cho 2n số thực : \(a_1,a_2,...,a_n;b_1,b_2,...,b_n\)
CMR : \(\left|a_1b_1+...+a_nb_n\right|\le\sqrt{\left(a_1^2+...+a_n^2\right)\left(b_1^2+...+b_n^2\right)}\)
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\(\dfrac{a_1}{2-a_1}+\dfrac{a_2}{2-a_2}+...+\dfrac{a_n}{2-a_n}\ge\dfrac{n}{2n-1}\)
\(\Leftrightarrow\dfrac{a^2_1}{2a_1-a^2_1}+\dfrac{a^2_2}{2a_2-a^2_2}+...+\dfrac{a^2_n}{2a_n-a^2_2}\ge\dfrac{n}{2n-1}\)
Áp dụng bất đẳng thức cộng mẫu số
\(\Rightarrow\dfrac{a^2_1}{2a_1-a^2_1}+\dfrac{a^2_2}{2a_2-a^2_2}+...+\dfrac{a^2_n}{2a_n-a^2_2}\ge\dfrac{\left(a_1+a_2+...+a_n\right)^2}{2\left(a_1+a_2+...+a_n\right)-\left(a^2_1+a^2_2+...+a_n^2\right)}\)
\(\Rightarrow\dfrac{a^2_1}{2a_1-a^2_1}+\dfrac{a^2_2}{2a_2-a^2_2}+...+\dfrac{a^2_n}{2a_n-a^2_2}\ge\dfrac{1}{2-\left(a^2_1+a^2_2+...+a_n^2\right)}\)
Chứng minh rằng \(\dfrac{1}{2-\left(a^2_1+a_2^2+...+a^2_n\right)}\ge\dfrac{n}{2n-1}\)
\(\Leftrightarrow2n-1\ge n\left[2-\left(a^2_1+a^2_2+...+a^2_n\right)\right]\)
\(\Leftrightarrow2n-1\ge2n-n\left(a^2_1+a^2_2+...+a^2_n\right)\)
\(\Leftrightarrow-1\ge-n\left(a^2_1+a^2_2+...+a^2_n\right)\)
\(\Leftrightarrow1\le n\left(a^2_1+a^2_2+...+a^2_n\right)\)
\(\Leftrightarrow\dfrac{1}{n}\le a^2_1+a^2_2+...+a^2_n\)
Áp dụng bất đẳng thức cộng mẫu số
\(\Rightarrow VP=\dfrac{a^2_1}{1}+\dfrac{a^2_2}{1}+...+\dfrac{a^2_n}{1}\ge\dfrac{\left(a_1+a_2+...+a_n\right)^2}{n}=\dfrac{1}{n}\)
\(\Rightarrow\) đpcm
Vậy \(\dfrac{1}{2-\left(a^2_1+a_2^2+...+a^2_n\right)}\ge\dfrac{n}{2n-1}\)
\(\Rightarrow\dfrac{a_1}{2-a_1}+\dfrac{a_2}{2-a_2}+...+\dfrac{a_n}{2-a_n}\ge\dfrac{n}{2n-1}\) ( đpcm )
mày bị điên đứa nào thích thì mà đứa nào chơi truy kích cho tao nick
a) Đặt \(d=\left(a_1,a_2,...,a_n\right)\Rightarrow\left\{{}\begin{matrix}a_1=dx_1\\a_2=dx_2\\...\\a_n=dx_n\end{matrix}\right.\) (với \(\left(x_1,x_2,...,x_n\right)=1\)).
Ta có \(A_i=\dfrac{A}{a_i}=\dfrac{d^nx_1x_2...x_n}{dx_i}=d^{n-1}\dfrac{x_1x_2...x_n}{x_i}=d^{n-1}B_i\forall i\in\overline{1,n}\).
Từ đó \(\left[A_1,A_2,...,A_n\right]=d^{n-1}\left[B_1,B_2,...,B_n\right]\).
Mặt khác do \(\left(x_1,x_2,...,x_n\right)=1\Rightarrow\left[B_1,B_2,...B_n\right]=x_1x_2...x_n\).
