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All Textbook Solutions for Precalculus

76AYU 77AYU 78AYU 79AYU 80AYU 81AYU 82AYU 83AYU 84AYU 85AYU 86AYU 87AYU 88AYU 89AYU 90AYU 91AYU 92AYU 93AYU 94AYU 95AYU 96AYU 97AYU 98AYU 99AYU 100AYU 101AYU 102AYU 103AYU 104AYU 105AYU 106AYU 107AYU 108AYU 109AYU 110AYU 111AYU 112AYU 113AYU 114AYU 115AYU 116AYU 117AYU 118AYU 119AYU 120AYU 121AYU True or False The quotient of two polynomial expressions is a rational expression, (p. A35)What are the quotient and remainder when 3 x 4 x 2 is divided by x 3 x 2 +1 . (pp. A25- A27)Graph y= 1 x .(pp.22-23)Graph y=2 ( x+1 ) 2 3 using transformations.(pp.106-114)True or False The domain of every rational function is the set of all real numbers.If, as x or as x , the values of R( x ) approach some fixed number L , then the line y=L is a _____ of the graph of R .If, as x approaches some number c , the values of | R( x ) | , then the line x=c is a ______ of the graph of R .For a rational function R , if the degree of the numerator is less than the degree of the denominator, then R is _____.9AYU True or False The graph of a rational function may intersect a horizontal asymptote.True or False If the degree of the numerator of a rational function equals the degree of the denominator, then the ratio of the leading coefficients gives rise to the horizontal asymptote.If a rational function is proper, then _____ is a horizontal asymptote.In Problems 15-26, find the domain of each rational function R( x )= 4x x3 In Problems 15-26, find the domain of each rational function R( x )= 5 x 2 3+x In Problems 15-26, find the domain of each rational function G( x )= 6 ( x+3 )( 4x )In Problems 15-26, find the domain of each rational function H( x )= 4 x 2 ( x2 )( x+4 )In Problems 15-26, find the domain of each rational function Q( x )= x(1x) 3 x 2 +5x2 In Problems 15-26, find the domain of each rational function F( x )= 3x(x1) 2 x 2 5x3 In Problems 15-26, find the domain of each rational function R( x )= x x 4 1 In Problems 15-26, find the domain of each rational function R( x )= x x 3 8 In Problems 15-26, find the domain of each rational function G( x )= x3 x 4 +1 In Problems 15-26, find the domain of each rational function H( x )= 3 x 2 +x x 2 +4 In Problems 15-26, find the domain of each rational function F( x )= 2( x 2 4 ) 3( x 2 +4x+4 )In Problems 15-26, find the domain of each rational function R( x )= 3( x 2 x6 ) 4( x 2 9 )In Problems 27-32, use the graph shown to find a. The domain and range of each function b. The intercepts, if any c. Horizontal asymptotes, if any d. Vertical asymptotes, if any e. Oblique asymptotes, if any In Problems 27-32, use the graph shown to find a. The domain and range of each function b. The intercepts, if any c. Horizontal asymptotes, if any d. Vertical asymptotes, if any e. Oblique asymptotes, if any In Problems 27-32, use the graph shown to find a. The domain and range of each function b. The intercepts, if any c. Horizontal asymptotes, if any d. Vertical asymptotes, if any e. Oblique asymptotes, if any In Problems 27-32, use the graph shown to find a. The domain and range of each function b. The intercepts, if any c. Horizontal asymptotes, if any d. Vertical asymptotes, if any e. Oblique asymptotes, if any In Problems 27-32, use the graph shown to find a. The domain and range of each function b. The intercepts, if any c. Horizontal asymptotes, if any d. Vertical asymptotes, if any e. Oblique asymptotes, if any In Problems 27-32, use the graph shown to find a. The domain and range of each function b. The intercepts, if any c. Horizontal asymptotes, if any d. Vertical asymptotes, if any e. Oblique asymptotes, if any In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. F( x )=2+ 1 x In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. Q( x )=3+ 1 x 2 In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. R( x )= 3 x In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. R(x)= 1 ( x1 ) 2 In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. G( x )= 2 (x+2) 2 In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. H( x )= 2 x+1 In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. R( x )= 1 x1 +1 In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. R( x )= 1 x 2 +4x+4 In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. F( x )=2 1 x+1 In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. G( x )=1+ 2 (x3) 2 In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. R( x )= x4 x In Problems 33-44, (a) graph the rational function using transformations, (b) use the final graph to find the domain and range, and (c) use the final graph to list any vertical, horizontal, or oblique asymptotes. R( x )= x 2 4 x 2 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. R( x )= 3x+5 x-6 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. R( x )= 3x x+4 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. G( x )= x 3 +1 x 2 -5x-14 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. H( x )= x 3 -8 x 2 -5x+6 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. P( x )= 4 x 2 x 3 -1 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. T( x )= x 3 x 4 -1 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. Q( x )= 2 x 2 -5x-12 3 x 2 -11x-4 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. F( x )= x 2 +6x+5 2 x 2 +7x+5 In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. R( x )= 8 x 2 +26x-7 4x-1 In problems , (a) graph the rational function using transformation , (b) use the final graph to find the domain and range , and (c) use the final graph to list any vertical , horizontal, or Oblique asymptotes. In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. G( x )= x 4 -1 x 2 -x In Problems 45-56, find the vertical, horizontal, and oblique asymptotes, if any, of each rational function. F( x )= x 4 -16 x 2 -2x 55AYU 56AYU 57AYU 58AYU 59AYU 60AYU 61AYU 62AYU 1AYU 2AYU 3AYU 4AYU 5AYU 6AYU In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x+1 x( x+4 )In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x ( x1 )( x+2 )In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= 3x+3 2x+4 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= 2x+4 x1 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= 3 x 2 4 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= 6 x 2 x6 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. P( x )= x 4 + x 2 +1 x 2 1 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. Q( x )= x 4 1 x 2 4 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. H( x )= x 3 1 x 2 9 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. G( x )= x 3 +1 x 2 +2x In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x 2 x 2 +x6 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x 2 +x12 x 2 4 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. G( x )= x x 2 4 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. G( x )= 3x x 2 1 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= 3 ( x1 )( x 2 4 )In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= 4 ( x+1 )( x 2 9 )In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. H( x )= x 2 1 x 4 16 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. H( x )= x 2 +4 x 4 1 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. F( x )= x 2 3x4 x+2 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. F( x )= x 2 +3x+2 x1 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x 2 +x12 x4 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x 2 x12 x+5 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. F( x )= x 2 +x12 x+2 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. G( x )= x 2 x12 x+1 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x ( x1 ) 2 ( x+3 ) 3 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= ( x1 )( x+2 )( x3 ) x ( x4 ) 2 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x 2 +x12 x 2 x6 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x 2 +3x10 x 2 +8x+15 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= 6 x 2 7x3 2 x 2 7x+6 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= 8 x 2 +26x+15 2 x 2 x15 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x 2 +5x+6 x+3 In Problems 7-50, follow Steps 