Basic roperties of Rational Epressions A rational epression is any epression of the form Q where and Q are polynomials and Q 0. In the following properties, no denominator is allowed to be zero. The Domain of a Rational Function: Unless we are told otherwise, we assume that the domain of a function is the set of all real numbers for which the function is defined. A rational epression is undefined when the denominator is zero. Hence when you need to find the domain of a rational function, you need to determine all values (if any) which cause the denominator to be zero. Eamples: Find the domain of the following functions: Basic roperty: Eample: f() + 4 g() + 4 Q R S if and only if S Q R 6 9 c) h() + 4 d) F() + 9 Q R Q R Q Q Q Q Q Q Q Q 4 4 0 7 4 7 4 7 4 7 4 8 8 8 8 Solution: R (all real numbers) { ε R 4 } (all real numbers ecept 4) c) { ε R 0,, } (all real numbers ecept 0,, ) d) R (all real numbers) Notice that. Multiplication and Division of Rational Epressions Since it is true that It must also be true that a ( + (a ), a a. WARNING: You must reduce only factors!! If the terms are not factors, they cannot be factored out. Nonsense like "canceling out" nonfactors will not be tolerated!! To multiply two rational epression, multiply the numerators and multiply the denominators. Q R S R Q S. To divide two rational epressions, invert the one immediately after the division sign, and do a rational epression multiplication. Q R S Q S R S Q R Eample: erform the indicated operation and simplify: + 0 4 + 9 + + 8 + 4 + 0 4 + 9 + 9 + ( + )( ) ( )( + ) ( ) ( + ) ( + )( ) ( ) ( + ) ( + )
Rule for Adding or Subtracting Fractions with Equal Denominators (RASFED) To add or subtract two rational epressions whose denominators are equal, simply add or subtract the numerators. Make sure you use parentheses when appropriate! Rule for Adding or Subtracting Fractions with Unequal Denominators (FLEAS). Factor the rational epression. Q + R Q + R Q Q R Q R Q. Find the Least Common Denominator (LCD). Eamples: erform the indicated operation and simplify: 4 + 4 4 4 4. Equalize each denominators by replacing each fraction with an equivalent one whose denominator is the LCD. 4. Add or Subtract using RASFED. + 4 + ( + )( ) (4 ) 4 4 + 4 4 4 Eample: + 4 6 8 + 9 ( ) ( + )( ) 6 8 + 9 ( + ) 7 Finding the LCD Step. Factor each denominator completely, including the prime factors of any constant factor. Eamples: erform the indicated operation and simplify. + + + + 4 Step. Form the product of all the factors that appears in the complete factorizations. Step. The number of times any factors appears in the LCD is the most number of times it appears in any one factorization. Eamples: Find the LCD for the given denominators: Denominators are 4, 0, and 6 4 8 0 6 6 4 9 LCD 60 Denominators are and ( ) ( ) ( + )( ) LCD ( + )( ) ( + )( ) ( + ) ( + ) ( + ) ( ) ( + ) ( ) ( + ) ( ) ( + ) ( ) + + ( + ) ( ) + ( + ) ( ) + + ( + )( ) ( + ) ( + )( ) + ( + )( ) ( + 4 + 4) ( + ) ( + )( ) + 4 + 4 ( + )( ) + 4 ( + )( ) ( + ) ( + )( ) ( )
Comple Fractions A simple fraction is any rational epression whose numerator and denominator contain no rational epression. A comple fraction is any rational epression whose numerator or denominator contains a rational epression. To simplify comple fractions: Step : Identify all fractions in the numerator and denominator and find the LCD. Step : Multiply the numerator and denominator by the LCD. Eamples: 4 6 4 6 6 4 9 7 y + y + y + y + y y ( + y) y + y y ( + y) y + Long Division of olynomials Monomial Denominator: When you divide a polynomial by a monomial, you use a form of the distributive property, and thus you must divide each term in the numerator by the denominator Eamples: erform the indicated operation. ( 6 + ) 6 + 6 + + Divide y +0y y by y y + 0y y y y y + 0y y y + 4y y y c) (6 8 + ) d) (6z 4 +6z +8z +64z) 8z Eample: Simplify the following: Long Division of olynomials 9 y y + h h olynomial Denominator: When you divide a polynomial by a polynomial, you can use the same form of long division that you used with numbers. You must remember to write polynomials in descending order and account for zero coefficients. It is convenient to remember that one can subtract a quantity by changing its sign and then adding. y y 9 y y 9y y y (y + )(y ) y(y ) y + y ( + h) + h ( + h) h ( + h) ( + h) h h ( + h) h h ( + h) h ( + h) Step. Write the division as in arithmetic. Write both polynomials in descending order and write all missing terms with a coefficient of zero. Set the current term to be the first one. Step. a. Divide the first term of the divisor into the current term of the dividend. The result is the current term of the quotient. b. Multiply every term in the divisor by the result and write the product under the dividend (align like terms). c. Subtract. [You may reverse the signs and then add.] Treat the difference as a new dividend. Step. If the remainder is a polynomial of degree greater than or equal to the degree of the divisor, then go to step. Otherwise (the remainder is zero or is a polynomial of degree less than the degree of the divisor) go on to step 4. Step 4. If there is a remainder, write it as the numerator of a fraction with the divisor as the denominator, and add this fraction to the quotient. Note: Division by polynomials can be remembered by DMS because you have to Divide, Multiply, Subtract, and then repeat.
