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All Textbook Solutions for Calculus: Early Transcendentals (3rd Edition)

Surface area Let f(x)=x+1. Find the area of the surface generated when the region bounded by the graph of f on the interval [0, 1] is revolved about the x-axis.Surface area Find the area of the surface generated when the region bounded by the graph of y=ex+14ex on the interval [0, ln 2] is revolved about the x-axis.Arc length Find the length of the curve y = x5/4 on the interval [0, 1]. (Hint: Write the arc length integral and let u2=1+(54)2x.)Skydiving A skydiver in free fall subject to gravitational acceleration and air resistance has a velocity given by v(t)=vT(eat1eat+1), where vT is the terminal velocity and a 0 is a physical constant. Find the distance that the skydiver falls after t seconds, which is d(t)=0tv(y)dy.What are the best choices for u and dv in evaluating xcosxdx?Verify by differentiation that lnxdx=xlnxx+C.How many times do you need to integrate by parts to reduce 1e(lnx)6dx to an integral of ln x?On which derivative rule is integration by parts based?Use integration by parts to evaluate xcosxdx with u = x and dv = cos x dx.Use integration by parts to evaluate xlnxdx with u = ln x and dv = x dx.Explain how integration by parts is used to evaluate a definite integral.5E How would you choose dv when evaluating xneaxdx using integration by parts?Integrals involving lnxdx Use a substitution to reduce the following integrals to lnudu. Then evaluate the resulting integral. 53. (sec2x)ln(tanx+2)dx Integrals involving lnxdx Use a substitution to reduce the following integrals to lnudu. Then evaluate the resulting integral. 52. (cosx)ln(sinx)dx Integration by partsEvaluate the following integrals using integration by parts. 9. xcos5xdx Integration by parts Evaluate the following integrals. 8. xsin2xdx Integration by partsEvaluate the following integrals using integration by parts. 11. te6tdt Integration by parts Evaluate the following integrals. 10. 2xe3xdx Integration by partsEvaluate the following integrals using integration by parts. 13. xln10xdx Integration by parts Evaluate the following integrals. 12. se2sds Integration by partsEvaluate the following integrals using integration by parts. 15. (2w+4)cos2wdw Integration by parts Evaluate the following integrals. 14. sec2d Integration by partsEvaluate the following integrals using integration by parts. 17. x3xdx Integration by partsEvaluate the following integrals using integration by parts. 18. x9lnxdx Integration by parts Evaluate the following integrals. 17. lnxx10dx Integration by parts Evaluate the following integrals. 18. sin1xdx Integration by parts Evaluate the following integrals. 21. xsinxcosxdx Integration by partsEvaluate the following integrals using integration by parts. 22. e2xsinexdx Repeated integration by parts Evaluate the following integrals. 29. x2sin2xdx Repeated integration by parts Evaluate the following integrals. 30. x2e4xdx Repeated integration by parts Evaluate the following integrals. 23. t2etdt Integration by partsEvaluate the following integrals using integration by parts. 26. t3sintdt Integration by partsEvaluate the following integrals using integration by parts. 27. excosxdx Repeated integration by parts Evaluate the following integrals. 24. e3xcos2xdx Repeated integration by parts Evaluate the following integrals. 25. exsin4xdx Repeated integration by parts Evaluate the following integrals. 28. e20sin6d Integration by partsEvaluate the following integrals using integration by parts. 31. e3xsinexdx Integration by partsEvaluate the following integrals using integration by parts. 32. 01x22xdx Definite integrals Evaluate the following definite integrals. 31. 0xsinxdx Definite integrals Evaluate the following definite integrals. 32. 1eln2xdx Definite integrals Evaluate the following definite integrals. 33. 0/2xcos2xdx Definite integrals Evaluate the following definite integrals. 34. 0ln2xexdx Definite integrals Evaluate the following definite integrals. 35. 1e2x2lnxdx Repeated integration by parts Evaluate the following integrals. 