Use of the Fundamental Theorem to evaluate definite integrals - AP Calculus AB

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Question

Evaluate

$\int_{-1}^{e-2}\frac{1}{x+2}$

Answer

We will use the Fundamental Theorem of Calculus

$\int_{a}^{b}f(x)dx=F(b)-F(a)$

and the rule

$\int\frac{1}{x+a}dx=\ln(x+a)$

First we find the anti derivative

$\int_{-1}^{e-2}\frac{1}{x+2}=\ln(x+2)|_{-1}^{e-2}$

And then we evaluate, (upper minus lower)

$\ln(x+2)|_{-1}^{e-2}=\ln(e-2+2)-\ln(-1+2)=\ln(e)-\ln(1)$

(Remembering your logarithm rules)

$\ln(e)-\ln(1)=1-0=1$

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Question

Using the Fundamental Theorem of Calculus solve the integral.

$\int_{1}^{3}e^xdx$

Answer

To solve the integral using the Fundamental Theorem, we must first take the anti-derivative of the function. The anti-derivative of is . Since the limits of integration are 1 and 3, we must evaluate the anti-derivative at these two values.

denotes the anti-derivative.

When we do this,

and .

The next step is to find the difference between the values at each limit of integration, because the Fundamental Theorem states

$\int_{a}^{b}f(x)dx=F(b)-F(a)$ .

Thus, we subtract to get a final answer of .

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Question

Using the Fundamental Theorem of Calculus and simplify completely solve the integral.

$\int_{3}^{6}\frac{dx}{x}$

Answer

To solve the integral, we first have to know that the fundamental theorem of calculus is

$\int_{a}^{b}f(x)dx=F(b)-F(a)$ .

Since denotes the anti-derivative, we have to evaluate the anti-derivative at the two limits of integration, 3 and 6.

To find the anti-derivative, we have to know that in the integral, $\frac{dx}{x}$ is the same as $\frac{1}{x}dx$ .

The anti-derivative of the function $\frac{1}{x}$ is , so we must evaluate .

According to rules of logarithms, when subtracting two logs is the same as taking the log of a fraction of those two values:

$ln\frac{6}{3}$ .

Then, we can simplify to a final answer of

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Question

Solve $\int_{0}^{3}(x^3-6x)dx$ using the Fundamental Theorem of Calculus.

Answer

To solve the integral, we first have to know that the fundamental theorem of calculus is

$\int_{a}^{b}f(x)dx=F(b)-F(a)$ .

Since denotes the anti-derivative, we have to evaluate the anti-derivative at the two limits of integration, 0 and 3.

The anti-derivative of the function is $\frac{1}{4}x^4-3x^2$ , so we must evaluate .

When we plug 3 into the anti-derivative, the solution is $\frac{-27}{4}$ , and when we plug 0 into the anti-derivative, the solution is 0.

To find the final answer, we must take the difference of these two solutions, so the final answer is $\frac{-27}{4}$ .

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Question

Solve $\int_{0}^{2}(2x^3-6x+\frac{3}{x^2+1})$ using the Fundamental Theorem of Calculus.

Answer

To solve the integral, we first have to know that the fundamental theorem of calculus is

$\int_{a}^{b}f(x)dx=F(b)-F(a)$ .

Since denotes the anti-derivative, we have to evaluate the anti-derivative at the two limits of integration, 0 and 2.

The anti-derivative of the function

$2x^3-6x+\frac{3}{x^2+1}$

is

$\frac{1}{2}x^4-3x^2+3tan^{-1}x$ ,

so we must evaluate .

When we plug 3 into the anti-derivative, the solution is $-4+3tan^{-1}(2)$ , and when we plug 0 into the anti-derivative, the solution is 0.

To find the final answer, we must take the difference of these two solutions, so the final answer is $-4+3tan^{-1}(2)$ .

