Simplifying Square-Root Radicals Containing Perfect Square Factors

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DETAILED SOLUTIONS AND CONCEPTS - OPERATIONS ON IRRATIONAL NUMBERS Prepared by Ingrid Stewart, Ph.D., College of Southern Nevada Please Send Questions and Comments to ingrid.stewart@csn.edu. Thank you! PLEASE NOTE THAT YOU CANNOT USE A CALCULATOR ON THE ACCUPLACER - ELEMENTARY ALGEBRA TEST! YOU MUST BE ABLE TO DO THE FOLLOWING PROBLEMS WITHOUT A CALCULATOR! Simplifying Square-Root Radicals Containing Perfect Square Factors Problem 1: Some radicands are perfect squares, whereas others are not. In the later case it is often useful to "simplify" the radicand IF it contains a perfect-square factor! If the radicand is a perfect square, find its square root. If the radicand is not a perfect square, try to factor the radicand so that one factor is the largest possible perfect square factor. Place the square root of this factor outside the radical and keep the other factors inside (or under) the radical. There is an assumed multiplication sign between the number outside the radical and and the radical expression. If the radicand is not a perfect square and it does not have a perfect square factor, then it is simplified. Simplify. to "simplify." Here we are asked to "simplify" instead of finding the square root. Since the radicand is a perfect square, we can say irrational number.. This is NOT an Problem 2: Simplify. to "simplify." Here we are asked to "simplify" instead of factoring out perfect-square factors.

Here the radicand is not a perfect square. However, we know that we can write the radicand as a product as follows: Since we know that 16 is a perfect square and it is also the largest perfect square factor of the radicand, we can now simplify the square root. in simplified form. Problem 3: Please note that means 4 times the. Simplify. Here the radicand is not a perfect square. However, we know that we can write the radicand as a product as follows: Since we know that 9 is a perfect square and it is also the largest perfect square factor of the radicand, we can now simplify the square root. in simplified form. Problem 4: Simplify. Here the radicand is not a perfect square. However, we know that we can write the radicand as a product as follows: Since we know that 25 is a perfect square and it is also the largest perfect square factor of the radicand, we can now simplify the square root. in simplified form. Problem 5: Simplify. Here the radicand is not a perfect square. However, we know that we can write the radicand as a product as follows:

Since we know that 4 is a perfect square and it is also the largest perfect square factor of the radicand, we can now simplify the square root. in simplified form. Problem 6: Simplify. Here the radicand is not a perfect square. However, we know that we can write the radicand as a product as follows: Since we know that 9 is a perfect square and it is also the largest perfect square factor of the radicand, we can now simplify the square root. in simplified form. Adding and Subtracting Square-Root Radicals Problem 7: Add or subtract the coefficients of like radicals. Use the common radical as a factor in the solution. Add to "simplify." Here we are asked to "simplify" instead of factoring perfectsquare factors out of the sum. Since both terms have the same radical we can add their coefficient to get

Problem 8: Add Please note that there is an implied coefficient of 1 in front of. It is NOT customary to write it. However, it must be used in addition and subtraction! Since both terms have the same radical we can add their coefficient to get Problem 9: Combine the "like" radicals in possible. and simplify, if to "simplify." Here we are asked to "simplify" instead of factoring perfectsquare factors out of the result. Let's rearrange the expression as follows and then combine the terms with like radicals. Please note that we cannot add the coefficients of the final difference! There are no like radicals and the radicands are prime numbers. Problem 10: Subtract to "simplify." Here we are asked to "simplify" instead of factoring perfectsquare factors out of the difference. No simplification can take place. The only thing that could be done is to change the radical to a rounded decimal number and then subtract. Problem 11: Subtract No simplification can take place. The only thing that could be done is to change the radicals to rounded decimal numbers and then subtract.

