Difference between revisions of "SFMT"
(Created page with "== Theorem == Given nonnegative real numbers <math>e_1, e_2, e_3, \cdots ,e_n</math> and that <math>x_1+x_2+x_3+\cdots+x_n</math> is fixed and all the terms inside the sum are...") |
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Given nonnegative real numbers <math>e_1, e_2, e_3, \cdots ,e_n</math> and that <math>x_1+x_2+x_3+\cdots+x_n</math> is fixed and all the terms inside the sum are nonnegative, the maximum value of <math>x_1^{e_1}x_2^{e_2}x_3^{e_3}\cdots x_n^{e_n}</math> is when <math>\dfrac{x_1}{e_1}=\dfrac{x_2}{e_2}=\dfrac{x_3}{e_3}=\cdots =\dfrac{x_n}{e_n}.</math> | Given nonnegative real numbers <math>e_1, e_2, e_3, \cdots ,e_n</math> and that <math>x_1+x_2+x_3+\cdots+x_n</math> is fixed and all the terms inside the sum are nonnegative, the maximum value of <math>x_1^{e_1}x_2^{e_2}x_3^{e_3}\cdots x_n^{e_n}</math> is when <math>\dfrac{x_1}{e_1}=\dfrac{x_2}{e_2}=\dfrac{x_3}{e_3}=\cdots =\dfrac{x_n}{e_n}.</math> | ||
== Proof == | == Proof == | ||
− | The weighted | + | The weighted AM-GM Inequality states that if <math>a_1, a_2, \dotsc, a_n</math> are nonnegative real numbers, and <math>\lambda_1, \lambda_2, \dotsc, \lambda_n</math> are nonnegative real numbers (the "weights") which sum to 1, then <cmath>\lambda_1 a_1 + \lambda_2 a_2 + \dotsb + \lambda_n a_n \ge a_1^{\lambda_1} a_2^{\lambda_2} \dotsm a_n^{\lambda_n}.</cmath>[/quote] We let <math>\lambda_i=\dfrac{e_i}{e_1+e_2+\cdots+e_n}</math> and <math>a_i=\dfrac{x_i}{e_i}</math> in this inequality. We get that <math>x_1+x_2+x_3+\cdots+x_n \ge \sqrt[n]{\dfrac{x_1^{e_1}x_2^{e_2}x_3^{e_3}\cdots x_n^{e_n}}{e_1^{e_1}e_2^{e_2}e_3^{e_3}\cdots e_n^{e_n}}}(e_1+e_2+e_3+\cdots+e_n).</math> Dividing both sides and then taking to the nth power, we get <math>\left(\dfrac{x_1+x_2+x_3+\cdots+x_n}{e_1+e_2+e_3+\cdots+e_n}\right)^n \ge \dfrac{x_1^{e_1}x_2^{e_2}x_3^{e_3}\cdots x_n^{e_n}}{e_1^{e_1}e_2^{e_2}e_3^{e_3}\cdots e_n^{e_n}}.</math>Then we can multiply both sides to get <math>x_1^{e_1}x_2^{e_2}x_3^{e_3}\cdots x_n^{e_n} \le \left(\dfrac{x_1+x_2+x_3+\cdots+x_n}{e_1+e_2+e_3+\cdots+e_n}\right)^n (e_1^{e_1}e_2^{e_2}e_3^{e_3}\cdots e_n^{e_n}).</math> The equality case for the weighted AM-GM inequality is when all the <math>a_i</math> terms such that <math>e_i</math> is not <math>0</math> are equal, or in this case <math>\dfrac{x_1}{e_1}=\dfrac{x_2}{e_2}=\dfrac{x_3}{e_3}=\cdots=\dfrac{x_n}{e_n}.</math> |
+ | == Example Problems == | ||
+ | === Problem 1 === | ||
+ | Given nonnegative integer x, y, z such that <math>x+y+z=16,</math> find the maximum value <math>x^3y^2z^3.</math> | ||
+ | === Solution 1 === | ||
+ | By the new theorem, we know that <math>\dfrac{x}{3}=\dfrac{y}{2}=\dfrac{z}{3},</math> so x=6, y=4, z=6. Plugging it in, our answer is <math>746496.</math> |
Revision as of 14:32, 19 September 2021
Theorem
Given nonnegative real numbers and that is fixed and all the terms inside the sum are nonnegative, the maximum value of is when
Proof
The weighted AM-GM Inequality states that if are nonnegative real numbers, and are nonnegative real numbers (the "weights") which sum to 1, then [/quote] We let and in this inequality. We get that Dividing both sides and then taking to the nth power, we get Then we can multiply both sides to get The equality case for the weighted AM-GM inequality is when all the terms such that is not are equal, or in this case
Example Problems
Problem 1
Given nonnegative integer x, y, z such that find the maximum value
Solution 1
By the new theorem, we know that so x=6, y=4, z=6. Plugging it in, our answer is