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3.1 POLYNOMIAL FUNCTIONS AND MODELS • A polynomial function P is given by P(x) = anxn + an-1xn-1 + … + a1x + a0 where the coefficients are real numbers and the exponents are whole numbers. • The first nonzero coefficient an is called the leading coefficient. The term anxn is called the leading term. The degree of the polynomial functions is n. • Graphical examples seen on page 256. LEADING TERM TEST • If anxn is the leading term of a polynomial function, then the behavior of the graph as x approaches infinity or negative infinity can be described in one of the four following ways • If n is even and an > 0: as x approaches negative infinity, the graph approaches positive infinity and as x approaches positive infinity, the graph approaches positive infinity. • If n is even and an < 0: as x approaches negative infinity, the graph approaches negative infinity and as x approaches positive infinity, the graph approaches negative infinity. • If n is odd and an > 0: as x approaches negative infinity, the graph approaches negative infinity and as x approaches positive infinity, the graph approaches positive infinity. • If n is odd and an < 0: as x approaches negative infinity, the graph approaches positive infinity and as x approaches positive infinity, the graph approaches negative infinity. EVEN AND ODD MULTIPLICITY • If (x – c)k > 1, is a factor of a polynomial function P(x) and (x – c)k+1 is not a factor of P(x) and: • k is odd, then the graph crosses the x-axis at (c,0) • k is even, then the graph is tangent to the x-axis at (c,0) • Every polynomial function of degree n, with n > 1, has at least one zero and at most n zeros. 3.2 GRAPHING POLYNOMIAL FUNCTIONS • If P(x) is a polynomial function of degree n, the graph of the function has: • At most n real zeros, and thus at most n x-intercepts • At most n – 1 turning points • Turning points on a graph also called relative extrema, occur when the function changes from increasing to decreasing or from decreasing to increasing. • Intermediate Value Theorem: • For an polynomial function P(x) with real coefficients, suppose that for a ≠ b, P(a) and P(b) are of opposite signs. Then the function has a real zero between a and b. TO GRAPH A POLYNOMIAL FUNCTION 1. Use the leading-term test to determine the end behavior. 2. Find the zeros of the function by solving f(x) = 0. Any real zeros are the first coordinate of the x-intercepts. 3. Use the x-intercepts (roots) to divide the x-axis into intervals and choose a test point in each interval to determine the sign of all function values in that interval. 4. Find f(0). This gives the y-intercept of the function. 5. If necessary, find the additional function values to determine the general shape of the graph, and then draw the graph. 6. As a partial check, use the facts that the graph has at most n x-intercepts and at most n – 1 turning points. Multiplicity of zeros can also be considered in order to check where the graph crosses or is tangent to the x-axis. HOMEWORK 3.3 POLYNOMIAL DIVISION • Long Division • When we divide one polynomial by another, we obtain a quotient and a remainder. If the remainder is zero, then the divisor is a factor of the dividend. • Example: (2x2 – 5x – 1) / (x – 3) • Answer: 2x + 1 + (2/(x – 3)) SYNTHETIC DIVISION THEOREMS • The Remainder Theorem • If a number c is substituted for x in the polynomial f(x), then the result f(c) is the remainder that would be obtained by dividing f(x) by x – c. That is, if f(x) = (x – c) Q(x) + R, then f(c) = R • The Factor Theorem • For a polynomial f(x), if f(c) = 0, then x – c is a factor of f(x). 3.4 THEOREMS ABOUT ZEROS OF POLYNOMIAL FUNCTIONS • The Fundamental Theorem of Algebra • Every polynomial function of degree n, with n > 1, has at least one zero in the system of complex numbers • Every polynomial function f of degree n, with n > 1, can be factored into n linear factors (not necessarily unique); that is, f(x) = an (x – c1) (x – c2) … (x - cn) • Nonreal Zeros: a + bi and a – bi, b ≠ 0 • If a complex number a + bi, b ≠ 0, is a zero of a polynomial function f(x) with real coefficients, then its conjugate a – bi is also a zero. For example, if 2 + 7i is a zero of a polynomial f(x), with real coefficients, then its conjugate, 2 – 7i is also a zero. (Nonreal zeros occur in conjugate pairs) RATIONAL COEFFICIENTS • Irrational Zeros: a + c√b and a - c√b, b is not a perfect square • If a + c√b where a, b, and c are rational and b is not a perfect square, is a zero of a polynomial function f(x) with rational coefficients, then its conjugate a – b√c is also a zero. For example if -3+ 5√2 is a zero of a polynomial function f(x) with rational coefficients then its conjugate, -3 - 5√2 is also a zero. • The Rational Zeros Theorem • Let P(x) be a polynomial function equal to anxn + an-1xn-1 + … + a1x + a0 where all the coefficients are integers. Consider a rational number denoted by p/q, where p and q are relatively prime (having no common factor besides -1 and 1). If p/q is a zero of P(x), then p is a factor of a0 and q is a factor of an. DESCARTES’ RULES OF SIGNS Let P(x) written in descending or ascending order, be a polynomial function with real coefficients and a nonzero constant term. The number of positive real zeros of P(x) is either: 1. The same as the number of variations of sign in P(x), or 2. Less than the number of variations of sign in P(x) by a positive even integer. The number of negative real zeros of P(x) is either: 3. The same as the number of variations of sign in P(-x) or 4. Less than the number of variations of sign in P(-x) by a positive even integer. A zero of multiplicity m must be counted m times. EXAMPLE P(x) = 5x4 – 3x3 + 7x2 – 12x + 4 There are 4 variations in sign. Thus the number of positive real zeros is either 4 or 4 – 2 or 4 – 4 That is, the number of positive real zeros is either 4, 2, or 0. P(-x) = 5x4 + 3x3 + 7x2 + 12x + 4 There are no changes in sign, so there