26. x2ln2xdx Integration by partsEvaluate the following integrals using integration by parts. 39. 01sin1ydy Integration by partsEvaluate the following integrals using integration by parts. 40. exdx Evaluate the integral in part (a) and then use this result to evaluate the integral in part (b). a. tan1xdx b. xtan1x2dx Volumes of solidsFind the volume of the solid that is generated when the given region is revolved as described. 42. The region bounded by f(x) = ln x, y = 1, and the coordinate axes is revolved about the x-axis.Volumes of solids Find the volume of the solid that is generated when the given region is revolved as described. 39. The region bounded by f(x) = ex, x = ln 2, and the coordinate axes is revolved about the y-axis.Volumes of solids Find the volume of the solid that is generated when the given region is revolved as described. 40. The region bounded by f(x) = sin x and the x-axis on [0, ] is revolved about the y-axis.Volumes of solidsFind the volume of the solid that is generated when the given region is revolved as described. 45. The region bounded by g(x)=lnx and the x-axis on [1, e] is revolved about the x-axis.Volumes of solids Find the volume of the solid that is generated when the given region is revolved as described. 42. The region bounded by f(x) = ex and the x-axis on [0, ln 2] is revolved about the line x = ln 2.Volumes of solids Find the volume of the solid that is generated when the given region is revolved as described. 41. The region bounded by f(x) = x ln x and the x-axis on [1, e2] is revolved about the x-axis.Integral of sec3 x Use integration by parts to show that sec3xdx=12secxtanx+12secxdx.Reduction formulas Use integration by parts to derive the following reduction formulas. 44. xneaxdx=xneaxanaxn1eaxdx, for a 0 Reduction formulas Use integration by parts to derive the following reduction formulas. 45. xncosaxdx=xnsinaxanaxn1sinaxdx, for a 0 Reduction formulas Use integration by parts to derive the following reduction formulas. 46. xnsinaxdx=xncosaxa+naxn1cosaxdx, for a 0 Reduction formulas Use integration by parts to derive the following reduction formulas. 47. lnnxdx=xlnnxnlnn1xdx Applying reduction formulas Use the reduction formulas in Exercises 50-53 to evaluate the following integrals. 54. x2e3xdx Applying reduction formulas Use the reduction formulas in Exercises 50-53 to evaluate the following integrals. 55. x2cos5xdx Applying reduction formulas Use the reduction formulas in Exercises 50-53 to evaluate the following integrals. 56. x3sinxdx Applying reduction formulas Use the reduction formulas in Exercises 50-53 to evaluate the following integrals. 57. 1eln3xdx Two methods Evaluate 0/3sinxln(cosx)dx in the following two ways. a. Use integration by parts. b. Use substitution.Two methods a. Evaluate xx+1dx using integration by parts. b. Evaluate xx+1dx using substitution. c. Verify that your answers to part (a) and (b) are consistent.Two methods a. Evaluate xlnx2dx using the substitution u = x2 and evaluating lnudu. b. Evaluate xlnx2dx using integration by parts. c. Verify that your answers to parts (a) and (b) are consistent.Logarithm base b Prove that logbxdx=1lnb(xlnxx)+C.Two integration methods Evaluate sinxcosxdx using integration by parts. Then evaluate the integral using a substitution. Reconcile your answers.Combining two integration methods Evaluate cosxdx using a substitution followed by integration by parts.64E An identity Show that if f has a continuous second derivative on [a, b] and f(a) = f(b) = 0, then abxf(x)dx=f(a)f(b).Integrating derivatives Use integration by parts to show that if f is continuous on [a, b], then abf(x)f(x)dx=12(f(b)2f(a)2).Function defined as an integral Find the arc length of the function f(x)=exln2t1dt on [e, e3].Log integrals Use integration by parts to show that for m 1, xmlnxdx=xm+1m+1(lnx1m+1)+C and for m = 1, lnxxdx=12ln2x+C.Comparing volumes Let R be the region bounded by y = sin x and the x-axis on the interval [0, ]. Which is greater, the volume of the solid generated when R is revolved about the x-axis or the volume of the solid generated when R is revolved about the