1 through 7 on page 234 to analyze the graph of each function. R( x )= x 2 +x30 x+6 39AYU 40AYU 41AYU 42AYU 43AYU 44AYU In Problems 51-54, find a rational function that might have the given graph. (More than one answer might be possible.)In Problems 51-54, find a rational function that might have the given graph. (More than one answer might be possible.)In Problems 51-54, find a rational function that might have the given graph. (More than one answer might be possible.)In Problems 51-54, find a rational function that might have the given graph. (More than one answer might be possible.)49AYU 50AYU 51AYU 52AYU 53AYU 54AYU 55AYU 56AYU Graph each of the following functions: y= x 2 1 x1 y= x 3 1 x1 y= x 4 1 x1 y= x 5 1 x1 Is x=1 a vertical asymptote? Why not? What is happening for x=1 ? What do you conjecture about y= x n 1 x1 ,n1 an integer, for x=1 ?Graph each of the following functions: y= x 2 x1 y= x 4 x1 y= x 6 x1 y= x 8 x1 What similarities do you see? What differences?Create a rational function that has the following characteristics: crosses the x-axis at 3; touches the x-axis at 2 ; one vertical asymptote, x=1 ; and one horizontal asymptote, y=2 . Give your rational function to a fellow classmate and ask for a written critique of your rational function.Create a rational function that has the following characteristics: crosses the x-axis at 2; touches the x-axis at 1 ; one vertical asymptote at x=5 and another at x=6 ; and one horizontal asymptote, y=3 . Compare your function to a fellow classmate's. How do they differ? What are their similarities?Write a few paragraphs that provide a general strategy for graphing a rational function. Be sure to mention the following: proper, improper, intercepts, and asymptotes.Create a rational function with the following characteristics: three real zeros, one of multiplicity 2; y-intercept 1; vertical asymptotes, x=2andx=3 ; oblique asymptote, y=2x+1 . Is this rational function unique? Compare your function with those of other students. What will be the same as everyone elseâ€™s? Add some more characteristics, such as symmetry or naming the real zeros. How does this modify the rational function?Explain the circumstances under which the graph of a rational function will have a hole.Solve the inequality 34x5 . Graph the solution set. (pp. A79-A80)Solve the inequality x 2 5x24 . Graph the solution set. (pp. 170-172)3AYU True or False The graph of f( x )= x x3 is above the x-axis for x0 or x3 , so the solution set of the inequality x x3 0 is { x| x0orx3 } .In Problems 5-8, use the graph of the function f to solve the inequality. (a) f( x )0 (b) f( x )0 In Problems 5-8, use the graph of the function f to solve the inequality. (a) f( x )0 (b) f( x )0 In Problems 5-8, use the graph of the function f to solve the inequality. (a) f( x )0 (b) f( x )0 In Problems 5-8, use the graph of the function f to solve the inequality. (a) f( x )0 (b) f( x )0 In Problems 9-14, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 81-86 of Section 4.1.] Solve f( x )0 , where f( x )= x 2 ( x3 ) .In Problems 9-14, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 81-86 of Section 4.1.] Solve f( x )0 , where f( x )=x ( x+2 ) 2 .In Problems 9-14, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 81-86 of Section 4.1.] Solve f( x )0 , where f( x )= ( x+4 ) 2 ( 1x ) .In Problems 9-14, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 81-86 of Section 4.1.] Solve f( x )0 , where f( x )=( x1 ) ( x+3 ) 2 .In Problems 9-14, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 81-86 of Section 4.1.] Solve f( x )0 , where f( x )=2( x+2 ) ( x2 ) 3 .In Problems 9-14, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 81-86 of Section 4.1.] Solve f( x )0 , where f( x )= 1 2 ( x+4 ) ( x1 ) 3 .In Problems 15-18, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 7-10 of Section 4.5.] Solve R( x )0 , where R( x )= x+1 x( x+4 ) .In Problems 15-18, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 7-10 of Section 4.5.] Solve R( x )0 , where R( x )= x ( x1 )( x+2 ) .In Problems 15-18, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 7-10 of Section 4.5.] Solve R( x )0 , where R( x )= 3x+3 2x+4 .In Problems 15-18, solve the inequality by using the graph of the function. [Hint: The graphs were drawn in Problems 7-10 of Section 4.5.] Solve R( x )0 , where R( x )= 2x+4 x1 .19AYU In Problems 19-48, solve each inequality algebraically. ( x-5 ) ( x+2 ) 2 0 In Problems 19-48, solve each inequality algebraically. x 3 -4 x 2 0 In Problems 19-48, solve each inequality algebraically. x 3 +8 x 2 0 In Problems 19-48, solve each inequality algebraically. 