Difference between revisions of "Factoring"
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* Prove that <math>2222^{5555} + 5555^{2222}</math> is divisible by 7. - USSR Problem Book | * Prove that <math>2222^{5555} + 5555^{2222}</math> is divisible by 7. - USSR Problem Book | ||
* Factor <math>(x-y)^3 + (y-z)^3 + (z-x)^3</math>. | * Factor <math>(x-y)^3 + (y-z)^3 + (z-x)^3</math>. | ||
+ | * Factor <math>x^4 + 1</math> into two polynomials with real coefficients | ||
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== Other Resources == | == Other Resources == | ||
* [http://tutorial.math.lamar.edu/pdf/Algebra_Cheat_Sheet_Reduced.pdf More Common Factorizations]. | * [http://tutorial.math.lamar.edu/pdf/Algebra_Cheat_Sheet_Reduced.pdf More Common Factorizations]. |
Revision as of 21:10, 10 August 2006
Factoring is an essential part of any mathematical toolbox. To factor, or to break an expression into factors, is to write the expression (often an integer or polynomial) as a product of different terms. This often allows one to find information about an expression that was not otherwise obvious.
Contents
[hide]Differences and Sums of Powers
Using the formula for the sum of a geometric sequence, it's easy to derive the more general formula:
Take note of the specific case where n is odd:
This also leads to the formula for the sum of cubes,
Vieta's/Newton Factorizations
These factorizations are useful for problems that could otherwise be solved by Newton sums or problems that give a polynomial and ask a question about the roots. Combined with Vieta's formulas, these are excellent factorizations that show up everywhere.
Other Useful Factorizations
Practice Problems
- Prove that is never divisible by 121 for any positive integer .
- Prove that is divisible by 7. - USSR Problem Book
- Factor .
- Factor into two polynomials with real coefficients