y-axis?A useful integral a. Use integration by parts to show that if f is continuous, xf(x)dx=xf(x)f(x)dx. b. Use part (a) to evaluate xe3xdx.Solid of revolution Find the volume of the solid generated when the region bounded by y = cos x and the x-axis on the interval [0, /2] is revolved about the y-axis.72E Two useful exponential integrals Use integration by parts to derive the following formulas for real numbers a and b. eaxsinbxdx=eax(asinbxbcosbx)a2+b2+Ceaxcosbxdx=eax(acosbx+bsinbx)a2+b2+C Integrating inverse functions Assume that f has an inverse on its domain. a. Let y = f1(x) and show that f1(x)dx=yf(y)dy. b. Use part (a) to show that f1(x)dx=yf(y)f(y)dy. c. Use the result of part (b) to evaluate lnxdx (express the result in terms of x). d. Use the result of part (b) to evaluate sin1xdx. e. Use the result of part (b) to evaluate tan1xdx.75E Find the error Suppose you evaluate dxx using integration by parts. With u = 1/x and dv = dx, you find that du = 1/x2 dx, v = x, and dxx=(1x)xx(1x2)dx=1+dxx. You conclude that = 1. Explain the problem with the calculation.77E Practice with tabular integration Evaluate the following integrals using tabular integration (refer to Exercise 77). a. x4exdx b. 7xe3xdx c. 102x2x+1dx d. (x32x)sin2xdx e. 2x23x(x1)3 f. x2+3x+432x+1dx g. Why doesnt tabular integration work well when applied to x1x2dx? Evaluate this integral using a different method. Tabular integration Consider the integral f(x)g(x)dx, where f can be differentiated repeatedly and g can be integrated repeatedly. Let Gk represent the result of calculating k Indefinite integrals of g, where the constants of integration are omitted. a. Show that integration by parts, when applied to f(x)g(x)dx with the choices u = f(x) and dv = g(x) dx, leads to f(x)g(x)dx = f(x)G1(x) f(x)G1(x)dx. This formula can be remembered by utilizing the following table, where a right arrow represents a product of functions on the right side of the integration by pats formula and a left arrow represents the integral of a product of functions (also appearing on the right side of the formula). Explain the significance of the signs associated with the arrows. b. Perform integration by parts again on f(x)G1(x)dx (from part (a)) with the choices u = f(x) and dv = G1(x) dx to Show that f(x)g(x)dx= f(x)G1(x) f (x)G2(x) + f(x)G2(x)dx. Explain the connection between this integral formula and the following table, paying close attention to the signs attached to the arrows. c. Continue the pattern established in parts (a) and (b) and integrate by parts a third time. Write the integral formula that results from three applications of integration by parts, and construct the associated tabular integration table (include signs of the arrows) d. The tabular integration table from part (c) is easily extended to allow for as many steps as necessary in the process of integration by parts. Evaluate x2ex/2dx by constructing an appropriate table, and explain why the process terminates after four rows of the table have been filled in e. Use tabular integration to evaluate x3cosxdx. How many rows of the table are necessary? Why? f. Explain why tabular integration is particularly suited to integrals of the form pn(x)g(x)dx, where pn is a polynomial of degree n 0 (and where, as before, we assume g is easily integrated as many times as necessary)Tabular integration extended Refer to Exercise 77. a. The following table shows the method of tabular integration applied to excosxdx. Use the table to express excosxdxin terms of the sum of functions and an indefinite integral. b. Solve the equation in part (a) for excosxdx. c. Evaluate e2xsin3xdx by applying the idea from parts (a) and (b). Tabular integration Consider the integral f(x)g(x)dx, where f can be differentiated repeatedly and g can be integrated repeatedly. Let Gk represent the result of calculating k Indefinite integrals of g, where the constants of integration are omitted. a. Show that integration by parts, when applied to f(x)g(x)dx with the choices u = f(x) and dv = g(x) dx, leads to f(x)g(x)dx = f(x)G1(x) f(x)G1(x)dx. This formula can be remembered by utilizing