Questions tagged [inequality]

Questions on proving, manipulating and applying inequalities. Do not use this tag just because an inequality appears somewhere in your question.

An inequality is a mathematical relation between two quantities that are not necessarily equal, but bigger or smaller.

To prove inequalities, a number of proven inequalities can be used, including:

  • The AM-GM inequality

    Let $x_i>0$, $\alpha_i>0$ such that $\alpha_1+\alpha_2+...+\alpha_n=1$. Prove that $$\alpha_1x_1+\alpha_2x_2+...+\alpha_nx_n\geq x_1^{\alpha_1}x_2^{\alpha_2}...x_n^{\alpha_n}$$

For $\alpha_1=\alpha_2=...=\alpha_n=\frac{1}{n}$ we obtain the well-known $$\frac{x_1+x_2+\cdots+x_n}{n} \ge \sqrt[n]{x_1x_2\cdots x_n}$$

  • The Power Mean inequality (P-M).

    Let $a_1, a_2,\cdots, a_n$ be positive numbers and $p>q$. Then $$\left(\frac{a_1^p+a_2^p+\cdots+a_n^p}{n}\right)^{\frac{1}{p}} \geq \left(\frac{a_1^q+a_2^q+\cdots+a_n^q}{n}\right)^{\frac{1}{q}}$$

  • The Rearrangement inequality (R).

    Let $a_1\le\dots\le a_n$ and $b_1\le\dots\le b_n$. For all permutations $\sigma\in S_n$, $$\sum_{i=1}^na_ib_{n-i+1}\le\sum_{i=1}^na_ib_{\sigma(i)}\leq\sum_{i=1}^na_ib_i.$$

The rearrangement generalizes similar for more than two sequences of numbers.

  • The Cauchy-Schwarz inequality (C-S).

    If $a_1, a_2, \cdots, a_n$ and $b_1, b_2,\cdots, b_n$ are two sequences of real numbers, then $$\sum^{n}_{i=1} a_i^2 \sum^{n}_{i=1} b_i^2\geq\left(\sum^{n}_{i=1} a_ib_i \right)^2$$

  • The H$\ddot o$lder inequality (H).

    Let $a_1$, $a_2$,..., $a_n$, $b_1$, $b_2$,..., $b_n$, $\alpha$ and $\beta$ be positive numbers. Then $$\left(\sum_{i =1}^n a_i\right )^\alpha \left(\sum_{i =1}^n b_i \right )^\beta\geq \left(\sum_{i =1}^n (a_ib_i)^\frac{1}{\alpha+\beta}\right )^{\alpha+\beta} $$

  • The Schur inequalities (S):

    Let $x$, $y$ and $z$ be positive numbers and $t$ is a real number. Prove that:$$x^t(x-y)(x-z)+y^t(y-z)(y-x)+z^t (z-x)(z-y)\ge 0$$

  • Muirhead inequalities

    A sequence $a_1 \geq a_2 \geq \dots \geq a_n$ majorizes a sequence $b_1 \geq b_2 \geq \dots \geq b_n$ if $$\sum_{i=1}^k a_i \geq\sum_{i=1}^k a_i $$ for all $1\leq k < n$ and $$\sum_{i=1}^n a_i =\sum_{i=1}^n a_i $$ If sequence $(a_i)$ majorizes $(b_i)$ (notated as $a_i \succ b_i$), then $$\sum_{\text{sym}}x_1^{a_1}x_2^{a_2}\dots x_n^{a_n}\geq \sum_{\text{sym}}x_1^{b_1}x_2^{b_2}\dots x_n^{b_n}$$

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How do we prove without calculus that $\forall \ x,y \ge 0$, we have $\ 1+x^3+y^3\ge x+x^2y+y^2$

I've been trying to prove an inequality I was given by a friend, but so far my only progress has been calculus bashing: $$LHS \ge RHS\iff1+x^3+y^3 - x-x^2y-y^2 \ge0$$ Letting $f(x,y) = 1+x^3+y^3 - x-x^2y-y^2$, we want $\frac{\partial f}{\partial…
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Lower Bound for $\frac{t + (1-t)p_1}{1+2t}\cdot \frac{t + (1-t)p_2}{1+t}$

I am interested in obtaining a lower bound for the function $$ f(t) = \frac{t + (1-t)p_1}{1+2t}\cdot \frac{t + (1-t)p_2}{1+t}, $$ defined on $(0,1)$, where $p_1$ and $p_2$ are two constants with the constraint that $p_1 + p_2 \leq 1$ and they are…
noam.szyfer
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Any suggestions to prove inequality?

I have been attempting to prove the following for $a \geq b \geq c > 0$ $\frac{(a^2-b^2)}{c}+\frac{(c^2-b^2)}{a}+\frac{(a^2-c^2)}{b}\geq 3a-4b+c$ I first identified which terms were definitely positive based on the restrictions. After factoring the…
ra1nmaster
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Find the integers $n\geq 2$ that satisfy $0 \leq 1 +\frac{n}{n-1}\cos\big(\pi\cdot\frac{n}{n+1}\big)$

I want to find the integers $n\geq 2$ that satisfy the inequality $$ x_1x_2+x_2x_3+\cdots+x_{n-1}x_n\leq\frac{n-1}{n}\Big(x_1^2+x_2^2+\cdots+x_n^2\Big) $$ for all $x_i>0$. I see that if $n=2$, the geometric mean and quadratic mean…
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If $(a+1)(b+1)(c+1)=8,$ then prove $abc \le 1$?

