a) Tìm tất cả các số tự nhiên \(k\) sao cho \(2k+1\) và \(4k+1\) đều là các số chính phương.
b) Với mỗi số tự nhiên \(k\) thỏa mãn đề bài, chứng minh rằng \(35|k^2-12k\)
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Ta có \(2\sin x\cos x=\left(\sin x+\cos x\right)^2-\left(\sin^2x+\cos^2x\right)\)
\(=\left(\dfrac{3}{4}\right)^2-1=-\dfrac{7}{16}\)
Từ đó \(A=\left|\sin x-\cos x\right|\)
\(\Rightarrow A^2=\left(\sin x-\cos x\right)^2\)
\(A^2=\sin^2x+\cos^2x-2\sin x\cos x\)
\(A^2=1+\dfrac{7}{16}=\dfrac{23}{16}\)
\(\Rightarrow A=\dfrac{\sqrt{23}}{4}\) (do \(A\ge0\))
Có \(\cos x+\sin x=\dfrac{3}{4}\)
\(\Leftrightarrow\left(\cos x+\sin x\right)^2=\dfrac{9}{16}\)
\(\Leftrightarrow2.\sin x.\cos x+1=\dfrac{9}{16}\)
\(\Leftrightarrow\sin x.\cos x=-\dfrac{7}{32}\)
Lại có \(\left(\cos x+\sin x\right)^2=\left(\cos x-\sin x\right)^2+4.\sin x.\cos x=\dfrac{9}{16}\)
\(\Leftrightarrow\left(\cos x-\sin x\right)^2=\dfrac{23}{16}\)
\(\Leftrightarrow\left|\sin x-\cos x\right|=\dfrac{\sqrt{23}}{4}\)
Mình sửa lại đề bài là AB cắt CD tại T chứ không phải là AD cắt BC đâu.
\(a,cos\alpha=\dfrac{5}{13}\)
\(sin\alpha=\sqrt{1-cos^2\alpha}=\sqrt{1-\left(\dfrac{5}{13}\right)^2}=\dfrac{12}{13}\)
\(1+tan^2\alpha=\dfrac{1}{cos^2\alpha}\Leftrightarrow1+tan^2\alpha=\dfrac{1}{\left(\dfrac{5}{13}\right)^2}\Leftrightarrow tan^2\alpha=\dfrac{144}{25}\Leftrightarrow tan\alpha=\dfrac{12}{5}\)
\(cot\alpha=\dfrac{1}{tan\alpha}=1:\dfrac{12}{5}=\dfrac{5}{12}\)
\(b,sin\alpha=\dfrac{7}{12}\)
\(cos\alpha=\sqrt{1-sin^2\alpha}=\sqrt{1-\left(\dfrac{7}{12}\right)^2}=\dfrac{\sqrt{95}}{12}\)
\(1+tan^2\alpha=\dfrac{1}{cos^2\alpha}\Leftrightarrow1+tan^2\alpha=\dfrac{1}{\left(\dfrac{\sqrt{95}}{12}\right)^2}\Leftrightarrow tan\alpha=\dfrac{49}{95}\)
\(cot\alpha=1:\dfrac{49}{95}=\dfrac{95}{49}\)
\(c,tan\alpha=\dfrac{15}{4}\)
\(cot\alpha=1:\dfrac{15}{4}=\dfrac{4}{15}\)
\(1+tan^2\alpha=\dfrac{1}{cos^2\alpha}\Leftrightarrow1+\left(\dfrac{15}{4}\right)^2=\dfrac{1}{cos^2\alpha}\Leftrightarrow cos\alpha=\sqrt{\dfrac{16}{241}}\)
\(sin\alpha=\sqrt{1-cos^2\alpha}=\sqrt{1-\left(\sqrt{\dfrac{16}{241}}\right)^2}\approx0,97\)
\(d,cot\alpha=-\dfrac{1}{\sqrt{3}}\\ tan\alpha=1:\left(-\dfrac{1}{\sqrt{3}}\right)=-\sqrt{3}\)
\(1+tan^2\alpha=\dfrac{1}{cos^2\alpha}\Leftrightarrow1+\left(-\sqrt{3}\right)^2=\dfrac{1}{cos^2\alpha}\Leftrightarrow cos\alpha=\dfrac{1}{2}\)
\(sin\alpha=\sqrt{1-\left(\dfrac{1}{2}\right)^2}=\dfrac{\sqrt{3}}{2}\)
Ta có xn luôn dương
Ta có \(2x_n+1=\) \(2\times\dfrac{\left(2+cos\alpha\right)x_n+cos^2\alpha}{\left(2-2cos2\alpha\right)x_n+2-cos2\alpha}+1=\)
\(=\dfrac{6x_n+2cos^2\alpha+2-cos2\alpha}{\left(2-2cos2\alpha\right)x_n+2-cos2\alpha}\)