the following table, where a right arrow represents a product of functions on the right side of the integration by pats formula and a left arrow represents the integral of a product of functions (also appearing on the right side of the formula). Explain the significance of the signs associated with the arrows. b. Perform integration by parts again on f(x)G1(x)dx (from part (a)) with the choices u = f(x) and dv = G1(x) dx to Show that f(x)g(x)dx= f(x)G1(x) f(x)G2(x) + f(x)G2(x)dx. Explain the connection between this integral formula and the following table, paying close attention to the signs attached to the arrows. c. Continue the pattern established in parts (a) and (b) and integrate by parts a third time. Write the integral formula that results from three applications of integration by parts, and construct the associated tabular integration table (include signs of the arrows) d. The tabular integration table from part (c) is easily extended to allow for as many steps as necessary in the process of integration by parts. Evaluate x2ex/2dx by constructing an appropriate table, and explain why the process terminates after four rows of the table have been filled in e. Use tabular integration to evaluate x3cosxdx. How many rows of the table are necessary? Why? f. Explain why tabular integration is particularly suited to integrals of the form pn(x)g(x)dx, where pn is a polynomial of degree n 0 (and where, as before, we assume g is easily integrated as many times as necessary)An identity Show that if f and g have continuous second derivatives and f(0) = f(1) = g(0) = g(1) = 0, then 01f(x)g(x)dx=01f(x)g(x)dx.Possible and impossible integrals Let In=xnex2dx, where n is a nonnegative integer. a. I0=ex2dx cannot be expressed in terms of elementary functions. Evaluate I1. b. Use integration by parts to evaluate I3. c. Use integration by parts and the result of part (b) to evaluate I5. d. Show that, in general, if n is odd, then In=12ex2pn1(x), where pn1 is a polynomial of degree n 1. e. Argue that if n is even, then In cannot be expressed in terms of elementary functions.A family of exponentials The curves y = xeax are shown in the figure for a = 1, 2, and 3. a. Find the area of the region bounded by y = xex and the x-axis on the interval [0, 4]. b. Find the area of the region bounded by y = xeax and the x-axis on the interval [0, 4], where a 0. c. Find the area of the region bounded by y = xeax and the x-axis on the interval [0, b]. Because this area depends on a and b, we call it A(a, b), where a 0 and b 0. d. Use part (c) to show that A(l, ln b) = 4A(2, (ln b)/2). e. Does this pattern continue? Is it true that A(1, ln b) = a2A(a, (ln b)/a)?Evaluate sin3xdxby splitting off a factor of sin x rewriting sin2x in terms of cos x and using an appropriate u-substitution.What strategy would you use to evaluate sin3xcos3xdx?State the half-angle identities used to integrate sin2 x and cos2 x.State the three Pythagorean identities.Describe the method used to integrate sin3 x.Describe the method used to integrate sinm x cosn x, for m even and n odd.What is a reduction formula?How would you evaluate cos2xsin3xdx?How would you evaluate tan10xsec2xdx?How would you evaluate sec12xtanxdx?Integrals of sin x or cos x Evaluate the following integrals. 11. cos3xdx Integrals of sin x or cos x Evaluate the following integrals. 10. sin3xdx Trigonometric integralsEvaluate the following integrals. 11. sin2x3xdx Integrals of sin x or cos x Evaluate the following integrals. 12. cos42d Integrals of sin x or cos x Evaluate the following integrals. 13. sin5xdx Integrals of sin x or cos x Evaluate the following integrals. 14. cos320xdx Integrals of sin x and cos x Evaluate the following integrals. 17. sin3xcos2xdx Integrals of sin x and cos x Evaluate the following integrals. 18. sin2cos5d Integrals of sin x and cos x Evaluate the following integrals. 19. cos3xsinxdx Integrals of sin x and cos x Evaluate the following integrals. 20. sin3cos2d Trigonometric integrals Evaluate the following integrals. 19. 0/3sin5xcos-2xdx Integrals of sin x and cos x Evaluate the following integrals. 