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Question

Use the fundamental theorem of Calculus to evaluate the definite integral

$\int_{\pi/2}^{\pi}(2cos(x)+1)dx$

Answer

Here we use the fundamental theorem of Calculus: $\int_{a}^{b}f(x)dx=F(b)-F(a)$

$F(x)=\int(2cos(x)+1)dx=2sin(x)+x$

Here we do not worry about adding a constant c because we are evaluating a definite integral.

$F(b)=F(\pi)=2sin(\pi)+\pi=0+\pi=\pi$

$F(a)=F(\frac{\pi}{2})=2sin(\frac{\pi}{2})+\frac{\pi}{2}= 2+\frac{\pi}{2}$

$F(b)-F(a)=F(\pi)-F(\frac{\pi}{2})=\pi-(2+\frac{\pi}{2})=\frac{\pi}{2}-2$

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Question

Evaluate $\int_1^x\frac{2}{t^2}dt$ .

Answer

We can integrate this without too much trouble

$\int_1^x\frac{2}{t^2}dt$ . Start

$=\int_1^x2t^{-2}dt$ . Rewrite the power

$=[-2t^{-1}]_1^x$ . Integrate

$=(-2x^{-1})- (-2)$ . Evaluate

$=\frac{2(x-1)}{2}$ . Simplify

Note that we were not asked to evaluate $\frac{d}{dx}\int_1^x\frac{2}{t^2}dt$ , so you should not attempt to use part one of the Fundamental Theorem of Calculus. This would give us the incorrect answer of $\frac{2}{x^2}$ .

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Question

Evaluate the indefinite integral:

$\int_0^{\frac{\pi}{4}} \tan(x)\sec^2(x)dx$

Answer

$\int_0^{\frac{\pi}{4}} \tan(x)\sec^2(x)dx$

First compute the indefinite integral:

$\int \tan(x)\sec^2(x)dx$

Note that the $\sec^2(x)$ is the derivative of $\tan(x)$ . So proceed by defining a new variable:

$u = \tan(x) : : : : :\rightarrow : : : : :du=\sec^2(x)dx$

Now the the integral can be written in terms of

$\int \tan(x)\sec^2(x)dx=\int udu =\frac{1}{2}u^2 +C=\frac{1}{2}\tan^2(x)+C$

Therefore:

$\int \tan(x)\sec^2(x)dx=\frac{1}{2}\tan^2(x)+C$

When we go to compute the indefinite integral the constant of integration will be ignored since it will be subtracted out when we evaluate.

We can precede by either going back to the original variable and evaluate over the original limits of integration, or we can find new limits of integration corresponding to the new variable . Let's look at both equivalent methods:

Solution 1)

$\int_0^{\frac{\pi}{4}}\tan(x)\sec^2(x)dx=\left[ \frac{1}{2}\tan^2(x)\right ]_{x=0}^{x=\frac{\pi}{4}}: : =: : : : \frac{1}{2}\tan^2\left(\frac{\pi}{4}\right) -\frac{1}{2}\tan^2\left(0\right)$

$\tan(0)=0$ so the last term vanishes. The first term reduces to $\frac{1}{2}$ since the tangent function is equal to .

$\int_o^{\frac{\pi}{4}}\tan(x)\sec^2(x)dx=\frac{1}{2}$

Solution 2)

We could have also solved without converting back to the original variable. Instead, we could just change the limits of integration. Use the definition assigned to the variable , which was $u = \tan(x)$ and then use this to find which value takes on when (lower limit) and when $x =\frac{\pi}{4}$ (upper limit).

$x = 0: : : : : : :\rightarrow: : : : :u = \tan(0)=0$

$x=\frac{\pi}{4}: : : : :\rightarrow : : : : :u=tan\left(\frac{\pi}{4}\right )=1$

$\int_0^1 udu =\left[\frac{1}{2}u^2 \right ]_{u=0}^{u=1} =\frac{1}{2}$

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Question

$\frac{d}{dx}\int_{0}^{x^2} sin(t)dt=?$

Answer

Derivatives and anti derivatives annihilate each other. Therefore, the derivative of an anti derivative is simply the function in the integral with the limits substituted in multiplied by the derivative of each limit. Also, be careful that the units will match the outermost units (which comes from the derivative).

