Math 111 Final Exam Review1. Use the graph of y = f(x) in .docx
- 1. Math 111 Final Exam Review 1. Use the graph of y = f(x) in Figure 1 to answer the following. Approximate where necessary. (a) Evaluate f(−1). (b) Evaluate f(0). (c) Solve f(x) = 0. (d) Solve f(x) = −7. (e) Determine if f is even, odd, or neither from its graph. (f) State any local maximums or local minimums. (g) State the domain and range of f. (h) Over what interval(s) is the function increasing? (i) Over what interval(s) is the function decreas- ing? (j) Over what interval(s) is the function concave up? (k) Over what interval(s) is the function concave down? (l) Find the zeros of f.
- 2. (m) Find a possible formula for this polynomial function. 2 -2 -4 -6 2 4-2-4 x y Figure 1 2. Let f(x) = 2x − 1 x + 2 . (a) Find f−1(x). (b) Confirm the inverse by computing f−1 (f(x)) and f ( f−1(x) ) .
- 3. (c) State the domain and range of f and f−1. (d) Evaluate f(0). (e) Evaluate f−1(0). (f) Solve f(x) = 3. (g) Determine if f is even, odd, or neither from its formula. (h) State any horizontal and vertical asymptotes. (i) State any horizontal and vertical intercepts. (j) Sketch a graph of y = f(x) in Figure 2. 4 8 -4 -8 4 8-4-8 x y Figure 2 1
- 4. 3. Let f(x) = |x|. For each of the following, sketch a graph of the tranformation in Figure 4 and write the simplified formula for the function. Describe the order of transformations, being as specific as possible and listing them in an appropriate order. (a) −f(x) (b) f(x + 1) (c) 2f(x) (d) f(x) + 3 (e) 2f(x + 1) + 3 (f) f(3x) 2 4 -2 -4 2 4-2-4 x y Figure 3. Graph of y = |x| 2 4
- 7. 4 -2 -4 2 4-2-4 x y (f) Figure 4 4. Complete Table 1 below using the given values in the table. If any value is undefined, write “undefined.” Table 1 x -2 -1 0 1 2 f(x) 2 1 0 1 2 g(x) 4 2 0 -2 -4 (g ◦ f)(x) (g · f)(x) f(x) + g(x) f(x) g(x)
- 8. g−1(x) Page 2 of 5 5. Find a formula for the piecewise-defined func- tion graphed in Figure 5 below. f(x) = 1 2 3 -1 -2 -3 1 2 3-1-2-3 x y b bc bc b Figure 5. Graph of y = f(x)
- 9. 6. In Figure 6, graph the piecewise function de- fined by f(x) = x2 − 4, −2 ≤ x < 0 2, 0 < x < 1 −1 2 x + 2, x ≥ 1 1 2 3 -1 -2 -3 1 2 3-1-2-3 x
- 10. y Figure 6 7. The volume, V (in cubic centimeters) of a circular balloon of radius r (in centimeters) is given by V = f(r) = 4 3 πr3. As someone blows air into the balloon, the radius of the balloon as a function of time t (in seconds) is given by r = g(t) = 2t. (a) Find and interpret f(3). (b) Find and interpret g(3). (c) Find and interpret f(g(3)). (d) Find and interpret f(g(t)). (e) Explain why g(f(r)) in nonsense. (f) Find and interpret r = f−1(V ). (g) Find and interpret f−1(20). 8. Write the following using exponents. (a) log4 (64) = 3 (b) ln ( √ e) = 1 2
- 11. (c) log10 ( 1 100 ) = −2 9. Solve the following equations. Give the exact solution and then round accurate to two decimal places. Check your solutions for (e) through (j). (a) 7x = 5 (b) e5x = 10 (c) 5ex = 10 (d) 2 ( 32x ) = 7 ( 5x−2 ) (e) log4(2x + 1) = 2 (f) log2(x) + log2(3) = log2(2)
- 12. (g) log2(x) − log2(3) = log2(2) (h) 2 log5(x − 6) = log5(x) (i) logx (√ 3 ) = 1 4 (j) log(1 − x) = 2 + log(1 + x) Page 3 of 5 10. Find the equation of an exponential function that passes through each pair of points: (a) ( −1, 1 3 ) and (1, 12) (b) (2, 128) and (5, 2) 11. Mr. Oops invests $10, 000 into an account. After 4 years, he has $4, 096. Let t be the number of years after Mr. Oops’ investment began and let Q be the value of the investment at time t.
- 13. (a) Write two ordered pairs of the form (t, Q) representing the information above. (b) Assuming the investment decreases exponentially, write an exponential function modeling the value of the investment, Q, at time t. Use the ordered pairs you found in (a) to do so. (c) Assuming the investment decreases linearly, write a linear function modeling the value of the investment, Q, at time t. Use the ordered pairs you found in (a) to do so. 12. The temperature of a cup of tea after it was brewed can be modeled by the function T = f(t) = 100e−0.1t + 68, where t is the number of minutes since the tea was brewed and T is the temperature in degrees Fahrenheit. (a) Find and interpret f(0). (b) Find and interpret f(10). (c) Find and interpret f−1(T). (d) Find and interpret f−1(80). (e) Graph the function f in your calculator. What is the horizontal asymptote? 13. Tom and Jerry make separate investments at the same time. Their respective investments can be modeled by the functions T = f(t) = 5000(1.065)t and J = g(t) = 4500
- 14. ( 1 + 0.065 12 )12t where t is the number of years since each investment began and T and J are their respective investment values in dollars. (a) Who has the higher effective rate of interest? (b) How much does Tom invest initially? How much does Jerry invest initially? (c) What will the values of their respective investments be after 5 years? (d) How long will it take for Jerry’s investment to double? (e) How long will it take for their investments to be worth the same amount? How much will their respective investments be worth at this time? Use your graphing calculator to answer these. 14. The percentage of carbon 14, Q, remaining in a fossil t years since decay began can be modeled by the function Q = f(t) = 100e−0.000124t (a) If a piece of cloth is thought to be 750 years old. What percentage of carbon 14 is expected
- 15. to remain in this sample? (b) If a fossilized leaf contains 70% of its original carbon 14, how old is the fossil? Page 4 of 5 15. Find possible equations for each polynomial function in Figure 7. List the zeros and their multi- plicity, the vertical intercept, and the long-run behavior. 2 4 6 8 -2 -4 -6 -8 2 4 6 8-2-4-6-8 x y (a)
- 16. 2 4 6 8 -2 -4 -6 -8 2 4 6 8-2-4-6-8 x y b (4, 2.4) (b) Figure 7 16. Sketch a graph of y = f(x) for each polynomial function below. Also list the zeros and their multiplicity, the vertical intercept, and the long-run behavior. (a) f(x) = −x2(x + 4) (b) g(x) = (x − 2)(x + 1)2(x + 2) 17. Find possible equations for each rational function in Figure 8 below. List the zeros and their multiplicity, any vertical asymptotes, any horizontal
- 17. asymptotes, and the vertical intercept. 2 4 6 8 -2 -4 -6 -8 2 4 6 8-2-4-6-8 x y (a) 2 4 6 8 -2 -4
- 18. -6 -8 2 4 6 8-2-4-6-8 x y b (2, 1.6) (b) Figure 8 18. Sketch each rational function below. List the zeros and their multiplicity, any vertical asymptotes, any horizontal asymptotes, and the vertical intercept. (a) f(x) = − x2 − 2x − 3 x2 + 3x + 2 (b) g(x) = 2x + 4 x2 − 16 Page 5 of 5