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MA16100I Fall 2015 Final Review Problems The following a a collection of problems to help prepare for the final exam. There are a lot of problems here, so don’t feel like you have to do them all. Also, these problems are not meant to be a representation of the final exam problems themselves. Final exam problems may be worded or phrased differently than what is below. For an accurate set of problems that the final exam problems would look like, check out the Past Exam Archive on the Purdue Math Department webpage. (I) Solve the following trigonometric equations. (1) tan x = 1 1 (2) sin x = − 2 √ 3 (3) cos x = 2 √ (4) csc x = 2 √ (5) cot x = − 3 (10) 2 cos2 x − cos x = 1 (6) sec x = 1 (11) sin 2x = sin x (7) csc x = 0 (12) cos x − cos 2x = 1 (8) tan2 x − tan x = 0 (9) sin x = cos x (13) sin2 x + cos x = 1 1 (14) sin x cos x = 2 (II) Sketch a graph of each of the following trigonometric functions. What is the period of each function? π (1) y = sin 2x (4) y = 2 csc 3x −2 (7) y = 2 sin 2x − 2 πx (2) y = −3 cos πx (5) y = cot x 3 π (3) y = tan (8) y = cos 3x − +1 (6) y = − sec 4x 2 2 (III) Simplify the following expressions involving inverse trigonometric functions. √ (6) sec cot−1 3 + csc−1 (−1) π (7) sec−1 sec − 6 −1 x (8) sec tan 2 (9) cos sin−1 x ! √ x2 + 4 −1 (10) sin sec x (1) tan−1 (−1) 1 (2) sin−1 √ 2 √ ! 3 (3) cos−1 2 (4) csc−1 2 √ (5) csc sec−1 2 + cos tan−1 − 3 (IV) Simplify. (1) 253/2 (5) 642/3 64−3/2 (2) 8−4/3 1/2 4 (3) 9 (6) 813/4 − 2432/5 (7) −3x−2 4x4 2x3 3x2 (8) 3 (x2 ) 2/3 (4) (−27) 1 2 (9) 2x 3x2 (10) x2 yz 3 −2xz 2 x3 y −2 −2 1 4 −3 (11) x y 3 7 x 2 5 (12) −2xy 8y 3 (V) Expand out each of the logarithmic expressions. (1) ln p x(x + 1) ! √ x x2 + 1 (4) log2 (x + 1) r 1 (2) ln t(t + 1) θ+5 (3) ln θeθ s (5) ln 2/3 (x + 1)1 0 (2x + 1)5 2√ (6) ln ex 2x + 1 r x(x + 2) (7) ln 3 x2 + 1 ! 2 ex (8) ln p x(x + 1) (VI) Graph each of the following exponential/logarithmic functions. (1) f (x) = 3x (2) f (x) = 5 (5) f (x) = 42−x − 3 −x (6) f (x) = −5 + e x (3) f (x) = 2 (6 ) (4) f (x) = 1 − 2 x x−4 (9) f (x) = log5 (x − 4) + 3 (7) f (x) = log10 x (10) f (x) = 2 log3 (x + 1) (11) f (x) = ln x2 (8) f (x) = log2 (2x) (12) f (x) = ln (x − 1) (VII) Solve the following exponential/logarithmic equations. (1) 32x−1 = 27 x (2) 32 = 4 2 (3) 324 = (4) 1 (6) 2x 32x (7) (8) (9) x−1 1 2 = 23−2x 8 1 64 2 2 23x 3x 24x = 576 2x = 3 43x−2 = 19 10 = 7 + 6e2x 2 (5) 42x−x = 3x (10) log7 (1 − x) = 3 (11) 2x = e2 (12) 16ex = 10 ex + 4 (13) 4 =1 1 + 3e−2x (VIII) Given the following point pairs, find the values of C and a such that the graph of y = Cax contains the two points. (1) (0, 2), (1, 12) (2) (1, −12), (−1, −3/4) (3) (2, 1/2), (−1, 4) 2 (4) (0, −5), (−1, −15) (IX) Given the graph, find the