$\frac{d}{dx}\int_{0}^{x^2} sin(t)dt= sin(x^2)\frac{d}{dx}(x^{2})-sin(0)\frac{d}{dx}(0)'$

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Question

$\frac{d}{dx}\int_{x}^{x^3}\frac{1}{t^2+1}dt=?$

Answer

This is a Fundamental Theorem of Calculus problem. Since a derivative and anti-derivative cancel each other out, we simply have to plug the limits into our function (with the outside variable). Then, we multiply each by the derivative of the bound:

$\frac{d}{dx}\int_{x}^{x^3}\frac{1}{t^2+1}dt=\frac{1}{{(x^3)}^2+1}\frac{d}{dx}(x^3)-\frac{1}{{(x)}^2+1}\frac{d}{dx}(x)$

$=\frac{3x^2}{x^6+1}-\frac{1}{x^2+1}.$

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Question

$\frac{d}{dx}\int_{0}^{sinx}(1-t^2)dt=?$

Answer

Using the Fundamental Theorem of Calculus, the derivative of an anti-derivative simply gives us the function with the limits plugged in multiplied by the derivative of the respective bounds:

$\frac{d}{dx}\int_{0}^{sinx}(1-t^2)dt=(1-sin^2x)\frac{d}{dx}(sinx)-(1-0^2)\frac{d}{dx}(0)$

In the last step, we made use of the following trigonometric identity:

$sin^2x+cos^2x=1. \rightarrow1-sin^2x=cos^2x.$

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Question

Evaluate the following indefinite integral:

$\int4t^3-6sin(t) dt$

Answer

Evaluate the following indefinite integral:

$\int4t^3-6sin(t) dt$

Recall that we can split subtraction and addition within integrals into separate integrals. This means that we can look at our problem in two steps.

Recall that we can integrate any exponential term by adding 1 to the exponent and dividing by the new exponent.

So,

$\int 4t^3dt=\frac{4t^{3+1}}{4}=t^4+c$

Next, recall that the integral of sine is negative cosine. However, we already have a negative sine, so we should get positive cosine.

$\int -6sin(t)dt=6cos(t)+c$

Now, we can combine our two halves to get our final answer.

Notice that we only have one "c" because c is just a constant, not a variable.

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Question

Evaluate the given definite integral:

$F(x)=\int^5_0 5e^x-5x^4+cos(x)dx$

Answer

Evaluate the given definite integral:

$\int^5_0 5e^x-5x^4+cos(x)dx$

Let's look at this integral as three separate parts, then we'll combine those parts to evaluate the answer.

First, the integral of is just

Second, The integral of any exponential term can be found by increasing the exponent by 1 and then dividing by the new number.

Third, the integral of cosine is simply positive sine.

Put all this together to get:

Now, we need to evaluate our answer by finding the difference between the limits of integration.

$5e^x-x^5+sin(x)+c\mid^5_0$

First, let's see what we get when we plug in 0

Next, let's use 5

Next, find the difference of F(5)-F(0)

So our answer is: -2388.89.

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Question

Evaluate the following definite integral.

$F(x)=\int_0^{\frac{\pi}{2}}5sin(x)+2cos(x)dx$

Answer

Evaluate the following definite integral.

$F(x)=\int_0^{\frac{\pi}{2}}5sin(x)+2cos(x)dx$

Lets begin by recalling that taking an integral is essentially the same as reversing the differentiation process.

So, when we integrate sine, we get negative cosine, and when we integrate cosine, we get sine. The coefficients will stay the same.

$F(x)=\int_0^{\frac{\pi}{2}}5sin(x)+2cos(x)dx=-5cos(x)+2sin(x)+c\mid_0^{\frac{\pi}{2}}$

$F(x)=-5cos(x)+2sin(x)+c\mid_0^{\frac{\pi}{2}}$

Now, we have integrated, but we still need to evaluate our integral. To do so, we need to find the difference between $F(\frac{\pi}{2})$ and .