22. sin3/2xcos3xdx Trigonometric integrals Evaluate the following integrals. 21. 0/2cos3xsin3xdx 22E Integrals of sin x and cos x Evaluate the following integrals. 15. sin2xcos2xdx Integrals of sin x and cos x Evaluate the following integrals. 16. sin3xcos5xdx Integrals of sin x and cos x Evaluate the following integrals. 23. sin2xcos4xdx Integrals of sin x and cos x Evaluate the following integrals. 24. sin3xcos3/2xdx Integrals of tan x or cot x Evaluate the following integrals. 25. tan2xdx Integrals of tan x or cot x Evaluate the following integrals. 26. 6sec4xdx Integrals of tan x or cot x Evaluate the following integrals. 27. cot4xdx Integrals of tan x or cot x Evaluate the following integrals. 28. tan3d Integrals of tan x or cot x Evaluate the following integrals. 29. 20tan6xdx Integrals of tan x or cot x Evaluate the following integrals. 30. cot53xdx Integrals involving tan x and sec x Evaluate the following integrals. 31. 10tan9xsec2xdx Integrals involving tan x and sec x Evaluate the following integrals. 32. tan9xsec4xdx Integrals involving tan x and sec x Evaluate the following integrals. 33. tanxsec3xdx Trigonometric integrals Evaluate the following integrals. 36. tan4xsec3/24xdx Additional integrals Evaluate the following integrals. 51. sec4(ln)d Integrals involving tan x and sec x Evaluate the following integrals. 42. tan5sec4d Additional integrals Evaluate the following integrals. 53. /3/3sec21d Trigonometric integrals Evaluate the following integrals. 40. 0/6tan52xsec2xdx Trigonometric integrals Evaluate the following integrals. 41. 0/4sec7xsecxdx Integrals involving tan x and sec x Evaluate the following integrals. 34. tanxsec4xdx Integrals involving tan x and sec x Evaluate the following integrals. 35. tan34xdx Integrals involving tan x and sec x Evaluate the following integrals. 36. sec2xtan5xdx Integrals involving tan x and sec x Evaluate the following integrals. 37. sec2xtan1/2xdx Integrals involving tan x and sec x Evaluate the following integrals. 38. sec2xtan3xdx Integrals involving tan x and sec x Evaluate the following integrals. 39. csc4xcot2xdx Integrals involving tan x and sec x Evaluate the following integrals. 40. csc10xcotxdx Trigonometric integrals Evaluate the following integrals. 49. /20/10csc25wcot45wdw Trigonometric integrals Evaluate the following integrals. 50. csc10xcot3xdx Trigonometric integrals Evaluate the following integrals. 51. (csc2x+csc4x)dx Trigonometric integrals Evaluate the following integrals. 52. 0/8(tan2x+tan32x)dx Integrals involving tan x and sec x Evaluate the following integrals. 41. 0/4sec4d Additional integrals Evaluate the following integrals. 50. 0/2xsin3(x2)dx Integrals involving tan x and sec x Evaluate the following integrals. 43. /6/3cot3d Integrals involving tan x and sec x Evaluate the following integrals. 44. 0/4tan3sec2d Additional integrals Evaluate the following integrals. 55. 0(1cos2x)3/2dx 58E Square roots Evaluate the following integrals. 59. 0/21cos2xdx Square roots Evaluate the following integrals. 60. 0/81cos8xdx Square roots Evaluate the following integrals. 61. 0/4(1+cos4x)3/2dx Arc length Find the length of the curve y = ln (sec x), for 0 x /4.Explain why or why not Determine whether the following statements are true and give an explanation or counterexample. a. If m is a positive integer, then 0cos2m+1xdx=0. b. If m is a positive integer, then 0sinmxdx=0.Sine football Find the volume of the solid generated when the region bounded by the graph of y = sin x and the x-axis on the interval [0, ] is revolved about the x-axis.VolumeFind the volume of the solid generated when the region bounded by y = sin2 x cos 3/2 x and the x-axis on the interval [0, /2] is revolved about the x-axis.66E Integrals of the form sinmxcosnxdx Use the following three identities to evaluate the given integrals. sinmxsinnx=12(cos((mn)x)cos((m+n)x))sinmxcosnx=12(sin((mn)x)+sin((m+n)x))cosmxcosnx=12(cos((mn)x)+cos((m+n)x)) 67. sin3xcos7xdx Integrals of the form sinmxcosnxdx Use the following three identities to evaluate the given integrals. sinmxsinnx=12(cos((mn)x)cos((m+n)x))sinmxcosnx=12(sin((mn)x)+sin((m+n)x))cosmxcosnx=12(cos((mn)x)+cos((m+n)x)) 