\(M=\dfrac{1}{16x}+\dfrac{1}{4y}+\dfrac{1}{z}=\dfrac{1}{16x}+\dfrac{4}{16y}+\dfrac{16}{16z}\)

Áp dụng BĐT Cauchy-Schwarz ta có:

\(M=\dfrac{1}{16x}+\dfrac{4}{16y}+\dfrac{16}{16z}=\dfrac{1^2}{16x}+\dfrac{2^2}{16y}+\dfrac{4^2}{16z}\)

\(\ge\dfrac{\left(1+2+4\right)^2}{16x+16y+16z}=\dfrac{7^2}{16\left(x+y+z\right)}=\dfrac{49}{16}\)

@Ace Legona tớ chưa học BĐT Cauchy-Schwarz ! Có cách giải khác không?

\(M=\dfrac{1}{16}\left(\dfrac{1}{x}+\dfrac{4}{y}+\dfrac{16}{z}\right)=\dfrac{1}{16}\left(\dfrac{1}{x}+\dfrac{2^2}{y}+\dfrac{4^2}{z}\right)\)

\(\Rightarrow M\ge\dfrac{1}{16}\dfrac{\left(1+2+4\right)^2}{x+y+z}=\dfrac{1}{16}.\dfrac{49}{1}=\dfrac{49}{16}\)

\(\Rightarrow M_{min}=\dfrac{49}{16}\) khi \(\left\{{}\begin{matrix}x+y+z=1\\\dfrac{1}{x}=\dfrac{2}{y}=\dfrac{4}{z}\end{matrix}\right.\) \(\Rightarrow\left\{{}\begin{matrix}x=\dfrac{1}{7}\\y=\dfrac{2}{7}\\z=\dfrac{4}{7}\end{matrix}\right.\)

\(P=\dfrac{1}{2023}\dfrac{1}{z}\left(\dfrac{1}{x}+\dfrac{1}{y}\right)=\dfrac{1}{2023.z}\dfrac{x+y}{xy}\)

Ap dung BDT cosi taco 

\(P\ge\dfrac{1}{2023z}.\dfrac{x+y}{\dfrac{\left(x+y\right)^2}{4}}=\dfrac{4}{2023z}\dfrac{1}{x+y}\)

<->\(P\ge\dfrac{4}{2023}\dfrac{1}{z\left(1-z\right)}=\dfrac{4}{2023}\dfrac{1}{-z^2+z}=\dfrac{4}{2023}\dfrac{1}{-\left(z-\dfrac{1}{2}\right)^2+\dfrac{1}{4}}\)

\(< =>P\ge\dfrac{4}{2023}\dfrac{1}{\dfrac{1}{4}}=\dfrac{16}{2023}\)

\(P_{min}=\dfrac{16}{2023}\Leftrightarrow Z=\dfrac{1}{2},x=y=\dfrac{1}{4}\)

\(T\ge\dfrac{\left(x+y+z\right)^2}{x+y+z+\sqrt{xy}+\sqrt{yz}+\sqrt{zx}}\ge\dfrac{\left(x+y+z\right)^2}{x+y+z+x+y+z}=\dfrac{x+y+z}{2}\ge\dfrac{2019}{2}\)

áp dụng BĐT:\(\dfrac{a^2}{x}+\dfrac{b^2}{y}+\dfrac{c^2}{z}\) với a,b,c,x,y,z là số dương

ta có BĐT Bunhiacopxki cho 3 bộ số:\(\left(\dfrac{a}{\sqrt{x}};\sqrt{x}\right);\left(\dfrac{b}{\sqrt{y}};\sqrt{y}\right);\left(\dfrac{c}{\sqrt{z}};\sqrt{z}\right)\)

ta có :

