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Algebraic Pitfalls By Jordan D. White.

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1 Algebraic Pitfalls By Jordan D. White

2 Adding/Subtracting Fractions:
When adding or subtracting fractions it can be common for someone to add or subtract without having a common denominator. For example: = 2 6 = However this is incorrect. It may help to think of the fraction as one unit or as decimals. 1 2 = 0.50 and = If we were to add them, we have 0.75 or in fractional form as opposed to which about 0.33. If we change the denominator first we should get this = = 3 4 Essentially having the same denominator allows us to add like terms.

3 Multiplying/Dividing Fractions:
When we have a sum or difference in a fraction it is common for some people to cancel out terms if we think there is a common factor, however this is problematic. Take We can see this is For some people they cancel the 2 and the 4 to get 1 2 , which is not the same thing. When we think the sum or difference, we can treat it as one item. When we have a products in the numerator or denominator then we cancel things out, i.e. 5 Γ— 6 3 = 5(2) = 10.

4 Division of 3 terms vs. 4 terms
With division of 4 terms, we have π‘Ž 𝑏 𝑐 𝑑 and this is the same thing as π‘Ž 𝑏 Γ— 𝑑 𝑐 . Ex: 4 terms, = 3 4 Γ— 5 6 = = 5 8 With division of 3 terms, there can be confusion. We have a/b/c and it is tempting to think a b ×𝑐. However we should think of it as a b c 1 and so we have a b Γ— 1 c or a bc . Ex: , we can view this as = 1 2 Γ— = 1 2Γ—2 = Ex: , we can view this as = 3 2 Γ— = 3 2Γ—4 = 3 8

5 Square Roots: When to Use the Principal Root
When dealing with the simplification of an expression i.e. 4 , it is okay to say 2, to just have the principal root, (the positive root). When solving an equation you want to examine both the positive and negative solutions so that you capture all of the possible solutions. For example, x = 9 , some would say x = 3, and just that. While it is true that x = 3 is one of the solutions, it does not tell the whole story, x = 3 or x = -3, in this case, as either of those answers would give us a true statement.

6 Dividing Out x and solving for x:
When solving for x, it can be tempting to divide out an x to simplify things, but this does not tell the whole story and sometimes it may actually complicate your process. Example: 2 π‘₯ 2 +π‘₯=0. If you divided an x out, then you get 2π‘₯+1=0. You would get π‘₯=βˆ’ However this misses solutions. If you factor here, it can help. So with 2 π‘₯ 2 +π‘₯=0, it is the same as π‘₯ 2π‘₯+1 =0. In order to to zero out the equation, then π‘₯=0, or 2π‘₯+1=0. Thus π‘₯=0 or π‘₯=βˆ’ 1 2 . With complicated equations, it becomes more clear that this method of dividing out π‘₯ does not work. Ex: π‘₯ 2 +5π‘₯+6=0, if you divide out a variable it gets messy quickly. We get π‘₯+5+ 6 π‘₯ =0, which we don’t know how to solve.

7 Squaring a Sum/Difference (Binomials)
When squaring a sum or difference for a binomial, it is not uncommon to miss some terms, usually the middle term. With π‘Ž+𝑏 2 and π‘Žβˆ’π‘ 2 , it is tempting to say that π‘Ž+𝑏 2 = π‘Ž 2 + 𝑏 2 and π‘Žβˆ’π‘ 2 = π‘Ž 2 βˆ’ 𝑏 2 . However this misses some information and is thus not true. π‘Ž+𝑏 2 = π‘Ž 2 +2π‘Žπ‘+ 𝑏 2 and π‘Ž+𝑏 2 = π‘Ž 2 βˆ’2π‘Žπ‘+ 𝑏 2 This a shortcut. If you foil things out you will find the same. Think about this way. π‘Ž+𝑏 2 = π‘Ž+𝑏 π‘Ž+𝑏 and π‘Žβˆ’π‘ 2 = π‘Žβˆ’π‘ π‘Žβˆ’π‘