are no negative real zeros. HOMEWORK 3.5 RATIONAL FUNCTIONS • Rational Functions • A rational function is a function f that is a quotient of two polynomials, that is, f(x) = p(x) / q(x) where p(x) and q(x) are polynomials, and where q(x) is not the zero polynomial. The domain of f consists of all inputs x for which q(x) ≠ 0, and the intersection of the domain of p(x) and q(x). ASYMPTOTES • The line x = a is a vertical asymptote for the graph of f if any of the following are true: f(x) infinity as x a – OR f(x) infinity as x a + f(x) negative infinity as x a – OR f(x) negative infinity as x a + • For a rational function f(x) = p(x) / q(x), where p(x) and q(x) are polynomials with no common factors other than constants, if a is a zero for the denominator, then the line x = a is a vertical asymptote for the graph of the function. • • The line y = b is a horizontal asymptote for the graph of f is f(x) b as x infinity OR f(x) b as x negative infinity BOBOBOTNEATSDC (Degree Check) • Bigger on Bottom y = 0 • Bigger on Top NONE • Each Are The Same Divide Coefficients ASYMPTOTES • Crossing an Asymptote • The graph of a rational function NEVER crosses a vertical asymptote • The graph of a rational function MIGHT cross a horizontal asymptote but does not necessarily do so (end behavior) • Sometimes a line that is neither vertical nor horizontal is an asymptote. • These are referred to as a slant or oblique asymptote • You can find these by dividing the polynomial function • Long Division or when applicable Synthetic Division • They only occur when there is NO horizontal asymptote. OCCURRENCE OF LINES AS ASYMPTOTES OF RATIONAL FUNCTIONS For a rational function f(x) = p(x) / q(x), where p(x) and q(x) have no common factors other than constants: Vertical Asymptotes occur at any x-values that make the denominator 0. The x-axis is the horizontal asymptote when the degree on bottom is bigger. A horizontal asymptote other than y = 0 occurs when the degrees are equal. An oblique asymptote occurs when the degree of the numerator is one greater than the degree of the denominator. There can be only one horizontal asymptote or one oblique asymptote: NEVER BOTH An asymptote is not part of the graph of the function. PROCEDURE FOR GRAPHING To graph a rational function f(x) = p(x)/q(x), where p(x) and q(x) have no common factors other than constants (other common factors means a hole): 1. Find the real zeros of the denominator. Determine the domain of the function and sketch any vertical asymptotes. 2. Find the horizontal or oblique asymptote, if there is one then sketch it. 3. Find the zeros of the function. The zeros are found by determining the zero of the numerator. These are the first coordinates of the x-intercepts of the graph. 4. Find f(0). This gives the y-intercept (0, f(0) ), of the function. 5. Find other function values to determine the general shape. Then draw the graph. 3.6 POLYNOMIAL AND RATIONAL INEQUALITIES Just as quadratic equation can be written in the form ax 2 + bx + c = 0, a quadratic inequality can be written in the same manner but instead of an “=“ there would be a <, <, >, or >. Quadratic inequalities are one type of polynomial inequalities. When the inequality symbol in a polynomial inequality is replaced with an equals sign, a related equation is formed. To solve a polynomial inequality: 1. Find an equivalent inequality with 0 on one side. 2. Solve the related polynomial equation, that is f(x) = 0. 3. Use the solutions to divide the x-axis into intervals. Then select a test value from each interval and determine the polynomial’s sign on the interval. 4. Determine the intervals for which the inequality is satisfied and write interval notation or set-builder notation for the solution set. Include the endpoints when the inequality is an “or equal to” sign. RATIONAL INEQUALITY Some inequalities involve rational expressions and functions. These are called rational inequalities. To solve a rational inequality: 1. Find an equivalent inequality with 0 on one side. 2. Change the inequality symbol to an equals sign and solve the related equation, that is f(x) = 0. 3. Find the values of the variable for which the related rational function is not defined. 4. The numbers found in steps 2 and 3 are called critical values. Use the critical value to divide the x-axis into intervals. Then test an x-value from each interval to determine the function’s sign in that interval. 5. Select the intervals for which the inequality is satisfied and write interval notation or set-builder notation for the solution set. If the inequality symbol “or equal to” is used, then the solutions to step 2 and 3 should be included. The x-values found in step 3 are NEVER included in the solution set. HOMEWORK 3.7 VARIATION AND APPLICATIONS Direct Variation: Whenever a situation produces pairs of numbers in which the ratio is constant, we say that there is direct variation. If a situation gives rise to a linear functin f(x) = kx or y = kx, where k is a positive constant, we say that we have direct variation or that y varies directly as x or y is directly proportional to . The number k is called the variation constant or constant of proportionality. INVERSE VARIATION Inverse Variation: Whenever a situation produces pairs of numbers in which the product is constant, we say that there is a inverse variation. If a situation gives rise to a function f(x) = k/x or y = k/x, where k is a positive constant, we say that we have inverse variation or that y varies inversely as x or that y is inversely proportional to x. The number k is called the variation constant or the constant of proportionality. COMBINED VARIATION We now look at other kinds of variation: • y varies directly as the nth power of x if there is some positive constant k such that y = kxn • y varies inversely as the nth power of x if there is some positive constant k such that y = k/xn • y varies jointly as x and z if there is some positive constant k such that y = kxz