$F(\frac{\pi}{2})=-5cos(\frac{\pi}{2})+2sin(\frac{\pi}{2})+c=-5(0)+2(1)+c=2+c$

Now, find the difference between our two values:

So, our answer must be 7.

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Question

Evaluate $\int_{0}^{3}(6x^2+1)\mathrm{d}x$

Answer

Here we use the Fundamental Theorem of Calculus

$\int_{a}^{b}f(x)dx=F(b)-F(a)$

and the rule

$\int x^adx=\frac{x^{a+1}}{a+1}$

First we find the anti-derivative using the rule above (no constant is needed because we are dealing with definite integrals)

$F(x)=\frac{6x^3}{3}+x$

Then we use the FTC by plunging in 3 and subtracting from plugging in 0

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Question

$\int_{-1}^{\pi}\pi x^2dx=$

Answer

We will use the Fundamental Theorem of Calculus

$\int_{a}^{b}f(x)dx=F(b)-F(a)$

First we find the anti derivative using the rule, then we apply the FTC

$\int x^a=\frac{x^a+1}{a+1}$

$\int_{-1}^{\pi}\pi x^2dx=\frac{\pi x^3}{3}|_{-1}^{\pi}=\frac{\pi\pi^3}{3}-\frac{-\pi}{3}$

Now we just need to simplify,

$=\frac{\pi^4+\pi}{3}$

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Question

$\int_{1}^{5}(4-(x-3)^2)dx=$

Answer

We will use the Fundamental Theorem of Calculus

$\int_{a}^{b}f(x)dx=F(b)-F(a)$

First we find the anti derivative

$\int_{1}^{5}(4-(x-3)^2)dx=4x-\frac{(x-3)^3}{3}]_1^5$

Then we evaluate it (upper minus lower)

$4x-\frac{(x-3)^3}{3}]_1^5=[4(5)-\frac{(5-3)^3}{3}]-[4(1)-\frac{(1-3^3)}{3}]$

$=[20-\frac{2^3}{3}]-[4-\frac{-2^3}{3}]=(\frac{60}{3}-\frac{8}{3})-(\frac{12}{3}+\frac{8}{3})=\frac{52}{3}-\frac{20}{3}$

$=\frac{32}{3}$

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Question

Find the area of the region given by the following integral.

$\int_{0}^{5}5t^4-3t^2+5e^tdt$

Answer

Find the area of the region given by the following integral.

$\int_{0}^{5}5t^4-3t^2+5e^tdt$

To evaluate this integral, recall the following rules:

$\int t^ndt=\frac{t^{n+1}}{n+1}+c$

$\int e^tdt=e^t +c$

Using these rules, we can find our integral.

$\int_{0}^{5}5t^4-3t^2+5e^tdt=\frac{5t^5}{5}-\frac{3t^3}{3}+5e^t\mid_0^5$

Clean it up a bit to get:

$t^5-t^3+5e^t\mid_0^5\rightarrow ((5)^5-(5)^3+5e^5)-(0^5-0^3+5e^0)$

Alright, clean it up some more to find our final answer:

$((5)^5-(5)^3+5e^5)-(5)=3125-125 +742.06-5=3737.06\approx3737$

So, our area is 3737

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Question

Evaluate the integral $\int_{0}^{\pi/2}\cos(x)-2\sin(2x)dx$

Answer

To evaluate a definite integral, that is to say an integral with an upper bound and lower bound, we will use the 2nd Fundamental Theorem of Calculus, which states,

$\int_a^b f(x)dx = F(b)-F(a)$ , where is the integral of .

We will first integrate just like with any integration.

We will integrate each term individually.

$\int_0^{\pi/2}\cos(x)dx - \int_0^{\pi/2}2\sin(2x)dx$

First, the integral of the cosine is the sine. Doing this, we get

$[\sin(x)]|_0^{\pi/2} - \int_0^{\pi/2}2\sin(2x)dx$

The $|_0^{\pi/2}$ is just notation for "evaluated from to $\pi/2$ ". It is simply a reminder to apply the 2nd Fundamental Theorem of Calculus. The $[\sin(x)]$ is the from the theorem. Before moving to the second integral, we can apply this theorem.

