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Mathematics LibreTexts

3.E: Multiple Integrals (Exercises)

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3.1: Double Integrals

A

For Exercises 1-4, find the volume under the surface z=f(x,y) over the rectangle R.

3.1.1. f(x,y)=4xy,R=[0,1]×[0,1]

3.1.2. f(x,y)=ex+y,R=[0,1]×[1,1]

3.1.3. f(x,y)=x3+y2,R=[0,1]×[0,1]

3.1.4. f(x,y)=x4+xy+y3,R=[1,2]×[0,2]

For Exercises 5-12, evaluate the given double integral.

3.1.5. 1021(1y)x2dxdy

3.1.6. 1020x(x+y)dxdy

3.1.7. 2010(x+2)dxdy

3.1.8. 2111x(xy+sinx)dxdy

3.1.9. π/2010xycos(x2y)dxdy

3.1.10. π0π/20sinxcos(yπ)dxdy

3.1.11. 2041xydxdy

3.1.12. 11211dxdy

3.1.13. Let M be a constant. Show that dcbaMdxdy=M(dc)(ba).

3.2: Double Integrals Over a General Region

A

For Exercises 1-6, evaluate the given double integral.

3.2.1. 101x24x2ydydx

3.2.2. π0y0sinxdxdy

3.2.3. 21lnx04xdydx

3.2.4. 202y0ey2dxdy

3.2.5. π/20y0cosxsinydxdy

3.2.6. 00xye(x2+y2)dxdy

3.2.7. 20y01dxdy

3.2.8. 10x202dydx

3.2.9. Find the volume V of the solid bounded by the three coordinate planes and the plane x+y+z=1.

3.2.10. Find the volume V of the solid bounded by the three coordinate planes and the plane 3x+2y+5z=6.

B

3.2.11. Explain why the double integral gives the area of the region R. For simplicity, you can assume that R is a region of the type shown in Figure 3.2.1(a).

C

3.2.12. Prove that the volume of a tetrahedron with mutually perpendicular adjacent sides of lengths a,\, b, \text{ and }c, as in Figure 3.2.6, is \frac{abc}{ 6}. (Hint: Mimic Example 3.5, and recall from Section 1.5 how three noncollinear points determine a plane.)

alt

Figure 3.2.6

3.2.13. Show how Exercise 12 can be used to solve Exercise 10.

3.3: Triple Integrals

A

For Exercises 1-8, evaluate the given triple integral.

3.3.1. \int_0^3 \int_0^2 \int_0^1 x yz \,dx\, d y\, dz

3.3.2. \int_0^1 \int_0^x \int_0^y x yz \,dz\, d y\, dx

3.3.3. \int_0^π \int_0^x \int_0^{x y} x^ 2 \sin z \,dz\, d y\, dx

3.3.4. \int_0^1 \int_0^z \int_0^y ze^{ y^ 2} \,dx\, d y\, dz

3.3.5. \int_1^e \int_0^y \int_0^{1/y} x^ 2 z \,dx \,dz \,d y

3.3.6. \int_1^2 \int_0^{y^ 2} \int_0^{z^ 2} yz \,dx \,dz \,d y

3.3.7. \int_1^2 \int_2^4 \int_0^3 1\,dx \,d y\, dz

3.3.8. \int_0^1 \int_0^{1−x} \int_0^{1−x−y} 1\,dz\, d y\, dx

3.3.9. Let M be a constant. Show that \int_{z_1}^{z_2} \int_{y_1}^{y_2} \int_{x_1}^{x_2} M\, dx\, d y\, dz = M(z_2 − z_1)(y_2 − y_1)(x_2 − x_1).

B

3.3.10. Find the volume V of the solid S bounded by the three coordinate planes, bounded above by the plane x+ y+ z = 2, and bounded below by the plane z = x+ y.

C

3.3.11. Show that \int_a^b \int_a^z \int_a^y f (x)\,dx \,d y \,dz = \int_a^b \frac{(b−x)^ 2}{ 2} f (x)\,dx. (Hint: Think of how changing the order of integration in the triple integral changes the limits of integration.)