one-sided and two-sided limits at the given points. At which of these points are the graphs continuous? (1) c = −1, 0, 1, 2, 3 (3) c = −1, 0, 1, 2, 3, 4, 5, 6, 7 (2) c = −1, 0, 1, 2, 3 (4) c = −1, 0, 1, 2, 3, 4, 5 (its difficult to see, but there is a solid point at (3, 0)) (X) Given the limits of f (x) and g(x), find the specified limits. (1) Suppose lim f (x) = −7 and lim g(x) = 0. Find x→−2 x→−2 (a) lim 3f (x) (c) lim cos (g(x)) x→−2 x→−2 (b) lim f (x)g(x) 2 x→−2 (2) Suppose lim f (x) = 1/2 and lim g(x) = x→0 x→−2 (d) lim (f (x)) x→−2 √ x→0 (a) lim −g(x) x→0 (b) lim f (x) + g(x) 1 f (x) f (x) cos x (f) lim x→0 x−1 (e) lim x→0 (d) lim g(x)f (x) x→0 x→−2 2. Find (c) lim x + f (x) x→0 f (x) g(x) − 7 (f) lim |f (x)| (e) lim x→0 (3) Suppose lim f (x) = 1 and lim g(x) = 8. Find x→1 (a) lim f (x) − g(x) x→1 (b) lim f (x) − x2 x→1 x→1 g(x) sin x x (d) lim ln (f (x)) f (x) + g(x) f (x) − 2g(x) (f) lim g (f (x)) (c) lim (e) lim x→1 x→1 x→1 3 x→1 (XI) Find the following limits. sin 3y 4y x (17) lim x→0 sin 3x tan 2x (18) lim x→0 x x csc 2x (19) lim x→0 cos 5x (1) lim (2x + 5) (16) lim x→−7 x→0 (2) lim (10 − 3x) x→12 (3) lim −x2 + 5x − 2 x→2 4 x→5 x − 7 (4) lim 1/3 (5) lim (2z − 8) x→0 1/x (20) lim (1 + 3x) x2 + 3x − 10 x→−5 x+5 x3 − 8 lim x→2 x4 − 16 x2 − 4x + 4 lim 3 x + 5x2 − 14x (a) x → 0 (b) x → 1 (c) x → 2 x2 + x lim 5 x + 2x4 + x3 (a) x → −1 (b) x → 0 (c) x → 1 √ 1− x lim x→1 1 − x √ x2 + 8 − 3 lim x→−1 x+1 4x − x2 √ lim x→1 2 − x 1 1 lim sin − x→2 x 2 h π i lim sec cos x + π tan −1 x→0 4 sec x √ sin 2x √ lim x→0 2x x→0 (6) lim (7) (8) (9) (10) (11) (12) (13) (14) (15) (21) lim ln (1 + x) 2/x x→0 1/(5x) (22) lim (1 + 3x) x→0 (23) lim (a) (b) (c) (d) (24) lim (a) (b) (c) (d) (e) (25) lim (a) (b) (c) (d) (e) 4 1 −4 x → 2+ x → 2− x → −2+ x → −2− x2 x2 − 3x + 2 x3 − 2x2 x → 2+ x → 2− x→2 x → 0+ x→0 x2 − 3x + 2 x3 − 4x x → 2+ x → −2+ x → 0− x → 1+ x→0 (XII) Where are the following functions continuous? For each point of discontinuity, determine the type (i.e. removable, infinite, step, infinite oscillation). 1 x ≤ −1 −x x≤0 sin π −1 < x < 0 −x 0<x<2 . (3) f (x) = x 1 x=0 (1) f (x) = . (x − 2)2 2≤x<4 √ 0<x<1 −x 8x − x2 4≤x≤8 1 x≥1 0 x≤1 1/(x − 1) 1<x<2 (4) f (x) = . x−2 2≤x<3 (x − 2)2 3≤x 0 x ≤ −1 x=0 1/x 0 < |x| < 1 0 (2) f (x) = . 1 0 x = 1 . (5) f (x) = x 6= 0 sin 1 x>1 x (XIII) Find the vertical asymptotes of the following functions. (1) f (x) = 5 2x 1 −4 ex (3) f (x) = x+1 x−1 (4) f (x) = 2 x + 4x − 5 cos x (5) f (x) = x−1 (2) f (x) = sin x x (7) f (x) = tan x (6) f (x) = x2 (8) f (x) = cot x (13) f (x) = ln(x2 − 1) (14) f (x) = x2 − 3x + 2 x3 − 4x (9) f (x) = sec x (10) f (x) = csc x (15) f (x) = 2 − (11) f (x) = ln x (12) f (x) = ln(x2 + 1) (16) f (x) = 1 x1/3 −2 (x − 3)2 (XIV) Find the derivative using the definition of the