2 x 3 -8 x 2 In Problems 19-48, solve each inequality algebraically. 3 x 3 -15 x 2 In problems 1954, solve each inequality algebraically. (x+2)(x4)(x6)0 In Problems 19-48, solve each inequality algebraically. ( x-5 ) 2 ( x+2 )0 In problems 1954, solve each inequality algebraically. x34x212x0 In Problems 19-48, solve each inequality algebraically. x 3 +2 x 2 -3x0 In Problems 19-48, solve each inequality algebraically. x 4 x 2 In Problems 19-48, solve each inequality algebraically. x 4 9 x 2 In Problems 19-48, solve each inequality algebraically. x 4 1 In Problems 19-48, solve each inequality algebraically. x 3 1 33AYU 34AYU 35AYU 36AYU 37AYU 38AYU 39AYU 40AYU 41AYU 42AYU 43AYU 44AYU 45AYU 46AYU 47AYU 48AYU 49AYU 50AYU 51AYU 52AYU 53AYU 54AYU 55AYU 56AYU 57AYU 58AYU 59AYU 60AYU For what positive numbers will the cube of a number exceed four times its square?For what positive numbers will the cube of a number be less than the number?What is the domain of the function f( x )= x 4 -16 ?What is the domain of the function f( x )= x 3 -3 x 2 ?What is the domain of the function f( x )= x-2 x+4 ?What is the domain of the function f( x )= x-1 x+4 ?67AYU 68AYU 69AYU 70AYU Average Cost Suppose that the daily cost C of manufacturing bicycles is given by C(x)=80x+5000 . Then the average daily cost C is given by C (x)= 80x+5000 x . How many bicycles must be produced each day for the average cost to be no more than 100 ?Average Cost See Problem 77. Suppose that the government imposes a 1000 -per-day tax on the bicycle manufacturer so that the daily cost C of manufacturing x bicycles is now given by C(x)=80x+6000 . Now the average daily cost C is given by C (x)= 80x+6000 x . How many bicycles must be produced each day for the average cost to be no more than 100 ?73AYU 74AYU 75AYU 76AYU 77AYU 78AYU 79AYU 1. Find f( 1 ) if f( x )=2 x 2 x 2. Factor the expression 6 x 2 +x-2 3. Find the quotient and remainder if 3 x 4 -5 x 3 +7x4 is divided by x3 . (pp. A25-A27 or A31-A34)4AYU 5AYU 6AYU 7AYU 8AYU 9AYU 10AYU In Problems 11-20, use the Remainder Theorem to find the remainder when f( x ) is divided by x-c . Then use the Factor Theorem to determine whether x-c is a factor of f( x ) . 11. f( x )=4 x 3 -3 x 2 -8x+4 ; x-2 In Problems 11-20, use the Remainder Theorem to find the remainder when f( x ) is divided by x-c . Then use the Factor Theorem to determine whether x-c is a factor of f( x ) . 12. f( x )=-4 x 3 +5 x 2 +8 ; x+3 In Problems , use the Remainder Theorem to find the remainder when is divided by . Then use the Factor Theorem to determine whether is a factor of . 13. In Problems 11-20, use the Remainder Theorem to find the remainder when f( x ) is divided by x-c . Then use the Factor Theorem to determine whether x-c is a factor of f( x ) . 14. f( x )=4 x 4 -15 x 2 -4 ; x-2 In Problems , use the Remainder Theorem to find the remainder when is divided by . Then use the Factor Theorem to determine whether is a factor of . 15. In Problems 11-20, use the Remainder Theorem to find the remainder when f( x ) is divided by x-c . Then use the Factor Theorem to determine whether x-c is a factor of f( x ) . 16. f( x )=2 x 6 -18 x 4 + x 2 -9 ; x+3 In Problems 11-20, use the Remainder Theorem to find the remainder when f( x ) is divided by x-c . Then use the Factor Theorem to determine whether x-c is a factor of f( x ) . 17. f( x )=4 x 6 -64 x 4 + x 2 -15 ; x+4 In Problems 11-20, use the Remainder Theorem to find the remainder when f( x ) is divided by x-c . Then use the Factor Theorem to determine whether x-c is a factor of f( x ) . 