\(=\dfrac{6x_n+2cos^2\alpha+2sin^2a+1}{\left(2x_n+1\right)\left(1-cos2\alpha\right)+1}\)
\(=\dfrac{3\left(2x_n+1\right)}{2\sin^2\alpha\left(2x_n+1\right)+1}\)
\(\Rightarrow\dfrac{1}{2x_{n+1}+1}=\dfrac{2\sin^2\alpha\left(2x_n+1\right)+1}{3\left(2x_n+1\right)}\)
\(=\dfrac{1}{3}\left(2\sin^2\alpha+\dfrac{1}{2x_n+1}\right)\)
\(\Rightarrow\dfrac{1}{2x_{n+1}+1}-\sin^2\alpha=\dfrac{1}{3}\left(\dfrac{1}{2x_n+1}-\sin^2\alpha\right)\)
\(\Rightarrow\dfrac{1}{2x_{n+1}+1}-\sin^2\alpha=\left(\dfrac{1}{3}\right)^n\left(\dfrac{1}{2x_1+1}-\sin^2\alpha\right)\)
\(=\left(\dfrac{1}{3}\right)^n\left(\dfrac{1}{3}-\sin^2\alpha\right)\)
\(\Rightarrow y_n=\sum\limits^{n-1}_{i=0}\left(\dfrac{1}{3}\right)^i\left(\dfrac{1}{3}-\sin^2\alpha\right)+n\sin^2\alpha\)
\(=\dfrac{1-\left(\dfrac{1}{3}\right)^n}{1-\dfrac{1}{3}}\left(\dfrac{1}{3}-\sin^2\alpha\right)+n\sin^2\alpha\)
Ta có \(\overrightarrow{BH}=\overrightarrow{BC}+\overrightarrow{CH}=-\overrightarrow{CB}+\dfrac{1}{2}\overrightarrow{CA}\)
\(\overrightarrow{MH}=\dfrac{1}{2}\overrightarrow{BA}=\dfrac{1}{2}\left(\overrightarrow{BC}+\overrightarrow{CA}\right)=\dfrac{1}{2}\overrightarrow{CA}-\dfrac{1}{2}\overrightarrow{CB}\)
\(x_1=a>2;x_{n+1}=x_n^2-2,\forall n=1,2,...\)
mà \(n\rightarrow+\infty\)
\(\Rightarrow a\rightarrow+\infty\Rightarrow x_n\rightarrow+\infty\)
\(\Rightarrow\lim\limits_{n\rightarrow+\infty}\dfrac{1}{x_n}=0\) \(\Rightarrow\lim\limits_{n\rightarrow+\infty}\left(\dfrac{1}{x_nx_{n+1}}\right)=0\)
\(\)\(\Rightarrow\lim\limits_{n\rightarrow+\infty}\left(\dfrac{1}{x_1}+\dfrac{1}{x_1x_2}+\dfrac{1}{x_1x_2x_3}+...+\dfrac{1}{x_1x_2...x_n}\right)=0\)
Hiện tại sách là chương trình mới những vẫn không có PowerPoint bạn nha. Nên hiện tại chưa biết được khi nào sẽ có PowerPoint, nhưng ở các lớp dưới thì cũng đã học rồi á bạn.
Theo chương trình sgk mới thì lớp 7, lớp 8 có học PowerPoint. Lớp 11 thì chưa có em nhé!
\(a,-125^o=\dfrac{\pi.\left(-125\right)}{180}rad=-\dfrac{25\pi}{36}rad\\ b,42^o=\dfrac{\pi.42}{180}rad=\dfrac{7\pi}{30}rad\)
\(tanx=\dfrac{1}{cotx}=\dfrac{1}{\sqrt[]{2}}=\dfrac{\sqrt[]{2}}{2}\left(tanx.cotx=1\right)\)
\(1+tan^2x=\dfrac{1}{cos^2x}\Rightarrow cos^2x=\dfrac{1}{1+tan^2x}=\dfrac{1}{1+\dfrac{1}{2}}\)
\(\Rightarrow cos^2x=\dfrac{2}{3}\Rightarrow cosx=\sqrt[]{\dfrac{2}{3}}\)
\(tanx=\dfrac{sinx}{cosx}\Rightarrow sinx=tanx.cosx=\dfrac{1}{\sqrt[]{2}}.\dfrac{\sqrt[]{2}}{\sqrt[]{3}}=\dfrac{\sqrt[]{3}}{3}\)
\(P=\dfrac{3sinx-2cosx}{12sin^3x+4cos^3x}=\dfrac{3.\dfrac{\sqrt[]{3}}{3}-2.\dfrac{\sqrt[]{2}}{\sqrt[]{3}}}{12.\left(\dfrac{\sqrt[]{3}}{3}\right)^3+4.\left(\sqrt[]{\dfrac{2}{3}}\right)^3}\)
\(=\dfrac{\sqrt[]{3}-\dfrac{2\sqrt[]{6}}{3}}{12.\left(\dfrac{\sqrt[]{3}}{3}\right)^3+4.\left(\sqrt[]{\dfrac{2}{3}}\right)^3}\)