Difference between revisions of "User:Temperal/The Problem Solver's Resource8"

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Fermat-Euler Identitity-If <math>gcd(a,m)=1</math>, then <math>a^{\phi{m}}\equiv1\pmod{m}</math>, where <math>\phi{m}</math> is the number of relitvely prime  numbers lower than <math>m</math>.
 
Fermat-Euler Identitity-If <math>gcd(a,m)=1</math>, then <math>a^{\phi{m}}\equiv1\pmod{m}</math>, where <math>\phi{m}</math> is the number of relitvely prime  numbers lower than <math>m</math>.
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Guass's Theorem-If <math>a|bc</math> and <math>(a,b) = 1</math>, then <math>a|c</math>.
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Revision as of 21:05, 5 October 2007



The Problem Solver's Resource
Introduction | Other Tips and Tricks | Methods of Proof | You are currently viewing page 8.

Intermediate Number Theory

These are more complex number theory theorems that may turn up on the USAMO or Pre-Olympiad tests. This will also cover diverging and converging series, and other such calculus-related topics.

Useful facts and Formulas

All quadratic resiues are 0 or 1$\pmod{4}$and 0,1, or 4 $\pmod{8}$.

Fermat-Euler Identitity-If $gcd(a,m)=1$, then $a^{\phi{m}}\equiv1\pmod{m}$, where $\phi{m}$ is the number of relitvely prime numbers lower than $m$.

Guass's Theorem-If $a|bc$ and $(a,b) = 1$, then $a|c$.


Back to page 7 | Continue to page 9