Calculus I–Sample Final exam
Transcription
Calculus I–Sample Final exam
Calculus I–Sample Final exam Solutions [1] Compute the following integrals: Z 4 dx (a) 2 2 x ln (x) Solution. Substituting u = ln x, ln 4 Z 4 Z ln 4 dx 1 1 −2 −1 − . = u du = −u = 2 ln 2 ln 4 2 x ln (x) ln 2 ln 2 Taking common denominator, using properties of the logarithm, one can get the answer in the more compact form Z 4 1 dx = . 2 2 ln 2 2 x ln (x) Z 2 (b) sin(2θ)esin (θ) dθ Solution. Z (c) Substituting u = sin2 θ, du = 2 sin θ cos θ dθ = sin(2θ) dθ, Z Z 2 sin2 (θ) sin(2θ)e dθ = eu du = eu + C = esin θ + C. dx √ x2 + 1 Solution. Substituting x = tan θ, x2 + 1 = sec2 θ, dx = sec2 θ dθ, Z Z Z dx sec2 θ cos θ 1 x √ = dθ = dθ = − +C = √ + C. 2 2 tan θ sec θ sin θ sin θ x2 x2 + 1 x2 + 1 x2 Z (d) π x2 sin x dx 0 Solution. Integrating by parts, π Z π Z π Z π 2 2 2 x sin x dx = − x cos x + 2 x cos x dx = π + 2 x cos x dx 0 0 0 0 π Z π Z π 2 2 = π + 2 x sin x − sin x dx = π − 2 sin x dx 0 0 0 π 2 = π + 2 cos x = π 2 − 4. 0 2 Z (e) t2 + 8 dt t2 − 5t + 6 Solution. Since the numerator has degree equal to that of the denominator, we have to divide to get t2 + 8 5t + 2 =1+ 2 . 2 t − 5t + 6 t − 5t + 6 5t + 2 Next we decompose 2 into partial fractions: t − 5t + 6 t2 5t + 2 5t + 2 A B = = + . − 5t + 6 (t − 2)(t − 3) t−2 t−3 Using Heaviside’s method we see at once that A = −12, B = 17 so that, all in all, t2 + 8 17 12 =1+ − . 2 t − 5t + 6 t−3 t−2 Thus Z t2 + 8 dt = t2 − 5t + 6 Z (f ) Z 17 12 1+ − dt = t + 17 ln |t − 3| − 12 ln |t − 2| + C. t−3 t−2 1/2 2x + 2 dx x2 − 2x + 1 0 Solution. By partial Fractions x2 2x + 2 A B A(x − 1) + B 2x + 2 = = + = . 2 2 − 2x + 1 (x − 1) x − 1 (x − 1) (x − 1)2 Equating the numerators of the expression at the extreme right with that at the extreme left we get Ax + (B − A) = 2x + 2, thus A = 2, B − A = 2, thus B = 4. Now Z 1/2 Z 1/2 2x + 2 2 4 dx = + dx x2 − 2x + 1 x − 1 (x − 1)2 0 0 1/2 4 = 4 + 2 ln 1 . = 2 ln |x − 1| − x−1 2 0 [2] Find the volume of the solid generated by revolving the region bounded by the following curves about the x-axis. Draw a picture of the region to be revolved. √ {y = 2 x}, {y = 2}, {x = 0} Solution. The region in question is 3 By slicing–washers. Z V =π 1 √ (22 − (2 x)2 ) dx = π ∈10 (4 − 4x) dx = 2π. . 0 By the shell method. Here we describe the region in terms of y; it is the region between the y − axis and the curve x = y 2 /4 for 0 ≤ y ≤ 2. Z Z 2 2 y π 2 3 y dy = 2π. V = 2π y dy = 4 2 0 0 [3] Find the center of mass of a thin plate of constant density δ covering the region delimited by {y = x2 }, {y = 2}. Solution. The region in red is the region covered by the plate: 4 By symmetry, x¯ = 0. Now (assume, as one may, that δ = 1) √ 1 Mx = 2 Z M = Z 2 1 (22 − (x2 )2 ) dx = √ 2 − 2 √ √ 2 8 2 (2 − x2 ) dx = . √ 3 − 2 √ 2 16 , (4 − x4 ) dx = √ 5 − 2 Z √ 2 6 Thus y¯ = Mx /M = 6/5. The center of mass is at 0, . 5 [4] It took 1800 J of work to stretch a spring from its natural length of 2 m to a length of 5m. Find the spring force constant Solution. Z 3 9k 1800 = W = k x dx = . 