Câu 1:

\(S_8=u_1+u_2+u_3+...+u_8\)

\(=\dfrac{u_1\left(1-q^8\right)}{1-q}=\dfrac{2048\cdot\left(1-\left(\dfrac{5}{4}\right)^8\right)}{1-\dfrac{5}{4}}\)

\(=\dfrac{325089}{8}\)

2: \(S_{10}=u_1+u_2+...+u_9+u_{10}\)

=>\(S_{10}=\dfrac{u_1\left(1-q^{10}\right)}{1-q}=\dfrac{-3\cdot\left(1-\left(\dfrac{1}{2}\right)^{10}\right)}{1-\dfrac{1}{2}}\)

\(=-6\cdot\left(1-\dfrac{1}{2^{10}}\right)=-6+\dfrac{6}{2^{10}}=-\dfrac{3069}{512}\)

Đặt \(u_n+\dfrac{5}{4}=v_n\)

\(GT\Rightarrow\left\{{}\begin{matrix}v_1=\dfrac{9}{4};v_2=\dfrac{13}{4}\\v_{n+2}=2v_{n+1}+3v_n\end{matrix}\right.\)

Ta có CTTQ của dãy \(\left(v_n\right)\) là:

\(v_n=\dfrac{11}{24}.3^n-\dfrac{7}{8}.\left(-1\right)^n\)

(Bạn tự chứng minh theo quy nạp)

\(\Rightarrow u_n=\dfrac{11}{24}.3^n-\dfrac{7}{8}\left(-1\right)^n-\dfrac{5}{4}\) với \(\forall n\in N\text{*}\)

\(\Rightarrow S=2\left(u_1+u_2+...+u_{100}\right)+u_{101}\)

\(=\left[\dfrac{11}{12}\left(3^1+3^2+...+3^{100}\right)-\dfrac{7}{4}\left(-1+1-...+1\right)-\dfrac{5}{2}.100\right]+\dfrac{11}{24}.3^{101}-\dfrac{7}{8}.\left(-1\right)^{101}-\dfrac{5}{4}\)

\(=\dfrac{11}{12}.\dfrac{3^{101}-3}{2}-250+\dfrac{11}{24}.3^{101}+\dfrac{7}{8}\)

\(=\dfrac{11}{24}.\left(2.3^{101}-3\right)-\dfrac{1993}{8}\)

\(=\dfrac{11}{4}.3^{100}-\dfrac{501}{2}\)

1:

\(S_{10}=\dfrac{u_1\cdot\left(1-q^{10}\right)}{1-q}=\dfrac{-3\cdot\left(1-\dfrac{1}{1024}\right)}{1-\dfrac{1}{2}}\)

\(=-6\cdot\dfrac{1023}{1024}=\dfrac{-3069}{512}\)

2:

\(\left\{{}\begin{matrix}u1=6\\u2=18\end{matrix}\right.\Leftrightarrow\left\{{}\begin{matrix}u1=6\\u1\cdot q=18\end{matrix}\right.\Leftrightarrow\left\{{}\begin{matrix}u1=6\\q=3\end{matrix}\right.\)

\(S_{12}=\dfrac{u_1\left(1-q^{12}\right)}{1-q}=\dfrac{6\cdot\left(1-3^{12}\right)}{1-3}=-3\cdot\left(1-3^{12}\right)\)

\(=3^{13}-3\)

bỏ ghim chh giùm kon, sợ quá:<

 Dễ thấy \(u_n>0,\forall n\inℕ^∗\). 

 Ta có \(u_{n+1}-u_n=\dfrac{u_n^2+2021}{2u_n}-u_n=\dfrac{2021-u_n^2}{2u_n}\)

 Với \(n\ge2\) thì \(u_n=\dfrac{u_{n-1}^2+2021}{2u_{n-1}}\) \(=\dfrac{u_{n-1}}{2}+\dfrac{2021}{2u_{n-1}}\) \(>2\sqrt{\dfrac{u_{n-1}}{2}.\dfrac{2021}{2u_{n-1}}}\) \(=\sqrt{2021}\)

Vậy \(u_n>\sqrt{2021},\forall n\ge2\), suy ra \(u_{n+1}-u_n=\dfrac{2021-u_n^2}{2u_n}< 0,\forall n\inℕ^∗\)

\(\Rightarrow\) Dãy \(\left(u_n\right)\) là dãy giảm. Mà \(u_n>\sqrt{2021}\)  \(\Rightarrow\left(u_n\right)\) có giới hạn hữu hạn. Đặt \(\lim\limits_{n\rightarrow+\infty}u_n=L\) \(\Rightarrow L=\dfrac{L^2+2021}{2L}\) \(\Leftrightarrow L=\sqrt{2021}\)

 Vậy \(\lim\limits_{n\rightarrow+\infty}u_n=\sqrt{2021}\)

Dễ thấy $u^n>0,\forall n\in N^{\ast }$. 

