Math 108, Solution of Midterm Exam 3

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Math 108, Solution of Midterm Exam 3 1 Find an equation of the tangent line to the curve x 3 +y 3 = xy at the point (1,1). Solution. Differentiating both sides of the given equation with respect to x, we get d [ x 3 +y 3] = d [xy] 3x +3y dy = y d (x)+x d (y) So, the slope of the tanget line is 3x +3y dy (3y x) dy dy and hence the equation of the tangent line is = y +xdy = y 3x = y 3x 3y x. dy = (1) 3(1) (1,1) 3(1) (1) = 1 y 1 = 1() y = x+ Let f be a function defined by f(x) = x 5 5x 4 +3. (a) Find intervals on which f is increasing and decreasing. Solution. The derivative of f is f (x) = d [ x 5 5x 4 +3 ] = 5x 4 0x 3 = 5x 3 (x 4) which is continuous everywhere, with f (x) = 0 where x = 0 and x = 4. The numbers 0 and 4 divide the x axis into three open intervals; namely, x < 0, 0 < x < 4, and x > 4. Choose a test number from each of these intervals; say c = 1 from x < 0, c = 1 from 0 < x < 4, and c = 5 from x > 4. Then, evaluate f (c) for each test number: f ( 1) = 5( 1) 3 ( 1 4) > 0, f (1) = 5(1) 3 (1 4) < 0, f (5) = 5(5) 3 (5 4) > 0. So, f(x) is increasing on x < 0 and x > 4 and decreasing on 0 < x < 4. 1

(b) Find x-coordinates of all critical points of f and classify each of them as a relative maximum, a relative minimum, or neither. Solution. Since f (x) exists for all x, the only critical numbers are where f (x) = 0, i.e., x = 0 and x = 4. Since f (x) > 0 to the left of x = 0 and f (x) < 0 to the right of x = 0, the critical point where x = 0 is a relative maximum. Since f (x) < 0 to the left of x = 4 and f (x) > 0 to the right of x = 4, the critical point where x = 4 is a relative minimum. (c) Find intervals on which the graph of f is concave up and concave down. Solution. Since the first derivative of f is f (x) = 5x 4 0x 3, the second derivative of f is f (x) = 0x 3 60x = 0x (x 3) The second derivative f (x) is continuous for all x and f (x) = 0 for x = 0 and x = 3. These numbers divide the x axis into three intervals; namely x < 0, 0 < x < 3, and x > 3. Evaluating f (x) at test numbers in each of these intervals (say, x = 1, x = 1, and x = 4, respectively), we find f ( 1) = 0( 1) ( 1 3) < 0, f (1) = 0(1) (1 3) < 0, f (4) = 0(4) (4 3) > 0. Thus, the graph of f(x) is concave down for x < 0 and 0 < x < 3 and concave up for x > 3. (d) Find x-coordinates of all inflection points of f. Solution. Since the concavity does not change at x = 0, f(x) does not an inflection point at x = 0. Since the concavity changes from downward to upward at x = 3, the graph of f(x) has an inflection point at x = 3. 3 Let f be a function defined everywhere except x = 1 and whose derivative is given by f (x) = x 7x+10. (a) Find all critical numbers of f and classify each of them as a relative maximum, a relative minimum, or neither.

Solution. Since f (x) = x 7x+10 = (x )(x 5) is continuous everywhere except x = 1 which is not in the domain of f(x) and f (x) = 0 when x = or x = 5, the critical numbers are x = and x = 5. The critical numbers and 5 together with x = 1 divide the x axis into four open intervals; namely, x < 1, 1 < x <, < x < 5, and x > 5. Evaluating f (x) at test numbers in each of these intervals (say, x = 0, x = 3, x = 3, and x = 6, respectively), we find f (0) = (0 )(0 5) < 0, f ( 3 ) 0 1 = (3 )(3 5) 3 1 > 0, f (3) = (3 )(3 5) 3 1 f (6) = (6 )(6 5) 6 1 Since f (x) > 0 to the left of x = and f (x) < 0 to the right of x =, the critical point where x = is a relative maximum. Since f (x) < 0 to the left of x = 5 and f (x) > 0 to the right of x = 5, the critical point where x = 5 is a relative minimum. < 0, > 0. (b) Find x-coordinates of all inflection points of f. Solution. By the quotient rule, f (x) = () d (x 7x+10) (x 70) d () = ()(x 7) (x 7x+10)(1) = x 7x x+7 x +70 = x x 3 = (x+1)(x 3) Since f (x) is not continuous at x = 1 and f (x) = 0 when x = 1 or x = 3, the x-axis is divided into four intervals; namely, x < 1, 1 < x < 1, 1 < x < 3, and x > 3. Evaluating f (x) at test 3

numbers in each of these intervals (say, x =, x = 0, x =, and x = 4, respectively), we find f ( ) = ( +1)( 3) ( 1) > 0, f (0) = (0+1)(0 3) (0 1) < 0, f () = (+1)( 3) ( 1) < 0, f (4) = (4+1)(4 3) (4 1) > 0. Since the concavity changes from upward to downward at x = 1, the graph of f(x) has an inflection point at x = 1. Since the concavity changes from downward to upward at x = 3, the graph of f(x) has an inflection point at x = 3. 4 Find all vertical and horizontal asymptotes of the graph of the function x +x 3 x +x. Solution. Since the denominator of the given function can be factored into ()(x+), it is 0 when x = 1 or x =. Since and x +x 3 x 1 x +x = ()(x+3) x 1 ()(x+) = x+3 x 1 x+ = 5 3 x +x 3 x 1+ x +x = ()(x+3) x 1+ ()(x+) = x+3 x 1+ x+ = 5 3, x = 1 is not a vertical asymptote. Since x +x 3 x + x +x = ()(x+3) x + ()(x+) = x+3 x + x+ = x = isavertical asymptoteofthegiven graph. Thereforex = istheonlyvertical asymptote of the given function. Since x +x 3 + 1 x + x +x = x 3 x x + 1+ 1 x 1 = x and x +x 3 + 1 x x +x = x 3 x x 1+ 1 x 1 = x y = is a horizontal asymptote of the given graph. 4

5 Find the absolute maximum and absolute minimum (if any) of the function f(x) = x 3 3x 9x+10 on the interval x. Solution. From the derivative f (x) = 3x 6x 9 = 3(x+1)(x 3) we see that the critical numbers are x = 1 and x = 3. Of these, only x = 1 lies in the interval < x <. Compute f(x) at the critical number x = 1 and at endpoints x = and x =. f( 1) = ( 1) 3 3( 1) 9( 1)+10 = 15 f( ) = ( ) 3 3( ) 9( )+10 = 8 f() = () 3 3() 9()+10 = 1 Compare these values to conclude that the absolute maximum of f(x) on the interval 1 x 3 is f( 1) = 15 and the absolute minimum is f() = 1. 6 Findtheabsolutemaximumandabsoluteminimum(ifany)ofthefunctionf(x) = x 3 1x+0 on the interval x 0. Solution. Since f (x) = 3x 1 = 3(x )(x+), x = is the only critical number of f(x) on x 0. Since f (x) < 0 for 0 < x < and f (x) > 0 for x >, the graph of f is decreasing for 0 < x < and increasing for x >. It follows that f() = () 3 1()+0 = 4 is the absolute minimum of f on the interval x 0 and that there is no absolute maximum. 5

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