Problem 12: Add There are no like radicals. However, 20 is NOT a prime number, therefore, we can simplify the second radical to see if we end up with a sum of like radicals. Now we can write and we find that we DO have like radicals when simplifying! Problem 13: Subtract There are no like radicals. However, 32 is NOT a prime number, therefore, we can simplify the second radical to see if we end up with a difference of like radicals. simplifying! and we find that we do have like radicals when Now we can write Please note that there is an implied coefficient of 1 in front of. It is NOT customary to write it. However, it must be used in addition and subtraction! Problem 14: Subtract There are no like radicals. However, 18 is NOT a prime number, therefore, we can simplify the second radical to see if we end up with a sum of like radicals. simplifying! and we find that we still DO NOT have like radicals when However, we might want to write

Please note that we cannot add the coefficients of the final difference! There are no like radicals and the radicands are now prime numbers. ing Square-Root Radicals the coefficients. the radicands. Simplify, if possible. Problem 15: Symbolically, this can be stated as. to "simplify." Here we are asked to "simplify" instead of factoring perfectsquare factors out of the product. Problem 16: The coefficients are both 1. But we can multiply the radicands as follows:. The radical cannot be simplified because 91 is a prime number. The coefficients are both 1. But we can multiply the radicands as follows:. The product can be reduced! which cannot be simplified. Problem 17: The coefficients are 3 and 2. Therefore, they need to be multiplied as well as the radicands.

. The radical cannot be simplified because 35 does not have any factors that are perfect squares. Problem 18: The coefficients are 4 and 2. Therefore, they need to be multiplied as well as the radicands. and we may be able to simplify it.. The radical is NOT a prime number Problem 19: and NOTE: Whenever you multiply a radical by itself, the solution is ALWAYS the radicand! Problem 20: Here we have to use the FOIL process. Remember that FOIL stands for First Product, Outer Product, Inner Product, and Last Product. F O I L Please note that the two middle products have like radicands that is why we added their coefficients!

Problem 21: Here we have to use the FOIL process again. F O I L Please note the following: Since the two middle products have the same value, they cancel each other out when one is subtracted from the other! Therefore, we get Dividing Square-Root Radicals Divide the coefficients. Divide the radicands. Simplify, if possible. Problem 22: Symbolically, this can be stated as. Divide to "simplify." Here we are asked to "simplify" instead of factoring perfectsquare factors out of the quotient. The radical cannot be simplified because 6 does not contain a perfectsquare factor.

Problem 23: Divide The coefficient 3 in the numerator and the denominator 6 can be divided (or reduced) because they are both outside the radical. NOTE: You cannot divide the 6 under the radical by the 6 in the denominator! We get. The coefficient 1 in the numerator is implied! The radical cannot be simplified because 6 does not contain a perfect-square factor. Problem 24: Divide We get number.. The radical cannot be simplified because 2 is a prime Rationalizing a Denominator containing an Irrational Square-Root Radical the denominator by itself. To preserve the value of the fraction, multiply the numerator by the same number. Simplify all radicals and reduce the resulting fraction, if possible. NOTE: In Steps 1 and 2 above, we have actually multiplied the fraction by an equivalent of the number 1! Problem 25: Rationalize the denominator in The radical cannot be simplified because 11 is a prime number.

Remember that and. Also,. Problem 26: NOTE: You cannot divide the 77 in the denominator by the 11 in the radical! Rationalize the denominator in. The radical cannot be simplified because 6 does not contain a perfect-square factor. NOTE: You cannot divide the 6 under the radical by the 6 in the denominator! However, the coefficient 4 in the numerator and the denominator 6 can be reduced because they are both outside the radical. can be written as. You cannot divide the 6 under the radical by the 3 in the denominator! Problem 27: Rationalize the denominator in NOTE: You cannot divide the x under the radical by the x in the denominator!

Problem 28: Rationalize the denominator in The radical cannot be simplified because 39 does not contain a perfect-square factor. NOTE: You cannot divide the 39 under the radical by the 3 in the denominator! Problem 29: Rationalize the denominator in Problem 30: The radical cannot be simplified because 2 is a prime number. NOTE: You cannot divide the 2 under the radical by the 2 in the denominator! Rationalize the denominator in First we need to be aware of the following: Now we can rationalize the denominator as usual.

The radical cannot be simplified because 35 does not contain a perfect-square factor. NOTE: You cannot divide the 35 under the radical by the 5 in the denominator!

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