\(\dfrac{a^2}{x}+\dfrac{b^2}{y}+\dfrac{c^2}{z}\left(x+y+z\right)\)\(=\left[\left(\dfrac{a}{\sqrt{x}}\right)^2+\left(\dfrac{b}{\sqrt{y}}\right)^2+\left(\dfrac{c}{\sqrt{z}}\right)^2\right]\).\(\left[\left(\sqrt{x}\right)^2+\left(\sqrt{y}\right)^2+\left(\sqrt{z}\right)^2\right]\)\(\ge\left(\dfrac{a}{\sqrt{x}}.\sqrt{x}+\dfrac{b}{\sqrt{y}}.\sqrt{y}+\dfrac{c}{\sqrt{z}}.\sqrt{z}\right)^2=\left(a+b+c\right)^2\)

lúc đó ta có :\(\dfrac{a^2}{x}+\dfrac{b^2}{y}+\dfrac{c^2}{z}\ge\dfrac{\left(a+b+c\right)^2}{x+y+z}\)

ta có \(T=\dfrac{x^2}{x+\sqrt{yz}}+\dfrac{y^2}{y+\sqrt{zx}}+\dfrac{z^2}{z+\sqrt{xy}}\)\(\ge\dfrac{\left(x+y+z\right)^2}{x+\sqrt{yz}+y+\sqrt{zx}+z+\sqrt{xy}}\) mà ta có :

\(\sqrt{yz}+\sqrt{zx}+\sqrt{xy}\)\(\le\dfrac{x+y}{2}+\dfrac{x+z}{2}+\dfrac{z+y}{2}\)\(\Rightarrow\sqrt{yz}+\sqrt{zx}+\sqrt{xy}\le x+y+z\)

\(\Rightarrow T=\dfrac{2019}{2}\Leftrightarrow x=y=z=673\)

vậy \(\text{MinT}=\dfrac{2019}{2}\) khi và chỉ khi x=y=z=673

Lời giải:

Sửa: $x^2\geq y^2+z^2$
Áp dụng BĐT Cauchy-Schwarz:

$P\geq \frac{y^2+z^2}{x^2}+\frac{7x^2}{2}.\frac{4}{y^2+z^2}+2007$

$=\frac{y^2+z^2}{x^2}+\frac{14x^2}{y^2+z^2}+2007$

$=\frac{y^2+z^2}{x^2}+\frac{x^2}{y^2+z^2}+\frac{13x^2}{y^2+z^2}+2007$

$\geq 2+\frac{13x^2}{y^2+z^2}+2007$ (áp dụng BĐT Cô-si)

$\geq 2+13+2007=2022$ (do $x^2\geq y^2+z^2$)

Vậy $P_{\min}=2022$

\(M=\dfrac{1}{16}\left(\dfrac{1}{x^2}+\dfrac{4}{y^2}+\dfrac{16}{z^2}\right)\ge\dfrac{1}{16}.\dfrac{\left(1+2+4\right)^2}{\left(x^2+y^2+z^2\right)}=\dfrac{49}{16}\)

\(\Rightarrow M_{min}=\dfrac{49}{16}\) khi \(\left\{{}\begin{matrix}x^2=\dfrac{1}{7}\\y^2=\dfrac{2}{7}\\z^2=\dfrac{4}{7}\end{matrix}\right.\)

Từ \(x\left(\dfrac{1}{y}+\dfrac{1}{z}\right)+y\left(\dfrac{1}{z}+\dfrac{1}{x}\right)+z\left(\dfrac{1}{x}+\dfrac{1}{y}\right)=-2\) ta có:

\(x^2y+y^2z+z^2x+xy^2+yz^2+zx^2+2xyz=0\)

\(\Leftrightarrow\left(x+y\right)\left(y+z\right)\left(z+x\right)=0\)

\(\Leftrightarrow\left[{}\begin{matrix}x+y=0\\y+z=0\\z+x=0\end{matrix}\right.\).

Không mất tính tổng quát, giả sử x + y = 0

\(\Leftrightarrow x=-y\)

\(\Leftrightarrow x^3=-y^3\).

Kết hợp với \(x^3+y^3+z^3=1\) ta có \(z^3=1\Leftrightarrow z=1\).

Vậy \(P=\dfrac{1}{x}+\dfrac{1}{y}+\dfrac{1}{z}=\dfrac{1}{-y}+\dfrac{1}{y}+\dfrac{1}{1}=1\).