Rational Expressions

1. Chapter 6 Rational Expressions

2. Rational Functions and Multiplying and Dividing Rational Expressions § 6.1

3. Rational Expressions Rational expressions can be written in the form where P and Q are both polynomials and Q 0. Examples of Rational Expressions

4. Evaluating Rational Expressions To evaluate a rational expression for a particular value(s), substitute the replacement value(s) into the rational expression and simplify the result. Example: Evaluate the following expression for y = 2.

5. Evaluating Rational Expressions In the previous example, what would happen if we tried to evaluate the rational expression for y = 5? This expression is undefined!

6. Undefined Rational Expressions We have to be able to determine when a rational expression is undefined. A rational expression is undefined when the denominator is equal to zero. The numerator being equal to zero is okay (the rational expression simply equals zero).

7. Undefined Rational Expressions Find any real numbers that make the following rational expression undefined. Example: The expression is undefined when 15x + 45 = 0. So the expression is undefined when x = 3.

8. For any rational expression and any polynomial R, where R ≠ 0, or, simply, Simplifying Rational Expressions Simplifying a rational expression means writing it in lowest terms or simplest form. Fundamental Principle of Rational Expressions

9. Simplifying Rational Expressions Simplifying a Rational Expression 1) Completely factor the numerator and denominator of the rational expression. 2) Divide out factors common to the numerator and denominator. (This is the same thing as “removing the factor of 1.”) Warning! Only common FACTORS can be eliminated from the numerator and denominator. Make sure any expression you eliminate is a factor.

10. Simplifying Rational Expressions Example: Simplify the following expression.

11. Simplifying Rational Expressions Example: Simplify the following expression.

12. Simplifying Rational Expressions Example: Simplify the following expression.

13. Multiplying Rational Expressions Multiplying Rational Expressions The rule for multiplying rational expressions is as long as Q  0 and S  0. 1) Completely factor each numerator and denominator. 2) Use the rule above and multiply the numerators and denominators. 3) Simplify the product by dividing the numerator and denominator by their common factors.

14. Multiplying Rational Expressions Example: Multiply the following rational expressions.

15. Multiplying Rational Expressions Example: Multiply the following rational expressions.

16. Dividing Rational Expressions Dividing Rational Expressions The rule for dividing rational expressions is as long as Q  0 and S  0 and R  0. To divide by a rational expression, use the rule above and multiply by its reciprocal. Then simplify if possible.

17. Dividing Rational Expressions Example: Divide the following rational expression.

18. § 6.2 Adding and Subtracting Rational Expressions

19. Adding and Subtracting with Common Denominators The rule for multiplying rational expressions is Adding or Subtracting Rational Expressions with Common Denominators are rational expression, then

20. Add the following rational expressions. Adding Rational Expressions Example:

21. Subtract the following rational expressions. Subtracting Rational Expressions Example:

22. Subtract the following rational expressions. Subtracting Rational Expressions Example:

23. To add or subtract rational expressions with unlike denominators, you have to change them to equivalent forms that have the same denominator (a common denominator). This involves finding the least common denominator of the two original rational expressions. Least Common Denominators

24. Finding the Least Common Denominator 1) Factor each denominator completely, 2) The LCD is the product of all unique factors each raised to a power equal to the greatest number of times that the factor appears in any factored denominator. Least Common Denominators

25. Find the LCD of the following rational expressions. Least Common Denominators Example:

26. Find the LCD of the following rational expressions. Least Common Denominators Example:

27. Find the LCD of the following rational expressions. Least Common Denominators Example:

28. Find the LCD of the following rational expressions. Least Common Denominators Example: Both of the denominators are already factored. Since each is the opposite of the other, you can use either x – 3 or 3 – x as the LCD.

29. To change rational expressions into equivalent forms, we use the principal that multiplying by 1 (or any form of 1), will give you an equivalent expression. Multiplying by 1

30. Rewrite the rational expression as an equivalent rational expression with the given denominator. Equivalent Expressions Example:

31. As stated in the previous section, to add or subtract rational expressions with different denominators, we have to change them to equivalent forms first. Unlike Denominators

32. Adding or Subtracting Rational Expressions with Unlike Denominators Find the LCD of the rational expressions. Write each rational expression as an equivalent rational expression whose denominator is the LCD found in Step 1. Add or subtract numerators, and write the result over the denominator. Simplify resulting rational expression, if possible. Unlike Denominators

33. Add the following rational expressions. Adding with Unlike Denominators Example:

34. Subtract the following rational expressions. Subtracting with Unlike Denominators Example:

35. Subtract the following rational expressions. Subtracting with Unlike Denominators Example:

36. Add the following rational expressions. Adding with Unlike Denominators Example:

37. § 6.3 Simplifying Complex Fractions

38. Complex Rational Fractions Complex rational expressions (complex fraction) are rational expressions whose numerator, denominator, or both contain one or more rational expressions. There are two methods that can be used when simplifying complex fractions.

39. Simplifying a Complex Fraction(Method 1) Simplify the numerator and the denominator of the complex fraction so that each is a single fraction. Perform the indicated division by multiplying the numerator of the complex fraction by the reciprocal of the denominator of the complex fraction. Simplify, if possible. Simplifying Complex Fractions

40. Simplifying Complex Fractions Example:

41. Simplifying a Complex Fraction(Method 2) Multiply the numerator and the denominator of the complex fraction by the LCD of the fractions in both the numerator and denominator. Simplify, if possible. Simplifying Complex Fractions

42. Simplifying Complex Fractions Example:

43. When you have a rational expression where some of the variables have negative exponents, rewrite the expression using positive exponents. The resulting expression is a complex fraction, so use either method to simplify the expression. Simplifying with Negative Exponents

44. Simplifying with Negative Exponents Example:

45. § 6.4 Dividing Polynomials: Long Division and Synthetic Division

46. Dividing a Polynomial by a Monomial Dividing a Polynomial by a Monomial Divide each term in the polynomial by the monomial. Example: Divide

47. Dividing a Polynomial by a Monomial Example: Divide

48. Dividing a polynomial by a polynomial other than a monomial uses a “long division” technique that is similar to the process known as long division in dividing two numbers, which is reviewed on the next slide. Dividing Polynomials

49. Dividing Polynomials We then write our result as Divide 43 into 72. Multiply 1 times 43. Subtract 43 from 72. Bring down 5. Divide 43 into 295. Multiply 6 times 43. Subtract 258 from 295. Bring down 6. Divide 43 into 376. Multiply 8 times 43. Subtract 344 from 376. Nothing to bring down.

50. Dividing Polynomials As you can see from the previous example, there is a pattern in the long division technique. Divide Multiply Subtract Bring down Then repeat these steps until you can’t bring down or divide any longer. We will incorporate this same repeated technique with dividing polynomials.