68. sin5xsin7xdx Integrals of the form sinmxcosnxdx Use the following three identities to evaluate the given integrals. sinmxsinnx=12(cos((mn)x)cos((m+n)x))sinmxcosnx=12(sin((mn)x)+sin((m+n)x))cosmxcosnx=12(cos((mn)x)+cos((m+n)x)) 69. sin3xsin2xdx Integrals of the form sinmxcosnxdx Use the following three identities to evaluate the given integrals. sinmxsinnx=12(cos((mn)x)cos((m+n)x))sinmxcosnx=12(sin((mn)x)+sin((m+n)x))cosmxcosnx=12(cos((mn)x)+cos((m+n)x)) 70. cosxcos2xdx Integrals of the form sinmxcosnxdx Use the following three identities to evaluate the given integrals. sinmxsinnx=12(cos((mn)x)cos((m+n)x))sinmxcosnx=12(sin((mn)x)+sin((m+n)x))cosmxcosnx=12(cos((mn)x)+cos((m+n)x)) 71. Prove the following orthogonality relations (which are used to generate Fourier series). Assume m and n are integers with m n. a. 0sinmxsinnxdx=0 b. 0cosmxcosnxdx=0 c. 0sinmxcosnxdx=0, for |m + n| even 72E A tangent reduction formula Prove that for positive integers n 1, tannxdx=tann1xn1tann2xdx. Use the formula to evaluate 0/4tan3xdx.A secant reduction formula Prove that for positive integers n 1, secnxdx=secn2xtanxn1+n2n1secn2xdx. (Hint: Integrate by parts with u = secn 2 x and dv = sec2 x dx.)75E Use a substitution of the form x = a sin to transform 9 x2 into a product.2QC The integral dxa2+x21atan1xa+C is given in Section 5.5. Verify this result with the appropriate trigonometric substitution.What change of variables is suggested by an integral containing x29?What change of variables is suggested by an integral containing x2+36?What change of variables is suggested by an integral containing 100x2?If x = 4 tan , express sin in terms of x.If x = 2 sin , express cot in terms of x.If x = 8 sec , express tan in terms of x.Sine substitution Evaluate the following integrals. 7. 05/2dx25x2 Sine substitution Evaluate the following integrals. 8. 03/2dx(9x2)3/2 Sine substitution Evaluate the following integrals. 9. 510100x2dx Sine substitution Evaluate the following integrals. 10. 02x24x2dx Sine substitution Evaluate the following integrals. 11. 01/2x21x2dx Sine substitution Evaluate the following integrals. 12. 1/211x2x2dx Sine substitution Evaluate the following integrals. 13. dx(16x2)1/2 Sine substitution Evaluate the following integrals. 14. 36t2dt Trigonometric substitutions Evaluate the following integrals. 21. dxx2x2+9 Trigonometric substitutions Evaluate the following integrals. 39. x2(25+x2)2dx Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 17. 02x2x2+4dx Trigonometric substitutions Evaluate the following integrals. 20. dx(1+x2)3/2 Trigonometric substitutions Evaluate the following integrals. 25. dxx281,x9 Trigonometric substitutions Evaluate the following integrals. 18. dxx249,x7 Trigonometric substitutions Evaluate the following integrals. 17. 64x2dx Trigonometric substitutions Evaluate the following integrals. 22. dtt29t2 Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 23. dx(25x2)3/2 Trigonometric substitutions Evaluate the following integrals. 38. 9x2x2dx Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 25. 9x2xdx Evaluating definite integrals Evaluate the following definite integrals. 52. 22x21xdx Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 27. 01/3dx(9x2+1)3/2 Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 28. 06z2(z2+36)2dz Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 29. dx(4+x2)2 Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 30. x31x2dx Trigonometric substitutions Evaluate the following integrals. 29. x216x2dx Trigonometric substitutions Evaluate the following integrals. 28. dx(x236)3/2,x6 Trigonometric substitutions Evaluate the following integrals. 31. x29xdx,x3 Trigonometric substitutions Evaluate the following integrals. 44. dxx3x21,x1 Trigonometric substitutions Evaluate the following integrals. 45. dxx(x21)3/2,x1 Evaluating definite integrals Evaluate the following definite integrals. 48. 8216dxx264 Evaluating definite integrals Evaluate the following definite integrals. 49. 1/31dxx21x2 Evaluating definite integrals Evaluate the following definite integrals. 50. 