Presentation is loading. Please wait.

Presentation is loading. Please wait.

Section 4.1 Polynomial Functions. A polynomial function is a function of the form a n, a n-1,…, a 1, a 0 are real numbers n is a nonnegative integer D:

Published byMercy McGee Modified over 9 years ago

Similar presentations

Presentation on theme: "Section 4.1 Polynomial Functions. A polynomial function is a function of the form a n, a n-1,…, a 1, a 0 are real numbers n is a nonnegative integer D:"— Presentation transcript:

1 Section 4.1 Polynomial Functions

2 A polynomial function is a function of the form a n, a n-1,…, a 1, a 0 are real numbers n is a nonnegative integer D: {x|x å real numbers} Degree is the largest power of x

3 Example: Determine which of the following are polynomials. For those that are, state the degree.

4 A power function of degree n is a function of the form where a is a real number a = 0 n > 0 is an integer.

5 (1, 1)(-1, 1) (0, 0) Power Functions with Even Degree

6 Summary of Power Functions with Even Degree 1.) Symmetric with respect to the y-axis. 2.) D: {x|x is a real number} R: {x|x is a non negative real number} 3.) Graph (0, 0); (1, 1); and (-1, 1). 4.) As the exponent increases, the graph increases very rapidly as x increases, but for x near the origin the graph tends to flatten out and lie closer to the x-axis.

7 (1, 1) (-1, -1) (0, 0) Power Functions with Odd Degree

8 Summary of Power Functions with Odd Degree 1.) Symmetric with respect to the origin. 2.) D: {x|x is a real number} R: {x|x is a real number} 3.) Graph contains (0, 0); (1, 1); and (-1, -1). 4.) As the exponent increases, the graph becomes more vertical when x > 1 or x < -1, but for -1 < x < 1, the graphs tends to flatten out and lie closer to the x-axis.

9 Graph the following function using transformations. (0,0) (1,1) (0,0) (1, -2)

10 (1,0) (2,-2) (1, 4) (2, 2)

11 If r is a Zero of Even Multiplicity Graph crosses x-axis at r. If r is a Zero of Odd Multiplicity Graph touches x-axis at r.

12 For the polynomial  fxxxx()  154 2 (a) Find the x- and y-intercepts of the graph of f. The x intercepts (zeros) are (-1, 0), (5,0), and (-4,0) To find the y - intercept, evaluate f(0) So, the y-intercept is (0,-20)

13 For the polynomial  fxxxx()  154 2 b.) Determine whether the graph crosses or touches the x-axis at each x-intercept. x = -4 is a zero of multiplicity 1 (crosses the x-axis) x = -1 is a zero of multiplicity 2 (touches the x-axis) x = 5 is a zero of multiplicity 1 (crosses the x-axis) c.) Find the power function that the graph of f resembles for large values of x.

14 d.) Determine the maximum number of turning points on the graph of f. At most 3 turning points. e.) Use the x-intercepts and test numbers to find the intervals on which the graph of f is above the x-axis and the intervals on which the graph is below the x-axis. On the interval Test number: x = -5 f (-5) = 160 Graph of f: Above x-axis Point on graph: (-5, 160) For the polynomial  fxxxx()  154 2

15  fxxxx()  154 2 On the interval Test number: x = -2 f (-2) = -14 Graph of f: Below x-axis Point on graph: (-2, -14) On the interval Test number: x = 0 f (0) = -20 Graph of f: Below x-axis Point on graph: (0, -20)

16 For the polynomial  fxxxx()  154 2 On the interval Test number: x = 6 f (6) = 490 Graph of f: Above x-axis Point on graph: (6, 490) f.) Put all the information together, and connect the points with a smooth, continuous curve to obtain the graph of f.

17 (6, 490) (5, 0) (0, -20) (-1, 0) (-2, -14) (-4, 0) (-5, 160)

18 Sections 4.2 & 4.3 Rational Functions 28

19 A rational function is a function of the form p and q are polynomial functions q is not the zero polynomial. D: {x|x å real numbers & q(x) = 0}.

20 Find the domain of the following rational functions. All real numbers x except -6 and -2. All real numbers x except -4 and 4. All Real Numbers 30

21 Vertical Asymptotes. Domain gives vertical asymptotes Reduce rational function to lowest terms, to find vertical asymptote(s). The graph of a function will never intersect vertical asymptotes. Describes the behavior of the graph as x approaches some number c Range gives horizontal asymptotes The graph of a function may cross intersect horizontal asymptote(s). Describes the behavior of the graph as x approaches infinity or negative infinity (end behavior) 31

22 Example: Find the vertical asymptotes, if any, of the graph of each rational function. Vertical asymptotes: x = -1 and x = 1 No vertical asymptotes Vertical asymptote: x = -4 32

23 (3,2) (1,0) (2,0) (0,1) In this example there is a vertical asymptote at x = 2 and a horizontal asymptote at y = 1.

24 Examples of Horizontal Asymptotes y = L y = R(x) y x y = L y = R(x) y x

25 Examples of Vertical Asymptotes x = c y x y x

26 If an asymptote is neither horizontal nor vertical it is called oblique. y x Note: a graph may intersect it’s oblique asymptote. Describes end behavior. More on this in Section 3.4.