18. f( x )= x 6 -16 x 4 + x 2 ; x+4 In Problems 11-20, use the Remainder Theorem to find the remainder when f( x ) is divided by x-c . Then use the Factor Theorem to determine whether x-c is a factor of f( x ) . 19. f( x )=2 x 4 - x 3 +2x-1 ; x- 1 2 In Problems 11-20, use the Remainder Theorem to find the remainder when f( x ) is divided by x-c . Then use the Factor Theorem to determine whether x-c is a factor of f( x ) . 20. f( x )=3 x 4 + x 3 -3x+1 ; x+ 1 3 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 21. f( x )=-4 x 7 + x 3 - x 2 +2 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 22. f( x )=5 x 4 +2 x 2 -6x-5 In Problems, determine the maximum number of real zeros that each polynomial function may have. Then use Descartes' Rule of Signs to determine how many positive and how many negative real zeros each polynomial function may have. Do not attempt to find the zeros. 23. In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 24. f( x )=-3 x 5 +4 x 4 +2 In Problems 2132, determine the maximum number of real zeros that each polynomial function may have. Then use Descartes' Rule of Signs to determine how many positive and how many negative real zeros each polynomial function may have. Do not attempt to find the zeros. f(x)=2x3+5x2x7 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 26. f( x )=- x 3 - x 2 +x+1 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 27. f( x )=- x 4 + x 2 -1 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 28. f( x )= x 4 +5 x 3 -2 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 29. f( x )= x 5 + x 4 + x 2 +x+1 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 30. f( x )= x 5 - x 4 + x 3 - x 2 +x-1 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 31. f( x )= x 6 -1 In Problems 21-32, use Descartes' Rule of Signs to determine how many positive and how many negative zeros each polynomial function may have. Do not attempt to find the zeros. 32. f( x )= x 6 +1 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 33. f( x )=3 x 4 -3 x 3 + x 2 -x+1 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 34. f( x )= x 5 - x 4 +2 x 2 +3 In Problems 3344, list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. f(x)=x52x2+8x5 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 36. f( x )=2 x 5 - x 4 - x 2 +1 In Problems 3344, list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. f(x)=9x3x2+x+3 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 38. f( x )=6 x 4 - x 2 +2 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 39. f( x )=6 x 4 - x 2 +9 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 40. f( x )=-4 x 3 + x 2 +x+6 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 41. f( x )=2 x 5 - x 3 +2 x 2 +12 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 42. f( x )=3 x 5 - x 2 +2x+18 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 43. f( x )=6 x 4 +2 x 3 - x 2 +20 In Problems 33-44, determine the maximum number of real zeros that each polynomial function may have. Then list the potential rational zeros of each polynomial function. Do not attempt to find the zeros. 44. f( x )=-6 x 3 - x 2 +x+10 In Problems 51-68, find the real zeros of f. Use the real zeros to factor f 51. f( x )= x 3 +2 x 2 -5x-6 In Problems 51-68, find the real zeros of f. Use the real zeros to factor f 52. f( x )= x 3 +8 x 2 +11x-20 In Problems 4556, use the Rational Zeros Theorem to find all the real zeros of each polynomial function. Use the zeros to factor f over the real numbers. f(x)=2x3x2+2x1 In Problems 4556, use the Rational Zeros Theorem to find all the real zeros of each polynomial function. Use the zeros to factor f over the real numbers. f(x)=2x3+x2+2x+1 In Problems 4556, use the Rational Zeros Theorem to find all the real zeros of each polynomial function. Use the zeros to factor f over the real numbers. f(x)=2x34x210x+20 In Problems 4556, use the Rational Zeros Theorem to find all the real zeros of each polynomial function. Use the zeros to factor f over the real numbers. f(x)=3x3+6x215x30

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