12dxx24x2 Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 39. x2(100x2)3/2dx Evaluating definite integrals Evaluate the following definite integrals. 54. 10/310dyy225 Trigonometric substitutions Evaluate the following integrals. 27. dx(1+4x2)3/2 Trigonometric substitutions Evaluate the following integrals. 40. dxx29x21,x13 Trigonometric substitutions Evaluate the following integrals using trigonometric substitution. 43. 04/3dxx2+16 Trigonometric substitutions Evaluate the following integrals. 24. dx16+4x2 Trigonometric substitutions Evaluate the following integrals. 43. x3(81x2)2dx 46E Evaluating definite integrals Evaluate the following definite integrals. 55. 4/34dxx2(x24)Trigonometric substitutions Evaluate the following integrals. 32. 94x2dx Evaluating definite integrals Evaluate the following definite integrals. 51. 01/3x2+1dx Sine substitution Evaluate the following integrals. 16. (369x2)3/2dx Trigonometric substitutions Evaluate the following integrals. 33. x24+x2dx 52E Trigonometric substitutions Evaluate the following integrals. 37. 9x225x3dx,x53 54E Trigonometric substitutions Evaluate the following integrals. 42. dxx3x2100,x10 56E Explain why or why not Determine whether the following statements are true and give an explanation or counterexample. a. If x = 4 tan , then csc = 4/x. b. The integral 121x2dx does not have a finite real value. c. The integral 12x21dx does not have a finite real value. d. The integral dxx2+4x+9 cannot be evaluated using trigonometric substitution.Area of an ellipse The upper half of the ellipse centered at the origin with axes of length 2a and 2b is described by y=baa2x2 (see figure). Find the area of the ellipse in terms of a and b.Area of a segment of a circle Use two approaches to show that the area of a cap (or segment) of a circle of radius r subtended by an angle (see figure) is given by Aseg=12r2(sin). a. Find the area using geometry (no calculus). b. Find the area using calculus.Completing the square Evaluate the following integrals. 58. dxx26x+34 Completing the squareEvaluate the following integrals. 61. dx32xx2 Completing the square Evaluate the following integrals. 60. du2u212u+36 Completing the square Evaluate the following integrals. 59. dxx2+6x+18 Completing the square Evaluate the following integrals. 61. x22x+1x22x+10dx Completing the square Evaluate the following integrals. 65. 1/2(2+3)/(22)dx8x28x+11 Completing the square Evaluate the following integrals. 64. 14dtt22t+10 Completing the square Evaluate the following integrals. 63. x28x+16(9+8xx2)3/2dx Asymmetric integrands Evaluate the following integrals. Consider completing the square. 76. dx(x1)(3x)Asymmetric integrands Evaluate the following integrals. Consider completing the square. 77. 2+24dx(x1)(x3)Using the integral of sec3 u By reduction formula 4 in Section 7.3, sec3udu=12(secutanu+lnsecu+tanu)+C. Graph the following functions and find the area under the curve on the given interval. 74. f(x) = (4 + x2)1/2, [0, 2]Using the integral of sec3 u By reduction formula 4 in Section 7.3, sec3udu=12(secutanu+lnsecu+tanu)+C. Graph the following functions and find the area under the curve on the given interval. 73. f(x)=(9x2)2,[0,32]72E 73E Using the integral of sec3 uBy reduction formula 4 in Section 8.3, sec3udu=12(secutanu+ln|secu+tanu|)+C. Graph the following functions and find the area under the curve on the given interval. 74. f(x)=1xx236, [123,12]75E Area and volume Consider the function f(x) = (9 + x2)1/2 and the region R on the interval [0, 4] (see figure). a. Find the area of R. b. Find the volume of the solid generated when R is revolved about the x-axis. c. Find the volume of the solid generated when R is revolved about the y-axis.Arc length of a parabola Find the length of the curve y = ax2 from x = 0 to x = 10, where a 0 is a real number.78E Show that dxxx21={sec1x+C=tan1x21+Cifx1sec1x+C=tan1x21+Cifx1.Evaluate for x21x3dx, for x 1 and for x 1.81E Magnetic field due to current in a straight wire A long, straight wire of length 2L on the y-axis carries a current L. According to the Biot-Savart Law, the magnitude of the magnetic field due to the