Difference between revisions of "Proofs of AM-GM"
GraemeMcRae (talk | contribs) (fix typo: if a_i=0 then the right hand is 0, and the *LEFT* hand is \ge 0) |
GraemeMcRae (talk | contribs) (→Alternate Proof by Convexity: added missing exponent in 2nd expression of the long inequality in this section) |
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<cmath> (r_i +1)^{\lambda_i} \le \exp(\lambda_i r_i) .</cmath> | <cmath> (r_i +1)^{\lambda_i} \le \exp(\lambda_i r_i) .</cmath> | ||
Multiplying <math>n</math> such inequalities gives us | Multiplying <math>n</math> such inequalities gives us | ||
− | <cmath> \frac{\prod_{i=1}^n a_i^{\lambda_i}}{ \sum_{i=1}^n \lambda_i r_i} = \prod_{i=1}^n (r_i + 1) \le \prod_{i=1}^n \exp \lambda_i r_i = \exp \sum_{i=1}^n \lambda_i a_i / \sum_{j=1}^n \lambda_j a_j - \lambda_i = \exp 0 = 1 ,</cmath> | + | <cmath> \frac{\prod_{i=1}^n a_i^{\lambda_i}}{ \sum_{i=1}^n \lambda_i r_i} = \prod_{i=1}^n (r_i + 1)^{\lambda_{i}} \le \prod_{i=1}^n \exp \lambda_i r_i = \exp \sum_{i=1}^n \lambda_i a_i / \sum_{j=1}^n \lambda_j a_j - \lambda_i = \exp 0 = 1 ,</cmath> |
so | so | ||
<cmath> \prod_{i=1}^n a_i^{\lambda_i} \le \sum_{i=1}^n \lambda_i r_i , </cmath> | <cmath> \prod_{i=1}^n a_i^{\lambda_i} \le \sum_{i=1}^n \lambda_i r_i , </cmath> |
Revision as of 09:33, 14 October 2010
This pages lists some proofs of the weighted AM-GM Inequality. The inequality's statement is as follows: for all nonnegative reals and nonnegative reals such that , then with equality if and only if for all such that .
We first note that we may disregard any for which , as they contribute to neither side of the desired inequality. We also note that if and , for some , then the right-hand side of the inequality is zero and the left hand of the inequality is greater or equal to zero, with equality if and only if whenever . Thus we may henceforth assume that all and are strictly positive.
Contents
Complete Proofs
Proof by Convexity
We note that the function is strictly concave. Then by Jensen's Inequality, with equality if and only if all the are equal. Since is a strictly increasing function, it then follows that with equality if and only if all the are equal, as desired.
Alternate Proof by Convexity
This proof is due to G. Pólya.
Note that the function is strictly convex. Let be the line tangent to at ; then . Since is also a continuous, differentiable function, it follows that for all , with equality exactly when , i.e., with equality exactly when .
Now, set for all integers . Our earlier bound tells us that so Multiplying such inequalities gives us so as desired. Equality holds when is always equal to zero, i.e., when for all such that .
Proofs of Unweighted AM-GM
These proofs use the assumption that , for all integers .
Proof by Rearrangement
Define the sequence as , for all integers . Evidently these sequences are similarly sorted. Then by the Rearrangement Inequality, where we take our indices modulo , with equality exactly when all the , and therefore all the , are equal. Dividing both sides by gives the desired inequality.
Proof by Cauchy Induction
We first prove that the inequality holds for two variables. Note that are similarly sorted sequences. Then by the Rearrangement Inequality, with equality exactly when .
We next prove that if the inequality holds for variables (with equality when all are equal to zero), than it holds for variables (with equality when all are equal to zero). Indeed, suppose the inequality holds for variables. Let denote the arithmetic means of , , , respectively; let denote their respective geometric means. Then with equality when all the numbers are equal, as desired.
These two results show by induction that the theorem holds for , for all integers . In particular, for every integer , there is an integer such that the theorem holds for variables.
Finally, we show that if and the theorem holds for variables, then it holds for variables with arithmetic mean and geometric mean . Indeed, set for , and let for . Then It follows that , or , with equality exactly when all the are equal to .
The last two results show that for all positive integers , the theorem holds for variables. Therefore the theorem is true.