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Reciprocal Functions

Reciprocal Functions. Information. Inverse variation. An airtight 1 dL (deciliter) container with a piston is sealed off, trapping air inside. As the piston is moved, the volume of the container changes. The table shows what happens to the pressure of the trapped air.

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Reciprocal Functions

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  1. Reciprocal Functions

  2. Information

  3. Inverse variation An airtight 1dL (deciliter) container with a piston is sealed off, trapping air inside. As the piston is moved, the volume of the container changes. The table shows what happens to the pressure of the trapped air. What can you say about the product of V and p? Write the function that relates them. Vp =1 p =1/V ⇒ Pressure varies inversely with volume. In inverse variation, the variables have a constant product.

  4. Reciprocal functions Inverse variation is described by reciprocal functions. Plot the data shown in the table and sketch a reciprocal curve to fit the data. p =1/V What is the domain for the sketched curve?

  5. Direct or inverse variation?

  6. Analyzing the parent function 1 f(x) = parent reciprocal function: x vertical asymptote: x =0 f(x)=0 horizontal asymptote: domain: (–∞, 0)∪(0, ∞) range: (–∞, 0)∪(0, ∞) roots: none

  7. Stretching reciprocal functions

  8. Reflecting reciprocal functions

  9. Translating reciprocal functions

  10. Combining transformations

  11. General form a f(x) = + k general reciprocal function: x – h vertical asymptote: x =h horizontal asymptote: f(x)=k (–∞, h)∪(h, ∞) domain: (–∞, k)∪(k, ∞) range: a roots: x = –+ h k

  12. Finding vertical and horizontal asymptotes A vertical asymptote in a reciprocal function occurs where it is undefined – where the denominator is zero. a Show that the vertical asymptote of a general reciprocal function is x = h. f(x) = + k x – h x – h = 0 equate the denominator to zero: x = h solve for x: To understand why a horizontal asymptote occurs, examine the behavior of the function as x becomes very large. a Explain why the horizontal asymptote of a general reciprocal function is y = k. f(x) = + k x – h xis in the denominator, and as the denominator of a fraction become much larger than the numerator, the fraction tends to zero, but does not affect the constant k.

  13. Asymptotes of reciprocal functions

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