2 0 Solving for k, k = 400. [5] A tank in the shape of a circular cone with its vertex at the bottom, base at the top, is filled with a liquid that happens to weigh 1 Newton/cubic meter. The tank is 12 meters high, the radius of the base of the cone is 4 meters. Determine the works it takes to empty the tank if the liquid needs to be pumped to a height 2 meters above the top of the tank. Suggestion: Use the axis of the cone as the y-axis, with the origin at the base of the cone. The top of the tank is then at y = 12 and the water needs to be raised to y = 14. Solution. Consider a “slab” of liquid at level y of thickness dy. By similar triangles this is an infinitesimal cylinder of radius y/3, height dy, thus of volume dV = π(y/3)2 dy = πy 2 dy/9. Since the liquid weighs 1 Newton per cubic foot, dV equals the weight of the slab in Newtons. The slab needs to be raised 14 − y meters. Thus Z π 14 (14 − y)y 2 dy = 320π. W = 9 0 [6] Determine the nature (convergence or divergence) of the following integrals and give reasons in each case. Z 2 s+1 √ (a) ds. 4 − s2 0 Solution. b ! Z 2 Z b s+1 s+1 s √ √ ds = lim ds = lim − (4 − s2 )1/2 + arcsin b→2− 0 b→2− 2 0 4 − s2 4 − s2 0 b π = lim −(4 − b2 )1/2 + 2 + arcsin =2+ b→2− 2 2 Converges 5 Z ∞ 2 dx. −x 2 Solution. (b) x2 This integral can be computed. But, since 2 x2 −x lim 1 x→∞ x2 and Z R∞ 2 ∞ (c) = 2 6= 0, ∞ (1/x2 ) dx converges being a p integral wit p = 2 > 1, the integral converges 3 x2 e−x dx. Converges. One can compare to e−x , or one can calculate it. 0 [7] Determine the following limits, or declare that the corresponding sequence diverges. en + 1 . n→∞ en − 1 Solution. (a) lim en + 1 = 1. n→∞ en − 1 lim n (b) lim n→∞ n+1 Solution. n . lim n→∞ 100n (c) lim . n→∞ n! Solution. n n+1 n = e−1 . 100n = 0. n→∞ n! lim 6 [8] Determine the nature (convergence or divergence) of the following series. Give reasons in each case. (a) ∞ X ln(n) n=1 n . Solution. Since ln n n n→∞ 1 n lim = lim ln n = ∞ n→∞ the series diverges by limit comparison with the divergent harmonic series (b) ∞ X n=2 P∞ n=1 1/n. (1/n) q . 2 ln(n) ln (n) − 1 P p Solution. One approach is to state that we saw in class that the series ∞ n=2 1/[n(ln n) ] converges if and only if p > 1 (not exactly a pPseries!), thus the series in question 2 converges by limit comparison with the series ∞ n=2 1/[n(ln n) ]. Or one can apply the integral test directly; the terms of the series decrease: Z ∞ Z b dx dx p p = lim b→∞ 2 2 x ln x ln2 x − 1 x ln x ln2 x − 1 Z ln b du √ (u = ln x) = lim b→∞ ln 2 u u2 − 1 ln b π = lim arcsec u = − arcsec ln 2. b→∞ 2 ln 2 The series converges . (c) ∞ X lnn (n) n=1 nn . Solution. (d) n ∞ X n−2 n=2 n Solution. The series converges by the root test. . The series diverges by the n-th term test. ∞ X √ (e) ( n6 + n + 1 − n3 ). n=1 Solution. Converges. Done in class. [9] Compute ∞ X n=1 6 (2n − 1)(2n + 1) 7 Solution. This is a telescoping series. One has 6 1 1 =3 − (2k − 1)(2k + 1) 2k − 1 2k + 1 thus n X 6 (2k − 1)(2k + 1) k=1 n X 1 1 1 1 1 1 1 = 3 − = 3 1 − + − ± ··· + − 2k − 1 2k + 1 3 3 5 2n − 1 2n + 1 k=1 1 = 3 1− → 3 as n → ∞. 2n + 1 sn = Thus ∞ X n=1 6 = 3. (2n − 1)(2n + 1) [10] Determine which of the following series: i. Converge absolutely. ii. Converge conditionally. iii. Diverge. Justify your answer. (a) ∞ X (−1)n+1 n=1 Solution. 