Vậy \(\left(a_1,a_2,...,a_n\right)\left[A_1,A_2,...,A_n\right]=d.d^{n-1}x_1x_2...x_n=d^nx_1x_2...x_n=A\).
\(S-P=a_1^3-a_1+a_2^3-a_2+...+a_n^3-a_n\)
\(=a_1\left(a_1-1\right)\left(a_1+1\right)+a_2\left(a_2-1\right)\left(a_2+1\right)+...+a_n\left(a_n-1\right)\left(a_n+1\right)\)
Do \(a_k\left(a_k-1\right)\left(a_k+1\right)\) là tích 3 số nguyên liên tiếp nên luôn chia hết cho 6
\(\Rightarrow S-P⋮6\)
Mà \(P⋮6\Rightarrow S⋮6\)
\(A_n=\dfrac{\sqrt{2n-1}}{\left(2n+1\right)\left(2n-1\right)}=\dfrac{\sqrt{2n-1}}{2}\left(\dfrac{1}{2n-1}-\dfrac{1}{2n+1}\right)\)
\(=\dfrac{\sqrt{2n-1}}{2}\left(\dfrac{1}{\sqrt{2n-1}}-\dfrac{1}{\sqrt{2n+1}}\right)\left(\dfrac{1}{\sqrt{2n-1}}+\dfrac{1}{\sqrt{2n+1}}\right)\)
\(< \dfrac{\sqrt{2n-1}}{2}\left(\dfrac{1}{\sqrt{2n-1}}-\dfrac{1}{\sqrt{2n+1}}\right)\left(\dfrac{1}{\sqrt{2n-1}}+\dfrac{1}{\sqrt{2n-1}}\right)\)
\(=\dfrac{1}{\sqrt{2n-1}}-\dfrac{1}{\sqrt{2n+1}}\)
\(\Rightarrow A_1+A_2+...+A_n< 1-\dfrac{1}{\sqrt{3}}+\dfrac{1}{\sqrt{3}}-\dfrac{1}{\sqrt{5}}+...+\dfrac{1}{\sqrt{2n-1}}-\dfrac{1}{\sqrt{2n+1}}=1-\dfrac{1}{\sqrt{2n+1}}< 1\)
Cái đầu tiên là \(\sqrt[n]{\frac{a_1^n+a_2^n+a_3^n+...+a_n^n}{n}}\)nhé.
Đặt \(f\left(x\right)=\left(a_1x-b_1\right)^2+...+\left(a_nx-b_n\right)^2\)
\(\Rightarrow f\left(x\right)\ge0\) với mọi x
Mặt khác : \(f\left(x\right)=\left(a_1^2+...+a_n^2\right)x^2-2\left(a_1b_1+...+a_nb_n\right)x+\left(b_1^2+...+b_n^2\right)\)
\(\Rightarrow\Delta'\le0\)
\(\Rightarrow\left(a_1b_1+...+a_nb_n\right)^2\le\left(a_1^2+...+a_n^2\right)\left(b_1^2+...+b_n^2\right)\)
\(\Rightarrow\left|a_1b_1+...+a_nb_n\right|\le\sqrt{\left(a_1^2+...+a_n^2\right)\left(b_{1^{ }}^2+...+b_n^2\right)}\)
Áp dụng bđt bunhia copski, ta có \(\left(a_1b_1+...+a_nb_n\right)^2\le\left(a_1^2+...+a_n^2\right)\left(b_1^2+...+b_2^2\right)\Leftrightarrow\sqrt{\left(a_1b_1+...+a_nb_n\right)^2}\le\sqrt{\left(a_1^2+...+a_n^2\right)\left(b_1^2+...+b_2^2\right)}\Leftrightarrow\left|a_1b_1+...+a_nb_n\right|\le\sqrt{\left(a_1^2+...+a_n^2\right)\left(b_1^2+...+b_2^2\right)}\)
Dấu bằng xảy ra khi \(\dfrac{a_1}{b_1}=...=\dfrac{a_n}{b_n}\)
Vậy \(\left|a_1b_1+...+a_nb_n\right|\le\sqrt{\left(a_1^2+...+a_n^2\right)\left(b_1^2+...+b_2^2\right)}\)