Transcript
Part 1: Addition and Subtraction Consider simplifying the following rational expression:
1π₯ + 1β
6π₯! + 2π₯ + 1+
1π₯! β 1
Letβs begin by recalling our approach with expressions that only involve numbers. We know that in order to add or subtract fractions,
we must first have a common denominator. Below is a common property to help achieve that goal:
!!Β± !
!= !"Β±!"
!" (Property 1)
Although this property guarantees that we get a common denominator, we may
or may not have found the Least Common Denominator (LCD). So, in a moment, we will explore how to find it since LCDs have the potential to drastically simplify our computations later on.
Consider the following difference: !!!"β !
!"
Using the above property, we have:
1112β
710 =
11 10 β 7(12)12(10)
= 110β 84
120
= 26
120
= 13
60
Notice that 120 is twice as large as the reduced denominator of 60! If you found it obvious that the LCD was 60, note that the LCD is not always so easy to identify.
Simplifying Rational Expressions
By: Saβdiyya Hendrickson
Strategy #1
Since LCDs, in general, may not be so easy to spot, letβs try to develop a strategic approach to finding them!
Step 1: Factor each denominator (π·! and π·!). In other words, express π·! and π·! as a product of their prime factors (i.e. the βpartsβ that make them).
For example:
π·!: 12 = 2! β 3! π·!: 36 = 2! β 5! Step 2: Construct the LCD by multiplying together the highest power of each prime that appears among the denominators.
LCD = 2! β 3! β 5! = 60 Step 3: Multiply each fractionβs numerator and denominator by the prime factors missing in its denominator and simplify the expression.
112! β 3!
55 β
72! β 5!
2 β 32 β 3 =
11 5 β 7 2 β 32! β 3! β 5!
=55β 4260
=1360
Remember: Every step has a purpose!
Strategy #2
Why? So that we can easily see the minimum requirements needed in order to βincludeβ every denominator in the LCD.
Why? We know that every denominator must be a factor of the LCD, so by taking the highest exponent on each prime, we guarantee that no denominator will end up
missing some of its βparts.β For example, if we include 2!, we will cover the requirement for "2" for both π·! and π·!. However, if we had only take 2!, only π·! will
be satisfied by the LCD.
Why? Remember that we cannot change the original problem. So, βwhat we do the bottom, we must always do to the top,β which simply means weβre multiplying by
β1β! Our goal was just to manipulate the expression so that we have an LCD.)
Because variables are just numbers in disguise, we can use the same strategic approach (above) for the rational expression first proposed:
1
π₯ + 1β6
π₯! + 2π₯ + 1+1
π₯! β 1
Step 1: Factor the denominators
π·!: (π₯ + 1)! (Already fully factored) π·!: π₯! + 2π₯ + 1 (Perfect Square; requires factoring) = π₯ + 1 ! π·!: π₯! β 1 (Difference of Squares; requires factoring) = π₯ + 1 ! π₯ β 1 ! Step 2: Construct the LCD by multiplying together the highest power of each factor that appears among the denominators
LCD: π₯ + 1 ! π₯ β 1 !
Step 3: Multiply each fractionβs numerator and denominator by the factors missing in its denominator and simplify the expression. 1 β π₯ + 1 π₯ β 1 β 6 β π₯ β 1 + 1 β π₯ + 1
π₯ + 1 ! π₯ β 1 =
π₯! β 1β 6π₯ + 6+ π₯ + 1π₯ + 1 ! π₯ β 1
=
π₯! β 5π₯ + 6π₯ + 1 ! π₯ β 1
= (π₯ β 2)(π₯ β 3)(π₯ + 1)!(π₯ β 1)
Strategy #3
Q: What would our denominator have been if we had used Propery 1? A: (π₯ + 1)(π₯! + 2π₯ + 1)(π₯! β 1)β¦ a polynomial of degree 5 instead of 3, which
also means a lot more work when simplifying the numerator!
Part 2: Multiplication and Division Recall that to multiply two fractions, we simply multiply the numerators together and write the product on top. Then multiply the denominators together and write the product on the bottom.
i.e. !!β !!= !"
!"
Division, on the other hand, is performed by multiplying the fraction in the numerator by the reciprocal (the fraction where the top and bottom are flipped) of the fraction in the denominator.
i.e. !!!!
= !!Γ· !
!= !
!β !!= !"
!"
Consider the following example:
π₯ + 3π₯! + 7π₯ + 10
π₯ + 3π₯ β 5 Γ·
π₯ + 3π₯! β 25
Begin by factoring the expressions in the numerators and denominators because it will make it easier to simplify/reduce the fraction at the end!
π₯ + 3
π₯! + 7π₯ + 10 π₯ + 3π₯ β 5 Γ·
π₯ + 3π₯! β 25 =
π₯ + 3π₯ + 2 π₯ + 5
π₯ + 3π₯ β 5 Γ·
π₯ + 3π₯ β 5 π₯ + 5
= π₯ + 3 π₯ + 3
π₯ + 2 π₯ + 5 π₯ β 5 βπ₯ β 5 π₯ + 5
π₯ + 3
= π₯ + 3 π₯ + 3 π₯ + 5 π₯ β 5
π₯ + 3 π₯ + 2 π₯ + 5 π₯ β 5
= π₯ + 3 π₯ + 3 π₯ + 5 π₯ β 5
π₯ + 3 π₯ + 2 π₯ + 5 π₯ β 5 ,
provided π β βπ,Β±π
=
π₯ + 3π₯ + 2
It is important to note that the only reason we were able to cancel those brackets is
because: we first stated restrictions, and consequently, π±!ππ±!π
= π±!ππ±!π
= π±!ππ±!π
= π, and we know that multiplying by 1 does not change the value of our final solution!
Strategy #4
top related