Math 165 – Exam 1D - solutions Problem 1 Evaluate the following limits. 2x + 4 12 a) lim = =4 x→4 x − 1 3 y+1 1 b) lim 2 = y→−1 y + 5y + 4 3 cos2 (t) sin(4t) sin(2t) 8 = 2 t→0 9t 9 Solution In a), simply use substitution. In b), factor and cancel out y + 1 to get 1 y+1 = 2 y + 5y + 4 y+4 c) lim the limit of which you can then compute again by substituting y = −1, since the denominator is now nonzero. In c), you need to split this up so you can use special trig limits, namely 8 cos2 (t) sin(4t) sin(2t) cos2 (t) sin(4t) sin(2t) = · · 9t2 9 4t 2t Then the first factor has limit 8/9 and the second and third factors have limit 1. Problem 2 Evaluate the limits, if they exist. 4t2 − 5t + 8 cos t 4 = 2 t→∞ 7t − 5t 7 3−z = −∞ b) lim− 2 z→2 z − 4 Solution In a), we factor out the leading power t2 in numerator and denominator, getting 4 − 5t−1 + 8t−2 cos t lim t→∞ 7 − 5t−1 and every term tends to zero except the 4 and the 7. In particular, we use the Sandwich Theorem on a) lim − 8 8 cos t 8 ≤ ≤ 2 2 2 t t t to see that the function in the middle has limit zero. In b), the denominator has limit zero, but the numerator does not. Also, the numerator is positive for z close to 2, and z 2 − 4 < 0 for z approaching 2 from the left. So the limit is negative infinity. Problem 3 Evaluate the following limit. √ √ x+4− 6 L = lim x→2 x−2 Solution We cannot use substitution, since and denomina√ √ both numerator tor have limit 0. So we multiply both by x + 4 + 6, getting x−2 √ √ x→1 (x − 2)( x + 4 + 6) √ 1 1 6 √ = √ = . = lim √ x→1 12 x+4+ 6 2 6 L = lim Problem 4 Consider the function f (x) = 2 + sin(5x). a) Find the instantaneous rate of change of f (x) at x = 0. Use a limit computation, no rules for derivatives that are not covered in Chapter 2. b) Find an equation for the tangent line to the graph of f (x) at x = 0. Solution a) First, the instantaneous rate of change is sin(5h) 1 = 5. m = lim (2 + sin(5h) − (2 + 0)) = 5 lim h→0 h→0 h 5h b) The tangent line has equation y = 5x + 2. Problem 5 Consider a function f (x) defined by A for x = 0, B for x = 3, f (x) = 2 x + x − 12 for all other values of x. x2 − 3x a) Can the constant A be chosen so that f (x) is continuous at x = 0, and if so, what should it be? b) Can the constant B be chosen so that f (x) is continuous at x = 3, and if so, what should it be? Solution a) No. The limit of f (x) at x = 0 does not exist, because x2 + x − 12 x+4 = 2 x − 3x x and lim+ f (x) = lim+ x→0 x→0 x+4 =∞ x (you could also use that the left-handed limit is −∞). b) Yes. We compute x+4 7 = . x→3 x 3 lim f (x) = lim x→3 This is the value we need to choose for B to make f (x) continuous at 3.