$F(\pi/2)-F(0)$

$\sin(\pi/2)- \sin(0)$

So far, we have the following expression for the entire problem

$1- \int_0^{\pi/2}2\sin(2x)dx$

The basic integral form for the remaining integral is $\int_a^b \sin(u)du =[ -\cos(u)]|_0^{\pi/2}$

Set , since that is what is inside our sine. The derivative of this is

.

This perfectly accounts for the in in front of the sine. Thus we can immediatly replace the entire integral with its basic integral form's result. $1 - \int_0^{\pi/2}2\sin(2x)dx$ $1- [-\cos(2x)]|_0^{\pi/2}$

Now we apply the 2nd Fundamental Theorem of Calculus again.

Plug in $\pi/2$ . Plug in and subtract.

$1- {[-\cos(2\cdot \pi/2)]-[-\cos(2\cdot0)]}$

$1-{[-\cos(\pi)]-[-\cos(0)]}$

This is our answer.

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Question

Evaluate the definite integral, $\int_{-1}^{2}(2x^2-x+5)(2x-2)dx$

Answer

To evaluate this definite integral, we could try to fit it to one of the basic integral forms. The problem is that it doesn't match any of them. When this happens, we have two options: (1) Use algebra to force it to match a basic integral form, or (2) use algebra to break it into multiple terms that we can evaluate separately. In this case, we will use option (2).

The two factors inside the integral can easily be multiplied together to get a polynomial. Doing this results in the following:

Combining like terms, we get

To integrate this polynomial, we integrate each terms separately.

$\int_{-1}^{2}(4x^3 -6x^2 +12x -10) dx$

$\int_{-1}^2 4x^3dx - \int_{-1}^26x^2 dx + \int_{-1}^2 12x dx -\int_{-1}^2 10dx$

To evaluate the first three of these integrals, we will first pull their constant coefficients outside their integral.

$4\int_{-1}^2 x^3dx - 6\int_{-1}^2x^2 dx + 12\int_{-1}^2 x dx -\int_{-1}^2 10dx$

The first three integral now match the power rule for integration. Recall that this rule states $\int_a^b x^n dx = [\frac{1}{n+1}x^{n+1}]|_a^b$ , which effectively says add 1 to the exponent to get the new exponent, and then multiply by the reciprocal of that new exponent. Applying this to the first three integrals gives us

$4[\frac{1}{4}x^4] - 6[\frac{1}{3}x^3] + 12[\frac{1}{2}x^2] - \int_{-1}^210dx$

Simplifying, we get

$x^4 -2x^3 +6x^2 - \int_{-1}^210dx$

We will wait until after integrating the 4th term to write the $|_{-1}^2$ part. We will apply this to all 4 terms at once later.

The fourth integral will follow the constant integration form, $\int_a^b (c)dx = [c\cdot x]|_a^b$ . Simply stated, multiply the constant by and "evaluate from a to b". "Evaluate from a to b" refers to the steps after integrating, using the 2nd Fundamental Theorem of Calculus. We will do this for all 4 terms after we finish integrating the 4th term.

Lets integrate the 4th term.

Now that we have used up all the integral symbols, we will apply the 2nd fundamental Theorem of Calculus, which, simply stated, says plug in the upper bound, then plug in the lower bound. Finally take the upper bound version minus the lower bound version to get the answer.

This is where we write the $|_{-1}^2$ . This notation means that the upper bound is 2 and the lower bound is -1. These numbers are the same numbers as on the integral symbol from the original question, $\int_{-1}^2$ .

$[x^4-2x^3 +6x^2 -10x]|_{-1}^2$

Applying the 2nd Fundamental Theorem of Calculus as described earlier, we get

Now we simplify to get our answer.

This is the correct answer.

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