current at a point (a, 0) is given by B(a)=0IrLLsinr2dy, where 0 is a physical constant, a 0, and , r, and y are related as shown in the figure. a. Show that the magnitude of the magnetic field at (a, 0) is B(a)=0IL2aa2+L2. b. What is the magnitude of the magnetic field at (a, 0) due to an infinitely long wire (L )?83E 85E 86E Find an antiderivative of f(x)=1x2+2x+4.If the denominator of a reduced proper rational function is (x 1) (x + 5)(x 10), what is the general form of its partial fraction decomposition?3QC 4QC What kinds of functions can be integrated using partial fraction decomposition?Give an example of each of the following. a. A simple linear factor b. A repeated linear factor c. A simple irreducible quadratic factor d. A repeated irreducible quadratic factor What term(s) should appear in the partial fraction decomposition of a proper rational function with each of the following? a. A factor of x 3 in the denominator b. A factor of (x 4)3 in the denominator c. A factor of x2 + 2x + 6 in the denominator 4E Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 5. 4xx29x+20 Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 6. 4x+14x21 Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 7. x+3(x5)2 Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 8. 2x32x2+x Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 9. 4x55x3+4x Setting up partial fraction decompositions Give the appropriate form of the partial fraction decomposition for the folio wing functions. 39. 20x(x1)2(x21)Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 11. 1x(x2+1)Setting up partial fraction decompositions Give the appropriate form of the partial fraction decomposition for the folio wing functions. 41. 2x2+3(x28x+16)(x2+3x+4)Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 13. x4+12x2(x2)2(x2+x+2)2 14E Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 15. x(x416)2 Set up the appropriate form of the partial fraction decomposition for the following expressions. Do not find the values of the unknown constants. 16. x2+2x+6x3(x2+x+1)2 Setting up partial fraction decomposition Give the partial fraction decomposition for the following functions. 7. 5x7x23x+2 Setting up partial fraction decomposition Give the partial fraction decomposition for the following functions. 8. 11x10x2x Give the partial fraction decomposition for the following expressions. 19. 6x22x8 Setting up partial fraction decomposition Give the partial fraction decomposition for the following functions. 12. x24x+11(x3)(x1)(x+1)Give the partial fraction decomposition for the following expressions. 21. 2x2+5x+6x2+3x+2 (Hint: Use long division first.)Give the partial fraction decomposition for the following expressions. 22. x4+2x3+xx21 IntegrationEvaluate the following integrals. 23.3(x1)(x+2)dx IntegrationEvaluate the following integrals. 24. 8(x2)(x+6)dx IntegrationEvaluate the following integrals. 25. 6x21dx Simple linear factors Evaluate the following integrals. 16. 01dtt29 IntegrationEvaluate the following integrals. 27. 8x53x25x+2dx IntegrationEvaluate the following integrals. 28. 127x23x22xdx IntegrationEvaluate the following integrals. 29. 125xx2x6dx IntegrationEvaluate the following integrals. 30. 21x2x3x212xdx Integration Evaluate the following integrals. 31. 6x2x45x2+4dx Integration Evaluate the following integrals. 32. 4x2x3xdx Integration Evaluate the following integrals. 33. 3x2+4x6x23x+2dx Integration Evaluate the following integrals. 34. 2z3+z26z+7z2+z6dz Simple linear factors Evaluate the following integrals. 23. x2+12x4x34xdx 36E Simple linear factors Evaluate the following integrals. 25. dxx410x2+9 Simple linear factors Evaluate the following integrals. 26. 052x24x32dx Repeated linear factors Evaluate the following integrals. 27. 81x39x2dx Repeated linear factors Evaluate the following integrals. 28. 16x2(x6)(x+2)2dx Repeated linear factors Evaluate the following integrals. 29. 11x(x+3)2dx Repeated linear factors Evaluate the following integrals. 30. dxx32x24x+8 Repeated linear factors Evaluate the following integrals. 31. 2x3+x2dx

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