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|<math> \left \{ (a_1+b+1)^p + (a_2+b_2)^p+ \cdots + (a_n+b_n)^p \right \} ^{1/p} \leqq (a_1^p + a_2^p + \cdots + a_n^p)^{1/p} + (b_1^p+b_2^p+ \cdots+ b_n^p)^{1/p}</math> | |<math> \left \{ (a_1+b+1)^p + (a_2+b_2)^p+ \cdots + (a_n+b_n)^p \right \} ^{1/p} \leqq (a_1^p + a_2^p + \cdots + a_n^p)^{1/p} + (b_1^p+b_2^p+ \cdots+ b_n^p)^{1/p}</math> | ||
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| + | |<math>\mbox{The equality ocures only if } f(x) /g(x) \mbox { is constant} </math> | ||
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! style="background: rgb(238, 238, 238) none repeat scroll 0% 0%; -moz-background-clip: -moz-initial; -moz-background-origin: -moz-initial; -moz-background-inline-policy: -moz-initial;" colspan="2" | Cauchy-schwarz Inequality for Integrals | ! style="background: rgb(238, 238, 238) none repeat scroll 0% 0%; -moz-background-clip: -moz-initial; -moz-background-origin: -moz-initial; -moz-background-inline-policy: -moz-initial;" colspan="2" | Cauchy-schwarz Inequality for Integrals | ||
Revision as of 09:21, 25 November 2010
| Inequalities | |
|---|---|
| Triangular Inequalities | |
| $ \vert a_1 \vert - \vert a_2 \vert \leqq \vert a_1 +a_2 \vert \leqq \vert a_1 \vert + \vert a_2 \vert $ | |
| $ \vert a_1 + a_2 + \cdots + a_n \vert \leqq \vert a_1 \vert + \vert a_2 \vert + \cdots + \vert a_n \vert $ | |
| Cauchy-schwarz Inequality | |
| $ \vert a_1 b_1 + a_2b_2 + \cdots + a_nb_n \vert ^2 \leqq \left ( \vert a_1 \vert ^2 + \vert a_2 \vert ^2 + \cdots + \vert a_n \vert ^2 \right ) \left ( \vert b_1 \vert ^2 + \vert b_2 \vert ^2 + \cdots + \vert b_n \vert ^2 \right ) $ | |
| $ \mbox{ The equality is valid if and only if } a_1/b_1 = a_2/b_2 = \cdots = a_n/b_n $ | |
| Inequalities Involving Arithmetic, Geometric and Harmonic | |
| $ \mbox{ if } A, \ G \mbox{ and } H \mbox{ are arithmatic, geometric and harmonic means of a positive numbers } a_1 , a_2 ,\cdots , a_n, \mbox{ then } $ | |
| $ H \leqq G \leqq A $ | |
| $ A = \frac{a_1 + a_2 + \cdots + a_n}{n} \qquad \qquad G = \sqrt[n]{a_1a_2 \cdots a_n} \qquad \qquad \frac{1}{H} = \frac{1}{n} \left ( {1 \over a_1} + {1 \over a_2 }+ \cdots +{1 \over a_n } \right ) $ | |
| $ \mbox{ the equality occures only if } a_1 = a_2 =\cdots = a_n. $ | |
| Holder Inequality | |
| $ \vert a_1 b_1 + a_2b_2 + \cdots + a_nb_n \vert \leqq \left ( \vert a_1 \vert ^p + \vert a_2 \vert ^p + \cdots + \vert a_n \vert ^p \right ) ^{1/p} \left ( \vert b_1 \vert ^q + \vert b_2 \vert ^q + \cdots + \vert b_n \vert ^q \right ) ^{1/q} $ | |
| $ {1 \over p} + {1 \over q} = 1 \qquad \qquad p > 1. q > 1 $ | |
| $ \mbox{ The equality occures only if } \vert a_1 \vert ^{p-1} / \vert b_1 \vert = \vert a_2 \vert ^{p-1} / \vert b_2 \vert = \cdots =\vert a_n \vert ^{p-1} / \vert n_1 \vert . $ | |
| $ \mbox{ for } p = q = 2, \mbox{ the formula reduces to Cauchy-Shwartz Inequality}. $ | |
| Tchebytchev Inequality | |
| $ \mbox{ if } a_1 \geqq a_2 \geqq \cdots \geqq a_n \mbox{ and } b_1 \geqq b_2 \geqq \cdots \geqq b_n \mbox{ then } $ | |
| $ \left ( \frac{a_1 + a_1 + \cdots + a_n}{n} \right ) \left ( \frac{ b_1 + b_2 + \cdots +b_n}{n} \right ) \leqq \frac{a_1b_1+a_2b_2+\cdots+a_nb_n}{n} $ | |
| $ (a_1 + a_2 + \cdots +a_n)(b_1 + b_2 + \cdots +b_n) \leqq n(a_1b_1 + a_2b_2 + \cdots +a_nb_n) $ | |
| Minkowski Inequality | |
| $ \mbox{ if } a_1,a_2, \cdots , a_n, b_1,b_2, \cdots, b_n \mbox{ are all positive and } p > 1 \mbox{ then } $ | |
| $ \left \{ (a_1+b+1)^p + (a_2+b_2)^p+ \cdots + (a_n+b_n)^p \right \} ^{1/p} \leqq (a_1^p + a_2^p + \cdots + a_n^p)^{1/p} + (b_1^p+b_2^p+ \cdots+ b_n^p)^{1/p} $ | |
| $ \mbox{The equality ocures only if } f(x) /g(x) \mbox { is constant} $ | |
| Cauchy-schwarz Inequality for Integrals | |
| Holder Inequality for Integrals | |
| Minkowski Inequality for Integrals | |
