\(N=\dfrac{\left(ab\right)^3+\left(bc\right)^3+\left(ca\right)^3}{\left(ab\right)\left(bc\right)\left(ca\right)}\)

Đặt \(\left(ab;bc;ca\right)=\left(x;y;z\right)\Rightarrow x+y+z=0\Rightarrow N=\dfrac{x^3+y^3+z^3}{xyz}\)

\(N=\dfrac{x^3+y^3+z^3-3xyz+3xyz}{xyz}=\dfrac{\dfrac{1}{2}\left(x+y+z\right)\left[\left(x-y\right)^2+\left(y-z\right)^2+\left(z-x\right)^2\right]+3xyz}{xyz}=\dfrac{3xyz}{xyz}=3\)

\(A=\dfrac{a^3+b^3+c^3}{abc}=\dfrac{3abc}{abc}=3\)

lam hơi nagwns sợ người hỏi ko hiểu đó :d

Ta có: \(A=a\left(a^2-bc\right)+b\left(b^2-ac\right)+c\left(c^2-ab\right)=0\)

\(\Rightarrow A=a^3+b^3+c^3-3abc=0\) \(\Rightarrow A=\left(a+b\right)^3+c^3-3ab\left(a+b\right)-3abc=0\)

\(\Rightarrow A=\left(a+b+c\right)\left[\left(a+b\right)^2-c\left(a+b\right)+c^2\right]-3ab\left(a+b+c\right)=0\)

\(\Rightarrow A=\left(a+b+c\right)\left(a^2+b^2+c^2-ab-bc-ac\right)=0\)

Vì \(a+b+c\ne0\Rightarrow a^2+b^2+c^2-ab-ac-bc=0\)

Xét \(M=a^2+b^2+c^2-ab-ac-bc=0\)

\(\Rightarrow2M=2a^2+2b^2+2c^2-2ab-2ac-2bc=0\)

\(\Rightarrow2M=\left(a-b\right)^2+\left(b-c\right)^2+\left(c-a\right)^2=0\)

Vì \(\left(a-b\right)^2\ge0;\left(b-c\right)^2\ge0;\left(c-a\right)^2\ge0\forall a,b,c\)

\(\Rightarrow a-b=0;b-c=0;c-a=0\) \(\Rightarrow a=b=c\)

\(\Rightarrow P=\frac{a^2}{b^2}+\frac{b^2}{c^2}+\frac{c^2}{a^2}=1+1+1=3\) 

Bài 1: Ta có:

\(M=\frac{ad}{abcd+abd+ad+d}+\frac{bad}{bcd.ad+bc.ad+bad+ad}+\frac{c.abd}{cda.abd+cd.abd+cabd+abd}+\frac{d}{dab+da+d+1}\)

\(=\frac{ad}{1+abd+ad+d}+\frac{bad}{d+1+bad+ad}+\frac{1}{ad+d+1+abd}+\frac{d}{dab+da+d+1}\)

$=\frac{ad+abd+1+d}{ad+abd+1+d}=1$

Bài 2:

Vì $a,b,c,d\in [0;1]$ nên

\(N\leq \frac{a}{abcd+1}+\frac{b}{abcd+1}+\frac{c}{abcd+1}+\frac{d}{abcd+1}=\frac{a+b+c+d}{abcd+1}\)

Ta cũng có:
$(a-1)(b-1)\geq 0\Rightarrow a+b\leq ab+1$

Tương tự:

$c+d\leq cd+1$

$(ab-1)(cd-1)\geq 0\Rightarrow ab+cd\leq abcd+1$

Cộng 3 BĐT trên lại và thu gọn thì $a+b+c+d\leq abcd+3$

$\Rightarrow N\leq \frac{abcd+3}{abcd+1}=\frac{3(abcd+1)-2abcd}{abcd+1}$

$=3-\frac{2abcd}{abcd+1}\leq 3$

Vậy $N_{\max}=3$

a/

$x^2+y^2+z^2=3$

$F=\dfrac{x^2+1}{z+2}+\dfrac{y^2+1}{x+2}+\dfrac{z^2+1}{y+2}$

$\ge \dfrac{(x+y+z)^2}{(x+y+z)+6}\qquad (\text{Titu})$

Đặt $t=x+y+z$.

Ta có $t^2\le 3(x^2+y^2+z^2)=9$

$\Rightarrow t\le 3$.

Xét $f(t)=\dfrac{t^2}{t+6}$ thì $f'(t)=\dfrac{t(t+12)}{(t+6)^2}>0$ nên $f(t)$ tăng trên $(0,+\infty)$.

Mặt khác $t\ge \sqrt{x^2+y^2+z^2}=\sqrt3$.

Suy ra $F\ge f(\sqrt3)=\dfrac{3}{6+\sqrt3}$ $=\dfrac{6-\sqrt3}{11}$.

Dấu bằng khi $x=y=z=1$.

$\boxed{\min F=\dfrac{6-\sqrt3}{11}}$.

b/

Đặt $S=\sqrt{\dfrac{a}{a+3}}+\sqrt{\dfrac{b}{b+3}}+\sqrt{\dfrac{c}{c+3}}.$

Theo bất đẳng thức Cauchy-Schwarz, $S^2\le (a+b+c)\left(\dfrac1{a+3}+\dfrac1{b+3}+\dfrac1{c+3}\right)$.

Lại có $(a+b+c)^2\ge 3(ab+bc+ca)=9$

$\Rightarrow a+b+c\ge 3$.

Theo bất đẳng thức Nesbitt dạng Engel,

$\dfrac1{a+3}+\dfrac1{b+3}+\dfrac1{c+3}\le \dfrac1{6}(3)=\dfrac12.$

Do đó $S^2\le \dfrac32$

$\Rightarrow S\le \sqrt{\dfrac32}<\dfrac32$.

Suy ra $\sqrt{\dfrac{a}{a+3}}+\sqrt{\dfrac{b}{b+3}}+\sqrt{\dfrac{c}{c+3}}\le \dfrac32.$

Ta có : \(a^2+b^2\ge2ab\Rightarrow a^2+b^2-ab\ge ab\)

\(\Rightarrow\dfrac{1}{a^2-ab+b^2}\le\dfrac{1}{ab}=\dfrac{abc}{ab}=c\) ( do $abc=1$ )

Tương tự ta có :

\(\dfrac{1}{b^2-bc+c^2}\le a\)

\(\dfrac{1}{c^2-ab+a^2}\le b\)

Cộng vế với vế các BĐT trên có :

\(\dfrac{1}{a^2-ab+b^2}+\dfrac{1}{b^2-bc+c^2}+\dfrac{1}{c^2-ac+a^2}\le a+b+c\)

Dấu "=" xảy ra khi $a=b=c$

\(VT=\dfrac{1}{a^2+b^2-ab}+\dfrac{1}{b^2+c^2-bc}+\dfrac{1}{c^2+a^2-ca}\)

\(VT\le\dfrac{1}{2ab-ab}+\dfrac{1}{2bc-bc}+\dfrac{1}{2ca-ca}=\dfrac{1}{ab}+\dfrac{1}{bc}+\dfrac{1}{ca}=\dfrac{a+b+c}{abc}=a+b+c\)

Dấu "=" xảy ra khi \(a=b=c=1\)

giúp  mình với nhé