My proof: $\sqrt[3]{(a+1)(b+1)(c+1)} = 2 \le \frac{a+b+c}{3} + 1 $according to AM-GM. Thus, $1 \le \frac {a+b+c}{3}$. Also, $ \sqrt[3]{abc} \le \frac{a+b+c}{3}$. Then, either $\frac {a+b+c}{3} \le 1$ or $1 \le \frac {a+b+c}{3}$. Suppose the latter…
Richard
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An inequality involving sine functions

Let $a>0$ be a fixed number and let $\theta\in(0,\pi/2)$ be also fixed. Is the following inequality true? $$ (k^2+a)-\frac{(1+a)\sin (k\theta)}{k\sin\theta}\geq 0 \quad \quad \forall k=1,2,\cdots. $$ Of course, it is an equality for $k=1$. Also, it…
teh
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Solving Inequalities - a curious observation

This question is about an interesting observation that comes up whenever one solves an inequality with a variable in the denominator. eg. 1/x < 1 Why is it that, in the solution to these inequalities, x can be a values that are 1) on the outsides of…
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Inequality $xy+yz+zx-xyz \leq \frac{9}{4}.$

Currently I try to tackle some olympiad questions: Let $x, y, z \geq 0$ with $x+y+z=3$. Show that $$ x y+y z+z x-x y z \leq \frac{9}{4}. $$ and also find out when the equality holds. I started by plugging in $z=3-x-y$ on the LHS and…
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Show that for any two positive real numbers $a, b: \frac a{a + 2b} + \frac b{b + 2a} ≥ \frac12$

Question: Show that for any two positive real numbers $a, b: \frac a{a + 2b} + \frac b{b + 2a} ≥ \frac12$. So for this question, I began by expanding all terms and moving them all to one side. However, I do not know how to definitively say that…
Jamie
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Prove $2 x \ln(x) + 1 - x^{2} < 0$, for $x > 1$

I am trying to rigorously show the following bound. \begin{equation} 2 x \ln(x) + 1 - x^{2} < 0, \text{ for $x > 1$} \end{equation} Based on plots, it appears to hold for all $x > 1$. My concern with showing such bounds is dealing with the boundary…
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How to simplify $|a\pm b| \le |c \pm d|$?

How many inequalities are hidden in $|a\pm b| \le |c \pm d|$? Am I right in thinking as follows: Case 1. $a\pm b >0$ and $c \pm d >0$. In this case we have $a\pm b \le c \pm d$ Case 2. $a\pm b <0$ and $c \pm d >0$. In this case we have $-(a\pm b)…
User101
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smallest $k$ s.t. $(x+y)^2\leq k(x^2-xy+y^2)$

I would appreciate if somebody could help me with the following problem Q: Find $K$? $$(x+y)^2\leq k(x^2-xy+y^2)$$. where $\forall x,y\in \mathbb{R}$
Young
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If $a,b,c > 0$ satisfy $a^2+b^2+c^2=3$ then $\frac{a}{b+c+3}+\frac{b}{a+c+3}+\frac{c}{a+b+3} \geq \frac{3}{5}$

Given $a,b,c > 0$ satisfying the condition $$a^2+b^2+c^2=3,$$ prove that $$\frac{a}{b+c+3}+\frac{b}{a+c+3}+\frac{c}{a+b+3} \geq \frac{3}{5}.$$ Thank you all
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ab+bc+ca=3 then $\sum\frac{\sqrt{a+3}}{a+\sqrt{bc}}\ge\frac{2(\sqrt{a}+\sqrt{b}+\sqrt{c})}{\sqrt{a+b+c+1}}$

Let $a,b,c≥0:ab+bc+ca=3$. Prove that: $$\frac{\sqrt{a+3}}{a+\sqrt{bc}}+\frac{\sqrt{b+3}}{b+\sqrt{ca}}+\frac{\sqrt{c+3}}{c+\sqrt{ab}}\ge\frac{2(\sqrt{a}+\sqrt{b}+\sqrt{c})}{\sqrt{a+b+c+1}}$$ This is really tough problem. I tried to use AM-GM as:…
Sickness
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$\frac{2-a}{a+\sqrt{bc+abc}}+\frac{2-b}{b+\sqrt{ca+abc}}+\frac{2-c}{c+\sqrt{ab+abc}}\ge1$

For $a,b,c\ge0: ab+bc+ca+abc=4$ then: $$\frac{2-a}{a+\sqrt{bc+abc}}+\frac{2-b}{b+\sqrt{ca+abc}}+\frac{2-c}{c+\sqrt{ab+abc}}\ge1$$ I used the condition and get: $a+\sqrt{bc+abc}=a+\sqrt{4-a(b+c)}\le a+2$ So we need to prove that:…
Sickness
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