8 Square Root of a Sum While you can split up roots when it comes to products, if it is a sum not so much. For example π‘₯𝑦 = π‘₯ 𝑦 . However π‘₯+𝑦 β‰  π‘₯ + 𝑦 The square roots of sums does not work the same. They does not follow the some rules. If it helps for the product, it makes sense. π‘₯𝑦 = (π‘₯𝑦) 1/2 . Then using exponent rules (π‘₯𝑦) 1/2 = (π‘₯) 1/2 (𝑦) 1/2 We can’t say the same with the square root of a sum. Example: = =2 Γ—2=4. (Product) Example: 8 = 4+4 = =2+2=4 (Sum) . This does not work, it would suggest that 8 = 4, or 4 2 =8 and we now that and 4 2 =16. Also we would be saying if this were true that we have 16 = 4 and 8 = 4. With the square root of a sum, treat the sum as one item.

9 Improper Distribution
It is not uncommon for some people to not distribute all the way through. For example 2(π‘₯βˆ’5), some might say the result is 2π‘₯βˆ’5. However they did not distribute the 2 to both terms. When you distribute a term or terms, you have to apply the distribution to every term in the parenthesis. So you’d have 2π‘₯βˆ’10. It may be helpful to physically multiply things out. Another common distribution error is dealing with exponents. Some will apply the term they are distributing first. For example 4 π‘₯ Some may say the result is 4 π‘₯ However exponentation comes first. We’d have to do π‘₯ and then multiply the result by 4.

10 Subtracting Polynomials
With subtracting polynomials, it is not uncommon to miss a few things. The most common mistake is not applying the minus sign to the whole expression. One way is to apply the minus sign, treating it like you are multiplying by negative one. If not, you have to be extraordinarily careful. You could also rearrange things. Ex: 4 π‘₯ 3 +3 π‘₯ 2 +2π‘₯ βˆ’1 βˆ’(5 π‘₯ 3 βˆ’4 π‘₯ 2 +7π‘₯+3), you can view this as 4 π‘₯ 3 +3 π‘₯ 2 +2π‘₯ βˆ’1 +(βˆ’5 π‘₯ 3 +4 π‘₯ 2 βˆ’7π‘₯βˆ’3). This could help you keep track better as well as show your work.

11 Negative Exponents One of the biggest misconceptions about negative exponents is that they make the numbers negative. This is very much not true. Negative exponents have no bearing on the sign of a number or variable. Negative exponents do not make the result negative. For example, someone may see 2 βˆ’1 and they may say this would be equal to -2, or they may say see 3 βˆ’2 and say it is equal βˆ’3 2 . They may think the result is βˆ’3 2 =9 or βˆ’(3 2 ) = -9 depending on how they read this, or even 3 Γ—(βˆ’2)=βˆ’6. In the example the logic for each case is wrong. If we have π‘Ž βˆ’π‘› where a is not zero, it just means we have 1 π‘Ž 𝑛 . This is how we define negative exponentiation. For instance if we have 2 βˆ’2 , this is equal to = as opposed to βˆ’2 2 =βˆ’4.

12 Fractional Exponents and Solving Them
When given an equation raised to a fractional exponent it can be tempting to turn into radical form. Ex: (π‘₯+1) 2/3 = 4 However this does not solve anything, it makes things more complicated. Ex: ( 3 π‘₯+1 ) 2 =4 or 3 π‘₯ =4. This is does not help us. Let’s try getting rid of the fractional exponent. This can be accomplished by raising both sides by the reciprocal of the exponent. This in conjunction with the power of a power rule for exponents, which allows us to move in the direction we need to move. Ex: (π‘₯+1) 2/3 = 4. If we take this and apply our logic then ((π‘₯+1) 2/3 ) 3/2 = 4 3/2 . This implies that we then have x+1= 4 3/2 . With 4 3/2 we can then use radical form. We have (4) 3 or ( 4 ) 3 . We get 8 in either case. So we then have x+1 = 8 or x = 7.

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