User:Temperal/The Problem Solver's Resource8
Intermediate Number TheoryThese 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. General Mean InequalityTake a set of functions . Note that does not exist. The geometric mean is . For non-negative real numbers , the following holds: for reals . I is the quadratic mean, is the arithmetic mean, the geometric mean, and the harmonic mean. Chebyshev's InequalityGiven real numbers and , we have %{\frac{\sum a_ib_i}{n}} \ge {\frac{\sum a_i}{n}}{\frac{\sum b_i}{n}}%. Minkowsky's InequalityGiven real numbers and , the following holds:
Nesbitt's InequalityFor all positive real numbers , and , the following holds: . Schur's inequalityGiven positive real numbers and real , the following holds: . Fermat-Euler IdentitityIf , then , where is the number of relitvely prime numbers lower than . Gauss's TheoremIf and , then . Power Mean InequalityFor a real number and positive real numbers , the th power mean of the is when and is given by the geometric mean]] of the when . Diverging-Converging TheoremA series converges iff . ErrataAll quadratic resiues are or and , , or . |