derivative. (I know, I know, using the definition is a pain, and we will be spending the next few weeks talking about the derivative rules. But it is good practice with algebra to evaluate via the definition.) (1) f (x) = 4 − x2 (2) f (x) = (x − 1)2 + 1 (3) f (x) = 1−x 2x √ (5) f (x) = 3x (4) f (x) = 1 x2 (6) f (x) = x − 1 x 1 x+1 √ (8) f (x) = x + x 1 (9) f (x) = (x − 1)2 (7) f (x) = √ (XV) Find the equation for the tangent line of the given function at the given point. (1) f (x) = x2 + 1 at c = 2 2 (2) f (x) = x − 2x at c = 1 x (3) f (x) = at c = 3 x−2 8 at c = 2 x2 (5) f (x) = x3 at c = 2 (4) f (x) = (6) f (x) = x3 + 3x at c = 1 5 (7) f (x) = √ √ x + 1 at c = 3 5x − 1 at c = 2 x−1 (9) f (x) = at c = 0 x+1 (8) f (x) = (XVI) Find the first and second derivatives, dy/dx and d2 y/dx2 . (30) y = x2 sin4 x + x cos−2 x 4 1 2 −3 (31) y = (5 − 2x) + +1 8 x √ (32) y = x tan (2 x) + 7 √ (33) y = sec ( x) tan x1 (34) y = cos 5 sin x3 p √ (35) y = 4 sin x+ x (1) f (x) = 4 − x2 (2) f (x) = (x − 1)2 + 1 1 (3) f (x) = 2 x 1−x (4) f (x) = 2x √ (5) f (x) = 3x 1 (6) f (x) = x − x 1 (7) f (x) = √ x+1 √ (8) f (x) = x + x 1 (9) f (x) = (x − 1)2 (36) x3 + y 3 = 18xy x−1 (37) y 2 = x+1 (38) x + tan(xy) = 0 (39) y 2 cos y1 = 2x + 2y √ 1 (40) y = x7 + x 7 − π+1 x2 − 1 x2 + 1 (11) y = (1 − x)(1 + x2 )−1 5x + 1 (12) y = √ 2 x (10) y = (41) y = 2 tan2 x − sec2 x (42) xy + 2x + 3y = 1 √ (43) xy = 1 (19) y = csc x (44) y = x (sin (ln x) + cos (ln x)) s (x + 1)5 (45) y = ln (x + 2)20 r x (46) y = x+1 x sin x (47) y = √ sec x √ x x2 + 1 (48) y = (x + 1)2/3 s x(x + 1)(x − 2) (49) y = 3 (x2 + 1)(2x + 3) (20) y = x2 − sec x + 1 (50) ln y = ey sin x (21) y = 4 − x2 sin x (51) ln(xy) = ex+y (22) y = x sin x + cos x (52) e2x = sin(x + 3y) (23) y = sec x csc x (53) tan y = ex + ln y (54) y = esin x ln x2 + 1 x3 + 7 (13) y = x (x − 1)(x2 + x + 1) (14) y = x3 1 + 3x (15) y = (3 − x) 3x (16) y = (x + 1)(x − 1)(x2 + 1) x2 + 3 (x − 1)3 + (x + 1)3 (18) y = tan x (17) y = (24) y = 6x2 cot x csc(2x) (25) y = (2x + 1)5 x −7 (26) y = 1 − 7 5 x 1 (27) y = + 5 5x (28) y = sec(tan x) e1/x x2 (56) y = (2x + 5)−1/2 (29) y = 5(cos x)−4 (60) y = tan−1 (ln x) (55) y = (57) y = x(x2 + 1)−1/3 (58) y = cos−1 x2 (59) y = sec−1 5x 6 (61) y = ln x2 + 4 − x tan−1 (62) y = 1 2 x 2 (65) y = 2x (66) y = (x + 1)x sinh (2x + 1) ln x (63) y = sech x (1 − ln sech x) √ √ (64) y = 2 x tanh x (67) y = (ln x) √ x (68) y = ( x) (XVII) Find the equation for the tangent line of the given graph at the given point. (1) y = x2 − 4 at c = 2 (2) y = sin x at c = π/3 (3) y = 1 + cos x at c = −π/3 9 (4) y = x + at c = −3 x (5) y = (x + 1)3 at c = −2 (6) x2 + y 2 = 25 at (3, −4) (7) 6x2 + 3xy + 2y 2 + 17y − 6 = 0 at (−1, 0) (8) x2 cos2 y − sin y = 0 at (0, π) (9) x2 y 2 = 9 at (−1, 3) √ 4 2 2 (10) y = y − x