3.4: Numerical Approximation of Multiple Integrals

C

3.4.1. Write a program that uses the Monte Carlo method to approximate the double integral \iint\limits_R e^{ x y}\, d A, where R = [0,1]×[0,1]. Show the program output for N = 10,\, 100,\, 1000,\, 10000,\, 100000 \text{ and }1000000 random points.

3.4.2. Write a program that uses the Monte Carlo method to approximate the triple integral \iiint\limits_S e^{ x yz}\, dV\), where S = [0,1] × [0,1] × [0,1]. Show the program output for N = 10,\, 100,\, 1000,\, 10000,\, 100000 \text{ and }1000000 random points.

3.4.3. Repeat Exercise 1 with the region R = {(x, y) : −1 ≤ x ≤ 1,\, 0 ≤ y ≤ x^ 2 }.

3.4.4. Repeat Exercise 2 with the solid S = {(x, y, z) : 0 ≤ x ≤ 1,\, 0 ≤ y ≤ 1, \,0 ≤ z ≤ 1− x− y}.

3.4.5. Use the Monte Carlo method to approximate the volume of a sphere of radius 1.

3.4.6. Use the Monte Carlo method to approximate the volume of the ellipsoid \frac{x^ 2}{ 9} + \frac{y^ 2}{ 4} + \frac{z^ 2}{ 1} = 1.

3.5: Change of Variables in Multiple Integrals

A

3.5.1. Find the volume V inside the paraboloid z = x^ 2 + y^ 2 \text{ for }0 ≤ z ≤ 4.

3.5.2. Find the volume V inside the cone z = \sqrt{ x^ 2 + y^ 2} for 0 ≤ z ≤ 3.

B

3.5.3. Find the volume V of the solid inside both x^ 2 + y^ 2 + z^ 2 = 4 and x^ 2 + y^ 2 = 1.

3.5.4. Find the volume V inside both the sphere x^ 2 + y^ 2 + z^ 2 = 1 and the cone z = \sqrt{ x^ 2 + y^ 2}.

3.5.5. Prove Equation (3.25).

3.5.6. Prove Equation (3.26).

3.5.7. Evaluate \iiint\limits_R \sin \left ( \frac{x+y}{ 2} \right ) \cos \left ( \frac{x−y}{ 2} \right ) \,d A, where R is the triangle with vertices (0,0),\, (2,0) \text{ and }(1,1). (Hint: Use the change of variables u = (x+ y)/2,\, v = (x− y)/2.)

3.5.8. Find the volume of the solid bounded by z = x^ 2 + y^ 2 \text{ and }z^ 2 = 4(x^ 2 + y^ 2 ).

3.5.9. Find the volume inside the elliptic cylinder \frac{x^ 2}{ a^ 2} + \frac{y^ 2}{ b^ 2} = 1 \text{ for } 0 ≤ z ≤ 2.

C

3.5.10. Show that the volume inside the ellipsoid \frac{x^ 2}{ a^ 2} + \frac{y^ 2}{ b^ 2} + \frac{z^ 2}{ c^ 2} = 1 \text{ is }\frac{4πabc}{ 3}. (Hint: Use the change of variables x = au,\, y = bv,\, z = cw, then consider Example 3.12.)

3.5.11. Show that the Beta function, defined by

B(x, y) = \int_0^1 t^{ x−1} (1− t)^{ y−1} dt ,\text{ for }x > 0,\, y > 0,

satisfies the relation B(y, x) = B(x, y) \text{ for }x > 0,\, y > 0.

3.5.12. Using the substitution t = u/(u +1), show that the Beta function can be written as

B(x, y) = \int_0^∞ \frac{u^{ x−1}}{ (u +1)^{x+y}}\, du ,\text{ for }x > 0,\, y > 0.

3.6: Application: Center of Mass

A

For Exercises 1-5, find the center of mass of the region R with the given density function δ(x, y).