 Ta có $u^{n+1}-u^n=\genfrac{}{}{0ex}{}{u^n+2021}{2u^n}-u^n=\genfrac{}{}{0ex}{}{2021-u^n}{2u^n}$

 Với $n\ge 2$ thì $u^n=\genfrac{}{}{0ex}{}{u^{n-1}+2021}{2u^{n-1}}$ $=\genfrac{}{}{0ex}{}{u^{n-1}}{2}+\genfrac{}{}{0ex}{}{2021}{2u^{n-1}}$ $>2\sqrt{\genfrac{}{}{0ex}{}{u^{n-1}}{2}.\genfrac{}{}{0ex}{}{2021}{2u^{n-1}}}$ $=\sqrt{2021}$

Vậy $u^n>\sqrt{2021},\forall n\ge 2$, suy ra $u^{n+1}-u^n=\genfrac{}{}{0ex}{}{2021-u^n}{2u^n}<0,\forall n\in N^{\ast }$

$\Rightarrow$ Dãy $\left(u^n\right)$ là dãy giảm. Mà $u^n>\sqrt{2021}$  $\Rightarrow \left(u^n\right)$ có giới hạn hữu hạn. Đặt $\stackrel{\lim }{n\to +\infty }{u}^n=L$ $\Rightarrow L=\genfrac{}{}{0ex}{}{L^2+2021}{2L}$ $\iff L=\sqrt{2021}$

 Vậy $\stackrel{\lim }{n\to +\infty }{u}^n=\sqrt{2021}$
 

Ta có: \(u_n>2020\) với mọi \(n\in N\text{*}\) \(\left(\text{*}\right)\)

Thật vậy, dễ thấy \(u_1=2021>2020\)

Giả sử \(\left(\text{*}\right)\) đúng với \(n=k\left(k\ge1\right)\)

\(\Rightarrow u_k>2020\)\(\Rightarrow u_{k+1}=\left[1-\dfrac{1}{\left(k+1\right)^2}\right]u_k+\dfrac{2020}{\left(k+1\right)^2}\)

\(>\left[1-\dfrac{1}{\left(k+1\right)^2}\right].2020+\dfrac{2020}{\left(k+1\right)^2}=2020\)

\(\Rightarrow\left(\text{*}\right)\) đúng với \(n=k+1\)

Do đó theo nguyên lý quy nạp ta có đpcm.

Lại có:

\(u_{n+1}-u_n=\dfrac{2020}{\left(n+1\right)^2}-\dfrac{u_n}{\left(n+1\right)^2}< 0\) với mọi \(n\in N\text{*}\)

\(\Rightarrow\left(u_n\right)\) là dãy giảm

\(\left(u_n\right)\) là dãy giảm và bị chặn nên \(\left(u_n\right)\) là dãy hội tụ

Đặt \(limu_n=L\)

\(\Rightarrow\left\{{}\begin{matrix}2020\le L\le2021\\L=\left[1-\dfrac{1}{\left(n+1\right)^2}\right].L+\dfrac{2020}{\left(n+1\right)^2}\end{matrix}\right.\)\(\Rightarrow L=2020\left(tm\right)\)

Vậy \(limu_n=2020\)

Ta có: \(u_n>2020\) với mọi \(n\in N\text{*}\) \(\left(\text{*}\right)\)

Thật vậy, dễ thấy \(u_1=2021>2020\)

Giả sử \(\left(\text{*}\right)\) đúng với \(n=k\left(k\ge1\right)\)

\(\Rightarrow u_k>2020\)\(\Rightarrow u_{k+1}=\left[1-\dfrac{1}{\left(k+1\right)^2}\right]u_k+\dfrac{2020}{\left(k+1\right)^2}\)

\(>\left[1-\dfrac{1}{\left(k+1\right)^2}\right].2020+\dfrac{2020}{\left(k+1\right)^2}=2020\)

\(\Rightarrow\left(\text{*}\right)\) đúng với \(n=k+1\)

Do đó theo nguyên lý quy nạp ta có đpcm.

Lại có:

\(u_{n+1}-u_n=\dfrac{2020}{\left(n+1\right)^2}-\dfrac{u_n}{\left(n+1\right)^2}< 0\) với mọi \(n\in N\text{*}\)

\(\Rightarrow\left(u_n\right)\) là dãy giảm

\(\left(u_n\right)\) là dãy giảm và bị chặn nên \(\left(u_n\right)\) là dãy hội tụ

Đặt \(limu_n=L\)

\(\Rightarrow\left\{{}\begin{matrix}2020\le L\le2021\\L=\left[1-\dfrac{1}{\left(n+1\right)^2}\right].L+\dfrac{2020}{\left(n+1\right)^2}\end{matrix}\right.\)\(\Rightarrow L=2020\left(tm\right)\)

Vậy \(limu_n=2020\)