at 3 1 , 4 2 ! (11) y 2 (2 − x) = x3 at (1, 1) (12) y 4 − 4y 2 = x4 − 9x2 at (3, 2) √ (13) x + xy = 6 at (4, 1) (14) x3/2 + 2y 3/2 = 17 at (4, 1) (XVIII) Find points of the graph that have a horizontal tangent line. (1) y = −x3 + 3x2 − 3x (3) y = x + sin x (5) x2 + xy + y 2 = 7 (2) y = (x4 /4) − x3 + x2 (4) y = x − cot x (6) x3 + y 3 − 9xy = 0 (XIX) Answer the following word problems. (1) A rock is thrown vertically at a rate of 64 ft/s from the edge of a 196 ft cliff. Suppose the height of the rock is given by s(t) = −16t2 + v0 t + s0 . (a) (b) (c) (d) What is the velocity and acceleration of the rock after t seconds? What is the velocity and acceleration of the rock at t = 1? t = 5? How high does the rock get? What is the speed of the rock when it hits the bottom of the cliff? (2) Now assume that the rock encounters some air resistance while traveling, and its height is now given by s(t) = ke−t − 16t + a. (a) What is the velocity and acceleration of the rock after t seconds? (b) What is the velocity and acceleration of the rock at t = 1? t = 5? (c) How high does the rock get? (3) The power P of an electric circuit is related to the circuit’s resistance R and current i by the equation P = Ri2 . (a) Write an equation to determine dP/dt if R and i are functions of t. (b) For a given circuit, at a specific moment in time, the power and resistance of a resistor is 1 kW and 16 kΩ, respectively. If the power is increasing at 100 W/s and the current is increasing at 0.1 A/s, then how fast is R changing? 7 (4) Water is flowing at the rate of 6 m3 /min from a reservoir shaped like a hemispherical bowl of radius 13 m. The volume of water remaining is given by V = 1 2 πy (3R − y) 3 where R is the radius of the hemisphere and y is the height of the water level from the base. (a) At what rate is the water level changing when the water is 8 m deep? (b) What is the radius r of the water’s surface when the water is y m deep? (c) At what rate is the radius r changing when the water is 8 m deep? (5) A spherical iron ball 8 in in diameter is coated with a layer of ice of uniform thickness. If the ice melts at the rate of 10 in3 /min, how fast is the thickness of the ice decreasing when it is 2 in thick? How fast is the surface area changing? (For a sphere, the volume is V = (4/3)πr3 , and the surface area is S = 4πr2 ). (6) One morning, the shadow of an 80 ft building on level ground is 60 ft long. At the moment in question, the angle θ the sun makes with the ground is increasing at the rate of 0.27◦ / min. At what rate is the shadow decreasing? (Careful about units!) (7) A particle moves along the parabola x = y 2 in the first quadrant in such a way that its y-coordinate (measured in meters) increases at a steady 10 m/sec. How fast is the