3.6.1. R = {(x, y) : 0 ≤ x ≤ 2,\, 0 ≤ y ≤ 4 },\, δ(x, y) = 2y

3.6.2. R = {(x, y) : 0 ≤ x ≤ 1,\, 0 ≤ y ≤ x 2 },\, δ(x, y) = x+ y

3.6.3. R = {(x, y) : y ≥ 0,\, x^ 2 + y^ 2 ≤ a^ 2 },\, δ(x, y) = 1

3.6.4. R = {(x, y) : y ≥ 0,\, x ≥ 0,\, 1 ≤ x^ 2 + y^ 2 ≤ 4 },\, δ(x, y) = \sqrt{ x^ 2 + y^ 2}

3.6.5. R = {(x, y) : y ≥ 0,\, x^ 2 + y^ 2 ≤ 1 },\, δ(x, y) = y

B

For Exercises 6-10, find the center of mass of the solid S with the given density function δ(x, y, z).

3.6.6. S = {(x, y, z) : 0 ≤ x ≤ 1,\, 0 ≤ y ≤ 1,\, 0 ≤ z ≤ 1 },\, δ(x, y, z) = x yz

3.6.7. S = {(x, y, z) : z ≥ 0,\, x^ 2 + y^ 2 + z^ 2 ≤ a^ 2 },\, δ(x, y, z) = x^ 2 + y^ 2 + z^ 2

3.6.8. S = {(x, y, z) : x ≥ 0,\, y ≥ 0,\, z ≥ 0,\, x^ 2 + y^ 2 + z^ 2 ≤ a^ 2 },\, δ(x, y, z) = 1

3.6.9. S = {(x, y, z) : 0 ≤ x ≤ 1,\, 0 ≤ y ≤ 1,\, 0 ≤ z ≤ 1 },\, δ(x, y, z) = x^ 2 + y^ 2 + z^ 2

3.6.10. S = {(x, y, z) : 0 ≤ x ≤ 1,\, 0 ≤ y ≤ 1,\, 0 ≤ z ≤ 1− x− y},\, δ(x, y, z) = 1

3.7: Application: Probability and Expected Value

B

3.7.1. Evaluate the integral \int_{−\infty}^{\infty} e^{ −x^ 2}\, dx using anything you have learned so far.

3.7.2. For σ > 0 \text{ and }µ > 0, evaluate \int_{\infty}^{−\infty} \frac{1}{ σ \sqrt{ 2π}} e^{ −(x−µ)^ 2 /2σ^ 2} dx.

3.7.3. Show that EY = \frac{n}{ n+1} in Example 3.18

C

3.7.4. Write a computer program (in the language of your choice) that verifies the results in Example 3.18 for the case n = 3 by taking large numbers of samples.

3.7.5. Repeat Exercise 4 for the case when n = 4.

3.7.6. For continuous random variables X, Y \text{ with joint p.d.f. }f (x, y), define the second moments E(X^ 2 ) \text{ and }E(Y^ 2 ) by

E(X^ 2 ) = \int_{-\infty}^{\infty} \int_{-\infty}^{\infty} x^ 2 f (x, y)\,dx\, d y \text{ and }E(Y^ 2 ) = \int_{-\infty}^{\infty} \int_{-\infty}^{\infty} y^ 2 f (x, y)\,dx \,d y ,

and the variances Var(X) and Var(Y) by

\text{Var}(X) = E(X^ 2 )−(EX)^ 2 \text{ and Var}(Y) = E(Y^ 2 )−(EY)^ 2 .

Find Var(X) and Var(Y) for X and Y as in Example 3.18.

3.7.7. Continuing Exercise 6, the correlation ρ \text{ between }X \text{ and }Y is defined as

ρ = \frac{E(XY)−(EX)(EY)}{ \sqrt{ \text{Var}(X)\text{Var}(Y)}} ,

where E(XY) = \int_{-\infty}^{\infty} \int_{-\infty}^{\infty} x y \,f (x, y)\,dx\, d y. Find ρ for X \text{ and }Y as in Example 3.18.
(Note: The quantity E(XY)−(EX)(EY) is called the covariance of X and Y.)

3.7.8. In Example 3.17 would the answer change if the interval (0,100) is used instead of (0,1)? Explain.


3.E: Multiple Integrals (Exercises) is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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