Determine the area of the shaded region in the following figur...

Question

Determine the area of the shaded region in the following figures.

Graph showing a shaded region between two curves, with equations labeled, illustrating area determination.

Accepted Answer

Hi everyone, let's take a look at this practice problem. This problem is to find the area enclosed by the shaded region in the given figure. And below the text we're given a graph that has two functions plotted on it. We have Y is equal to the square root of the quantity of 5 minus X in quantity, and we have Y is equal to the square root of the quantity of X + 3 in quantity. And the shaded region on the graph is bounded above by these two functions and below by the x-axis. We are also given 4 possible choices as our answers. For choice A, we have 17 divided by 6 square units. For choice B, we have 32 divided by 3 square units. For choice C, we have 16 divided by 3 square units. And for choice D, we have 28 divided by 3 square units. So we're asked to find the area enclosed by the shaded region in our figure. So if we look at our shaded region, on the left hand side of the shaded region, our region is bounded above by the function Y is equal to the square root of the quantity of X + 3 in quantity, and on the right hand side, the shaded region is bounded above by the function Y is equal to the square root of the quantity of 5 minus X in quantity. So, we need to find the X value, at which the upper bound of the shaded region changes from one function to the next. And this is going to occur when these two functions intersect. So we need you to just find that x value. And so to find the X value for the intersection points, we just set the two Y values equal to each other. That means we're going to have the square root of the quantity of 5 minus X in quantity, and that's going to be equal to the square root of the quantity of X plus 3 in quantity. So we need to solve this expression for X. So we're going to square both sides of the equation, to begin with, so we'll have 5 minus X is equal to X plus 3. So the next step is to add X to both sides of the equation, as well as subtract 3 from both sides of the equation. In doing so, we'll have that 2 is equal to 2 multiplied by X, and divide both sides of the equation by 2, we'll get that X is equal to 1. And this agrees with what to see in the graph, since it appears that the two functions intersect at the point of 1.2. So now we just need to find the area of our shaded region. So we'll call that area A. And this is going to be equal to the area underneath the Y equal to the square root of the quantity of X + 3 in quantity function on the left hand side of our region. And we can find that area by integrating our function here over that region. So we'll have the integral from -3 to 1 of the square root of the quantity of X plus 3 in quantity DX. Then we'll have to add to this the area underneath the curve for the second for the right half of the region, and that curve is Y is equal to the square root of the quantity of 5 minus X in quantity. And so, again, that area underneath that curvace could be given by an integral, so this could be the integral from 1 to 5 of the square root of the quantity of 5 minus X in quantity DX. So to find the area we need to just evaluate each of these integrals, and we're going to do these independently. So for the first interval, we'll have the intervals from -3 to 1 of the square root of the quantity of X plus 3 in quantity DX. And to evaluate this interval, we're going to use substitution. So we're going to set U equal to. X + 3, and so that means that DU is going to be equal to DX. And so our integral here is going to be equal to the integral, and here, since we've changed variables, we need to change the limits of integration. So for the lower limit of integration, when X is equal to -3, U is going to be equal to -3 + 3, which is going to be 0, and for the upper limit, when X is equal to 1, U is going to be equal to 1 + 3, which is going to be 4. And then we will have you raised to the one half hour. DU. So here we just rewritten the square root of you as you raise to the one half power, because this is going to be easier to integrate in this form. So performing the integration, this is going to be equal to, and recall that when you integrate you to the 1 half power with respect to you, you get you to the 3 half power divided by the quantity of 3 divided by 2 in quantity, and this needs to be evaluated from 0 to 4. So substituting in our limits of integration, this is going to be equal to. We can actually simplify the fraction by bringing the fraction that's in the denominator up to the numerator. So we'll have 2 divided by 3, multiplied by the quantity, and here substituting in our upper limited integration, we'll get 4 raised to the 3 half power. Then we'll have minus for a lower limit of integration, we'll have 0 raised to the 3/al power in quantity. And evaluating this expression, we see that this is going to be equal to. 16 divided by 3. Next, we need to evaluate the other integral. And so that is going to be the integral. From 1 to 5 of the square root of the quantity of 5 minus X and quantity DX. And again, we can evaluate this interval using substitution, so we will set U equal to 5 minus X. That means that DU is going to be equal to minus DX. And so that means our integral here is going to be equal to, and here we'll pull the minus sign out in front of the integral. So we'll have minus, and then we'll have the integral, and here again, we have to change our limits of integration. So when X is equal to 1, U is going to be equal to 5 minus 1, which is 4. And when X is equal to 5, U is going to be equal to 5 minus 5, which is 0, and then again, we'll have you raised to the 12 power multiplied by D U. And again, here we just rewritten the square root of you as you raised to the 1/2 power. So this is the same integration that we had before, so this is going to be equal to. Here we have the minus, and we'll have you raised to the 3 house power divided by the quantity of 3 divided by 2 in quantity, and this needs to be evaluated from 4 to 0. So substituting in our limits of the integration and simplifying the fraction out front, this is going to be equal to minus 2 divided by 3, multiplied by the quantity of 0 raised to the 3 has power, minus 4 raised to the 3 has power in quantity. And evaluating this expression, we see that this is going to be equal to 16 divided by 3. So that means that our area, A is going to be equal to. For the first interval, we had 16 divided by 3, and we'll have plus. For the second interval, we also had 16 divided by 3. And so, when we add these two values together, we see that our area A is going to be equal to 32, divided by 3. Square units. So that is the answer that we are looking for for this problem. And if we were to compare our answer here to our answer choices, we see that the correct answer choice corresponds to answer choice B. So, I hope that this explanation has been useful, and I'll see you in the next video.

Determine the area of the shaded region in the following figures.

Key Concepts

Definite Integral

Area Between Curves

Intersection Points

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