distance the particle is from the point (1/4, 0) changing when x = 3? How fast is the angle between the +x-axis and the line joining the particle to the point (1/4, 0) changing when x = 3? (8) A man 6 ft tall walks at the rate of 5 ft/sec toward a streetlight that is 16 ft above the ground. At what rate is the tip of his shadow moving when he is 10 ft from the base of the light? (9) A light shines form the top of a pole 50 ft high. A ball is dropped from the same height form a point 30 ft away from the light. How fast is the shadow of the ball moving along the ground 1/2 sec later? Assume the ball falls a distance s = 16t2 ft in t seconds. (10) Two airplaces are flying along straight line course that intersect at right angles. Plane A is approaching the intersection point at a speed of 442 mph. Plane B is flying away from the intersection at 481 mph. At what rate is the distance between the planes changing when A is 5 miles from the intersection point and B is 12 miles from the intersection point? (11) At what rate is the distance between the tip of the second hand and the 12 o’clock mark (the top of the circular clock) changing when the second hand points to 4 o’clock? (12) Two ships are steaming straight away from a point O along routes that make a 120◦ angle. Ship A moves at 14 mph, and ship B moves at 21 mph. How fast are the ships moving apart from each other when OA = 5 and OB = 3 miles? (13) Water is flowing at a rate of 50 m3 /min from a shallow concrete conical reservoir (vertex down) of base radius 45 m and height 6 m. How fast is the water level falling when the water is 5 m deep? How fast is the area of the surface of the water changing then? (XX) Find the absolute extrema of each function on the given interval. (1) f (x) = 4 − x2 on [−3, 1] 1 (2) f (x) = − 2 on [1, 2] x 1 1 (3) f (x) = x + on ,3 x 2 x2 1 (4) f (x) = on − , 1 x+1 2 √ 4 − x2 on [−1, 2] h π πi (6) f (x) = sec x on − , 3 6 (5) f (x) = (7) f (x) = x2 ex on [−3, 1] (8) f (x) = x ln(x + 3) on [0, 3] 8 (XXI) Find the intervals of increasing and decreasing, concavity, inflection points, and relative extrema for each function. Make a sketch of the graph of the function. (1) f (x) = x4 − 6x3 − 5 (2) f (x) = x4 (3) f (x) = (x + 1)(x − 1)2 x+1 (4) f (x) = (x − 1)2 (5) f (x) = x5 − 5x4 (6) f (x) = x1/5 (7) f (x) = (2 − x2 )3/2 x3 (8) f (x) = 3x + 1 x2 − 3 x−2 √ (10) f (x) = x 8 − x2 (9) f (x) = (11) f (x) = x2 ln x (XXII) For each of the following graphs, find the intervals of concavity and inflection points if (b) the graph is of f 0 (a) the graph is of f (1) (2) (3) (XXIII) Find the following limits. 