u is
The integral was solved using the identical rule.
Now, we replace u with our original term:
.
Solving the second integral, we get
using the following rule:
Summing the results, we get
Example Question #2241 : Calculus
Evaluate the following integral:
To evaluate the integral, we must make the following substitution:
The derivative was found using the following rule:
Next, we rewrite the integral and integrate:
The integral was found using the following rule:
Finally, replace u with our original x term:
Example Question #162 : Integral Expressions
Evaluate the following integral:
To integrate, we can split the integral into three integrals, for ease of making substitutions later:
To integrate the first integral, we must make the following substitution:
Next, rewrite the integral and integrate:
The integral was performed using the following rule:
Finally, replace u with the original term:
The result of all three integrals, added together, is
and the other two integrals were integrated using the following rules:
,
Example Question #168 : Integral Expressions
Evaluate the following integral:
To evaluate the integral, we must make the following substitution:
The derivative was found using the following rule:
Next, rewrite the integral in terms of u and integrate:
The integral was found using the following rule:
Finally, replace u with our original x term:
Example Question #1221 : Functions
Evaluate the following integral:
To evaluate the integral, we first must perform the following substitution:
The derivative was found using the following rule:
Now, rewrite the integral and integrate:
The integral was performed using the following rule:
Finally, replace u with our original term: