1.2 Describing end behavior of polynomial and rational functions

    Cards (59)

    • Steps to determine the end behavior of a polynomial function
      1️⃣ Identify the degree of the polynomial
      2️⃣ Identify the leading coefficient
      3️⃣ Use the degree and leading coefficient to describe the end behavior
    • Match the degree and leading coefficient with the correct end behavior:
      Even degree, Negative leading coefficient ↔️ Both ends approach -∞
      Odd degree, Negative leading coefficient ↔️ Left: ∞, Right: -∞
    • What is the degree and leading coefficient of 3x45x2+3x^{4} - 5x^{2} +2x7 2x - 7?

      Degree: 4, Coefficient: 3
    • What determines the end behavior of a rational function?
      Horizontal asymptotes
    • The end behavior of a rational function is determined by the presence of horizontal asymptotes
    • When the degree of the numerator is greater than the degree of the denominator, there is no horizontal asymptote.

      True
    • If the degree of a polynomial is even and the leading coefficient is positive, both ends approach positive infinity
    • The degree of a polynomial is the highest power of x
    • Describe the end behavior of the polynomial f(x)=f(x) =2x35x+ 2x^{3} - 5x +1 1.

      f(x)f(x) \to - \infty as xx \to - \infty and f(x)f(x) \to \infty as xx \to \infty
    • For f(x)=f(x) = \frac{3x^{2} + 1}{x^{2} - 4}, the horizontal asymptote is 3
    • The degree of the denominator in a rational function is the highest power of x
    • Match the degree and leading coefficient with the correct end behavior:
      Even, Positive ↔️ f(x)f(x) \to \infty as x±x \to \pm \infty
      Even, Negative ↔️ f(x)f(x) \to - \infty as x±x \to \pm \infty
      Odd, Positive ↔️ f(x)f(x) \to - \infty as xx \to - \infty and f(x)f(x) \to \infty as xx \to \infty
      Odd, Negative ↔️ f(x)f(x) \to \infty as xx \to - \infty and f(x)f(x) \to - \infty as xx \to \infty
    • For the polynomial f(x) = 2x^{3} - 5x + 1</latex>, what is its degree?
      3
    • What is the horizontal asymptote when the degree of the numerator is less than the degree of the denominator?
      y=y =0 0
    • If the degree of the numerator is less than the degree of the denominator, the horizontal asymptote is y=y =0 0.

      True
    • For f(x)=f(x) = \frac{3x^{2} + 1}{x^{2} - 4}, the horizontal asymptote is y=y =3 3.

      True
    • What is the degree of the numerator in a rational function?
      Highest power of xx
    • For polynomial functions, the end behavior depends on the degree and the leading coefficient.
    • What is the end behavior of f(x)=f(x) =3x42x+ 3x^{4} - 2x +1 1?

      f(x)f(x) \to \infty as x±x \to \pm \infty
    • What happens to the end behavior of a rational function if the degree of the numerator is greater than the denominator?
      f(x)f(x) increases or decreases without bound
    • The end behavior of a polynomial function is determined by the leading coefficient and the degree
    • What is the end behavior of a polynomial with an odd degree and a positive leading coefficient?
      Left: -∞, Right: ∞
    • The leading coefficient is the coefficient in front of the term with the highest power of x
    • A polynomial with an odd degree and a negative leading coefficient approaches positive infinity on the left and negative infinity on the right.
      True
    • What does the end behavior of a rational function describe?
      Behavior as x±x \to \pm \infty
    • What is the horizontal asymptote when the degrees of the numerator and denominator are equal?
      y=y =leading coefficient of numeratorleading coefficient of denominator \frac{\text{leading coefficient of numerator}}{\text{leading coefficient of denominator}}
    • What determines the end behavior of a polynomial function?
      Degree and leading coefficient
    • Match the degree and leading coefficient with the corresponding end behavior:
      Even degree, positive leading coefficient ↔️ f(x)f(x) \to \infty as x±x \to \pm \infty
      Even degree, negative leading coefficient ↔️ f(x)f(x) \to - \infty as x±x \to \pm \infty
      Odd degree, positive leading coefficient ↔️ f(x)f(x) \to - \infty as xx \to - \infty and f(x)f(x) \to \infty as xx \to \infty
    • For the polynomial 3x45x2+3x^{4} - 5x^{2} +2x7 2x - 7, the degree is 44 and the leading coefficient is 33.

      True
    • Identifying the degrees of the numerator and denominator is crucial for determining the end behavior of rational functions.

      True
    • What is the degree of the numerator in a rational function?
      The highest power of x
    • What is the end behavior of an even degree polynomial with a positive leading coefficient?
      f(x)f(x) \to \infty as x±x \to \pm \infty
    • The leading coefficient is the coefficient of the term with the highest power of xx.

      True
    • Match the degree comparison with the correct end behavior of rational functions:
      Numerator < Denominator ↔️ f(x)0f(x) \to 0 as x±x \to \pm \infty
      Numerator = Denominator ↔️ f(x)yf(x) \to y as x±x \to \pm \infty
      Numerator > Denominator ↔️ f(x)f(x) \to \infty or f(x)f(x) \to - \infty as x±x \to \pm \infty
    • What guides the end behavior of rational functions?
      Horizontal asymptotes
    • What happens to the end behavior of a rational function if the degree of the numerator is greater than the degree of the denominator?
      f(x)f(x) \to \infty or f(x)f(x) \to - \infty
    • Match the degree comparison with the correct horizontal asymptote and end behavior:
      Numerator < Denominator ↔️ y=y =0 0 and f(x)0f(x) \to 0
      Numerator = Denominator ↔️ y=y =leading coefficient of numeratorleading coefficient of denominator \frac{\text{leading coefficient of numerator}}{\text{leading coefficient of denominator}} and f(x)yf(x) \to y
      Numerator > Denominator ↔️ None and f(x)f(x) \to \infty or f(x)f(x) \to - \infty
    • If the degree of the numerator is less than the denominator, what is the horizontal asymptote?
      y=y =0 0
    • If the degree of the numerator is less than the degree of the denominator, the end behavior is f(x)0f(x) \to 0 as x±x \to \pm \infty.

      True
    • What does the end behavior of a polynomial function describe?
      Function's behavior at infinity
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