27 Recall that the graph of is (1,1) (-1,-1) 37

28 Graph the function using transformations (1,1) (-1,-1) (3,1) (1,-1) (2,0) (3,2) (1,0) (2,0) (0,1)

29 Consider the rational function 1. If n < m, then y = 0 is a horizontal asymptote 2. If n = m, then y = a n / b m is a horizontal asymptote 3. If n = m + 1, then y = ax + b is an oblique asymptote, found using long division. 4. If n > m + 1, neither a horizontal nor oblique asymptote exists. 39

30 Example: Find the horizontal or oblique asymptotes, if any, of the graph of Horizontal asymptote: y = 0 Horizontal asymptote: y = 2/3

31 Oblique asymptote: y = x + 6

32 To analyze the graph of a rational function: 1) Find the Domain. 2) Locate the intercepts, if any. 3) Test for Symmetry. If R(-x) = R(x), there is symmetry with respect to the y-axis. If - R(x) = R(-x), there is symmetry with respect to the origin. 4) Find the vertical asymptotes. 5) Locate the horizontal or oblique asymptotes. 6) Determine where the graph is above the x-axis and where the graph is below the x-axis. 7) Use all found information to graph the function. 42

33 Example: Analyze the graph of

34 a.) x-intercept when x + 1 = 0: (-1,0) b.) y-intercept when x = 0: y - intercept: (0, 2/3) c.) Test for Symmetry: No symmetry

35 d.) Vertical asymptote: x = -3 Since the function isn’t defined at x = 3, there is a hole at that point. e.) Horizontal asymptote: y = 2 f.) Divide the domain using the zeros and the vertical asymptotes. The intervals to test are:

36 Test at x = -4 R(-4) = 6 Above x-axis Point: (-4, 6) Test at x = -2 R(-2) = -2 Below x-axis Point: (-2, -2) Test at x = 1 R(1) = 1 Above x-axis Point: (1, 1) g.) Finally, graph the rational function R(x)

37 (-4, 6) (-2, -2) (-1, 0)(0, 2/3) (1, 1)(3, 4/3) y = 2 x = - 3

Download ppt "Section 4.1 Polynomial Functions. A polynomial function is a function of the form a n, a n-1,…, a 1, a 0 are real numbers n is a nonnegative integer D:"

Similar presentations

3.4 Rational Functions I. A rational function is a function of the form Where p and q are polynomial functions and q is not the zero polynomial. The domain.

3.4 Rational Functions I. A rational function is a function of the form Where p and q are polynomial functions and q is not the zero polynomial. The domain.
Section 5.3 – The Graph of a Rational Function

Section 5.3 – The Graph of a Rational Function
Section 5.1 – Polynomial Functions Defn: Polynomial function The coefficients are real numbers. The exponents are non-negative integers. The domain of.

Section 5.1 – Polynomial Functions Defn: Polynomial function The coefficients are real numbers. The exponents are non-negative integers. The domain of.
Rational Functions I; Rational Functions II – Analyzing Graphs

Rational Functions I; Rational Functions II – Analyzing Graphs
3.5 - 1 Rational function A function  of the form where p(x) and q(x) are polynomials, with q(x) ≠ 0, is called a rational function.

Rational function A function  of the form where p(x) and q(x) are polynomials, with q(x) ≠ 0, is called a rational function.
Math 139 – The Graph of a Rational Function 3 examples General Steps to Graph a Rational Function 1) Factor the numerator and the denominator 2) State.

Math 139 – The Graph of a Rational Function 3 examples General Steps to Graph a Rational Function 1) Factor the numerator and the denominator 2) State.
Rational Functions Sec. 2.7a. Definition: Rational Functions Let f and g be polynomial functions with g (x ) = 0. Then the function given by is a rational.

Rational Functions Sec. 2.7a. Definition: Rational Functions Let f and g be polynomial functions with g (x ) = 0. Then the function given by is a rational.
LIAL HORNSBY SCHNEIDER

LIAL HORNSBY SCHNEIDER
Section 5.2 – Properties of Rational Functions

Section 5.2 – Properties of Rational Functions
4.4 Rational Functions Objectives:

4.4 Rational Functions Objectives:
Rational Functions Find the Domain of a function

Rational Functions Find the Domain of a function
POLYNOMIALS.

POLYNOMIALS.
Polynomial and Rational Functions

Polynomial and Rational Functions
Sullivan PreCalculus Section 3.2 Polynomial Functions

Sullivan PreCalculus Section 3.2 Polynomial Functions
College Algebra Sixth Edition James Stewart Lothar Redlin Saleem Watson.

College Algebra Sixth Edition James Stewart Lothar Redlin Saleem Watson.
Analyzing Polynomial & Rational Functions & Their Graphs Steps in Analysis of Graphs of Poly-Rat Functions 1)Examine graph for the domain with attention.

Analyzing Polynomial & Rational Functions & Their Graphs Steps in Analysis of Graphs of Poly-Rat Functions 1)Examine graph for the domain with attention.
Sullivan PreCalculus Section 3

Sullivan PreCalculus Section 3
Polynomials and Rational Functions (2.1)

Polynomials and Rational Functions (2.1)
By Noureen Villamar Melissa Motieram Elizabeth Stasiak Period B.

By Noureen Villamar Melissa Motieram Elizabeth Stasiak Period B.
Write the equation for transformation of.

Write the equation for transformation of.

Similar presentations

Ads by Google