Eamples: Calculate the indicated quotients by long division: 7 + + Eamples: Calculate the indicated quotients by synthetic division: 7 + + 4 8 8 + 4 8 8 c) 64 + 9 + 4 c) 4 8 + Synthetic Division of olynomials When you divide a polynomial by a first degree polynomial with linear coefficient, we can perform the division by using only the necessary coefficients. Step. Write the opposite of the constant term of the divisor by itself. Write all of the coefficient of the dividend (using zero when terms are missing, of course). Remainder Theorem When you divide a polynomial () by a the factor c, the remainder is (c). Thus we sometimes evaluate a polynomial () when c by performing the appropriate synthetic division. Eamples : Let () 4 +. By direct substitution, evaluate (). Step. Bring down the first term of the dividend. This also becomes the current term. Find the remainder when () is divided by. Step. a. Multiply the current term by the divisor term. b. ut the product under the net term of the dividend. c. Add the result. The result becomes the current term. Step 4. If there is another term of the dividend, then go to Step. Otherwise, go to Step. Eamples : Let () 4 6 + 4 + 7. Find (4) Step. The constants of the bottom line are the coefficients of the quotient and the remainder.
Equations Involving Fractions When we solve equations with fractions, we always assume that no denominator is zero. Therefore, we can find the LCD and multiply both sides by this nonzero factor. We must check to see that our solution does not cause any denominator to be zero. To solve equations with (simple) fractions: Step : Identify all fractions in the equation and find the LCD. Step : Multiply the both sides of the equation by the LCD. Step : Solve the resulting equation. Step 4: Check the answer into the original problem. (At least check to make sure no denominator can be zero.) WARNING: You must know the difference between an epression and an equation. When you solve an equation, you may multiply both sides by the LCD and we get an equation without fractions. When you have an epression with fractions, you must perform the indicated operation and / or simplify. Nonsense like treating epressions like equations will not be tolerated!! c) y y y 9 y y (y + )(y ) (y + )(y ) y y (y + )(y ) (y + )(y ) (y + )(y ) (y + )(y ) d) y + y 6 y 9 y 4 + ( + )( ) + ( ) ( + )( ) ( + )( ) ( + )( ) + ( ) ( + )( ) + ( + ) 4 + + + 4 no solution Eamples: Solve the following: ( 6)( 8) 6 8 6 ( 6)( 8) 8 ( 8) ( 6) 6 8 z 4 z z z z 4 z z z 4 z(z ) z z 4 z (z ) z (z ) z 4 z(z ) z (z ) z z 4 z(z 4) z(z ) (z ) 4 z 4z z z z + 4 4 z 4z z 4z 0 0 all real numbers ecept 0, z (z ) e) + 0 + + ( + )( + ) 0 + + ( + )( + ) + ( + )( + ) + 0( + ) ( + ) ( + + 6) + 0 + 0 + 6 + 0 + + 0 + 0 + 6 + 7 + 6 0 ( + 9)( + 4) 0 9/, 4 f) y + y + + y + y + 6y + y + y 6 y + (y + )(y ) y + + y + y (y + )(y ) 6y + + (y+)(y) (y )(y + ) + (y + )(y + ) (y + )(y ) + (6y + ) y y + y + 8y + y + y 6 + 6y + y + 7y + y + 7y + 7 y 4 y ± y
Eample: It takes Rosa, traveling at 0 mph, 4 minutes longer to go a certain distance than it takes Maria traveling at 60 mph. Find the distance traveled. Eample: Toni needs 4 hours to complete the yard work. Her husband, Sonny, needs 6 hours to do the work. How long will the job take if they work? distance rate time Rosa 0 Toni Sonny 4 hours 6 hours hours Maria 60 4 + 6 0 60 4 4 + 6 00 0 60 00 4 6 80 + 80 hours 4 minutes 80 miles Eample: Beth can travel 08 miles in the same length of time it takes Anna to travel 9 miles. If Beth s speed is 4 mph greater than Anna s, find both rates. Eample: Working, Rick and Rod can clean the snow from the driveway in 0 minutes. It would have taken Rick, working alone, 6 minutes. How long would it have taken Rod alone? distance rate time Beth 08 + 4 Rick Rod 6 minutes minutes 0 minutes Anna 9 6 + 0 08 + 4 9 80 6 + 80 0 ( + 4) 08 + 4 ( + 4) 08 + 4 08 9( + 4) 08 9 + 768 6 768 48 + 80 9 80 4 4 4 minutes Beth mph Anna 48 mph
Eample: John, Ralph, and Denny, working, can clean a store in 6 hours. Working alone, Ralph takes twice as long to clean the store as does John. Denny needs three times as long as does John. How long would it take each man working alone? Eample: You can row, row, row your boat on a lake miles per hour. On a river, it takes you the same time to row miles downstream as it does to row miles upstream. What is the speed of the river current in miles per hour? John Ralph Denny hours hours hours 6 hours distance rate time downstream + 6 + + + + 6 6 6 6 + + John minutes Ralph minutes Denny minutes upstream ( + )( ) + + ( + )( ) ( ) ( + ) + 0 8 4 4 mph Eample: An inlet pipe on a swimming pool can be used to fill the pool in hours. The drain pipe can be used to empty the pool in 0 hours. If the pool is empty and the drain pipe is accidentally opened, how long will it take to fill the pool? inlet pipe drain pipe hours 0 hours hours 0 60 0 60 60 60 0 0 hours