1 n3/2 . It converges absolutely because ∞ ∞ X X 1 1 n+1 (−1) = 3/2 3/2 n n n=1 n=1 is a p-series with p = 3/2 > 1, thus converges. (b) ∞ X 1 (−1)n+1 √ . n n=1 Solution. The series converges by the alternate series test. However, the series of absolute values is a p-series with p = 1/2 < 1, hence diverges. The series converges conditionally . 8 [11] Find the radii and intervals of convergence of the following power series (a) ∞ X x2n+1 n=1 n! . The radius is r = ∞, the interval is (−∞, ∞). Solution. (b) ∞ X n=1 xn √ . 3n n n Solution. The radius is r = 3, the interval is [−3, 3]. ∞ X 2n (x − 3)n . (c) n + 1 n=0 1 5 The radius is r = , the interval is , f rac72 . 2 2 Solution. (d) ∞ X (−1)n n=0 3n (x + 1)n . Solution. The radius is r = 3, the interval is (−4, 2). [13] Find the Taylor polynomials of order 3 generated by f at x = 0 when ex + e−x . 2 Solution. Method 1. We know (or have no excuse for not knowing) that ex = 2 3 4 2 3 4 1+x+ x2 + x6 + x24 +· · · ; replacing x by −x one gets e−x = 1−x+ x2 − x6 + x24 ∓· · · ; 2 4 adding and dividing by two, (ex + e−x )/2 = 1 + x2 + x24 + · · · . Keeping only the terms of degree ≤ 3 we get that the polynomial is: (a) f (x) = 1+ x2 . 2 Method 2. We compute three derivatives: f 0 (x) = ex − e−x , 2 f 00 (x) = ex + e−x , 2 f 000 (x) = ex − e−x . 2 Setting x = 0 (also in f (x)) we get that f (0) = 1, f 0 (0) = 0, f 00 (0) = 1, f 000 (0) = 0. The third order Taylor polynomials at x = 0 is: 1 1 x2 T3 (x) = f (0) + f 0 (0)x + f 00 (0)x2 + f 000 (0)x3 = 1 + . 2 6 2 (b) f (x) = sin(x). 9 Solution. Method 1. We know (or have no excuse for not knowing) that 3 x5 sin x = x − x6 + 120 ± · · · . Keeping only the terms of degree ≤ 3 we get that the polynomial is: x3 x− . 6 Method 2. We compute three derivatives: f 0 (x) = cos x, f 00 (x) = − sin x, f 000 (x) = − cos x. Setting x = 0 (also in f (x)) we get that f (0) = 0, f 0 (0) = 1, f 00 (0) = 0, f 000 (0) = −1. The third order Taylor polynomials at x = 0 is: 1 x3 1 T3 (x) = f (0) + f 0 (0)x + f 00 (0)x2 + f 000 (0)x3 = x − . 2 6 6 [14] Write out a Maclaurin series for the following functions f (x). In each case give the interval of validity (in what interval is f (x) equal to the sum of its series) (a) f (x) = x2 ex . Remember to state the interval where the Maclaurin series converges to f (x). P xn Solution. Since ex = ∞ n=0 n! , and this is valid for −∞ < x < ∞, we get by the simple expedient of multiplying by x2 , 2 x xe = ∞ X xn+2 n=0 n! = x2 + x 3 + x4 x5 + + · · ·. 2 6 The interval of validity is, of course, still −∞ < x < ∞. (b) f (x) = 1 . 1−4x Remember to state the interval where the Maclaurin series converges to f (x). ∞ X 1 Solution. We saw zillions of time that = xn if (and only if) |x| < 1. 1 − x n=0 Thus (replacing x by 4x) ∞ X 1 = 4n xn = 1 + 4x + 16x2 + 64x3 + · · ·. 1 − 4x n=0 10 for |4x| < 1. Because if a power series centered at 0 converges to a function in an interval around zero then the power series is the Maclaurin series, the series in the frame above is the Maclaurin series for 1/(1 − 4x). Because it converges to the 1 1 . function if and only if |4x| < 1, the interval of validity is − , 4 4 (c) f (x) = arctan x Solution. Done in class