1 x2 − 2x + 5 (1) lim = x→∞ 2x2 + 5x + 1 2 2x + 1 =0 (2) lim x→−∞ 3x2 + 2x − 7 5 − 2x3/2 (3) lim x→∞ 3x2 − 4 x (4) lim √ x→−∞ x2 − x √ x4 − 1 (5) lim x→−∞ x3 − 1 2x x→−∞ (x6 − 1)1/3 (7) lim cos x (6) (8) (9) (10) (11) lim (12) x→∞ (13) 1 lim sin x→∞ x sin 3x lim x→∞ x 1 lim x sin x→∞ x 2 − x + sin x lim x→−∞ x + cos x 9 (14) (15) (16) 8 lim − arctan x x→∞ x 1 lim x→∞ ex + 1 1 lim x→−∞ ex + 1 h i p lim x + x2 + 3 x→±∞ h i p lim 3x − 9x2 − x x→±∞ (17) lim [ln(x + 1) − ln x] x→∞ sin 5x x x sin x lim x→0 1 − cos x x2 lim x→0 ln (sec x) x2x lim x x→0 2 − 1 sin x2 lim x→0 x (18) lim x→0 (19) (20) (21) (22) x−3 x2 − 3 √ 9x + 1 (24) lim √ x→∞ x+1 Z x 1 ln t dt (25) lim x→∞ x ln x 1 (23) lim x→3 (26) lim+ x1/(1−x) (28) lim+ xx x→0 2sin x − 1 x→0 ex − 1 (29) lim (30) lim e−1/x ln x x→0+ √ x→1 (27) lim x 1/ ln x (31) lim x→1+ x→∞ 10 x2 − 1 sec−1 x (XXIV) Find the indefinite integrals. Z (1) 4x5 dx Z (2) ex dx Z (3) 4 cos x dx Z −5 dx (4) x Z (5) sec2 x dx Z (6) − sec x tan x dx Z (7) 3 sin x dx Z (8) 3x2 − 2x + 1 dx Z (9) cos (7θ + 5) dθ Z (10) x2 sin x3 dx Z 1 dθ (11) 2 cos (2θ) Z (12) sin4 t cos t dt Z 3z dz √ (13) 3 z2 + 1 Z (14) x4 − 2x2 + 8x − 2 x3 − x + 2 dx Z (15) Z (16) sin 3x dx Z 2 x3 x4 − 1 dx Z √ (17) (18) 3 − 2s ds Z 4y dy p 2y 2 + 1 Z x x (20) tan7 sec2 dx 2 2 Z 5 3 r (21) r4 7 − dr 10 Z (22) e3x + 5e−x dx (19) √ Z (23) Z (24) Z (25) Z (26) Z (27) Z (28) Z (29) 18 tan2 x sec2 x 2 dx 2 + tan3 x Z (30) 11 e− √ r r dr esec πt sec πt tan πt dt er dr 1 + er dx 1 + ex 2x dx x2 − 5 x2 + 2x + 3 dx x3 + 3x2 + 9x dx √ 2 x + 2x dx √ 2 −x + 4x − 1 (XXV) Evaluate the definite integral. Z 3 p (1) Z y + 1 dy 0 Z 1 (2) r p π/4 √ ln π 1 − r2 dr (10) Z tan x sec2 x dx −3 π Z 2 3 cos x sin x dx Z 5r Z dv (8) 4 dx 2 x (ln x) 2 Z cos−3 2θ sin 2θ dθ 2 x2 − 2 dx x+1 1 x−1 dx x+1 (15) 0 Z 2 ln x dx x (14) π/6 (7) 0 1 4y − y 2 + 4y 3 + 1 −2/3 12y 2 − 2y + 4 dy(16) 0 Z 0 4 cos θ dθ 3 + 2 sin θ 2 (13) 1 2 v 3/2 1+ 1 Z dr √ 10 v 4 (6) Z 2 r2 ) (4 + 0 π/2 −π/2 1 (5) dx x (12) 0 Z −2 (11) 0 (4) 2 2 2xex cos ex dx 0 π/4 (3) Z 1 + ecot θ csc2 θ dθ Z −1 Z π/2 (9) (XXVI) Solve the differential equations. 3 dy = 12x 3x2 − 1 , y(1) = 3 dx dy = et sin et − 2 , y(ln 2) = 0 (2) dt (1) (XXVII) Solve the following problems. (1) A hard-boiled egg at 98◦ C is put in a sink of 18◦ C water. After 5 minutes, the egg’s temperature is 38◦ C. Assuming that the water has not warmed appreciably, how much longer will it take the egg to reach 20◦ C? (2) An aluminum beam was brought from the outside cold into a machine shop where the temperature was held at 65◦ F. After 10 minutes, the beam warmed to 35◦ F and after another 10 minutes it was 50◦ F.. Estimate the beam’s initial temperature. (XXVIII) Find the derivative of the following functions. √ Z x (1) f (x) = Z cos t dt (2) f (x) = 0 3t2 dt Z (5) f (x) = x 0 Z sin x (3) f (x) = x4 √ Z u du x (4) f (x) = 0 12 p 1 + t2 dt x2 cos tan x Z tan x (6) f (x) = − tan x √ t dt dt 1 + t2