1/ \(2C^k_n+5C^{k+1}_n+4C^{k+2}_n+C^{k+3}_n\)

\(=2\left(C^k_n+C_n^{k+1}\right)+3\left(C^{k+1}_n+C^{k+2}_n\right)+\left(C^{k+2}_n+C^{k+3}_n\right)\)

\(=2C_{n+1}^{k+1}+3C_{n+1}^{k+2}+C_{n+1}^{k+3}\)

\(=2\left(C_{n+1}^{k+1}+C_{n+1}^{k+2}\right)+\left(C_{n+1}^{k+2}+C^{k+3}_{n+1}\right)\)

\(=2C_{n+2}^{k+2}+C_{n+2}^{k+3}=C_{n+2}^{k+2}+\left(C_{n+2}^{k+2}+C_{n+2}^{k+3}\right)=C_{n+2}^{k+2}+C_{n+3}^{k+3}\)

Áp dụng ct:C(k)(n)=C(k)(n-1)+C(k-1)(n-1) có:
................C(k-1)(n-1)= C(k)(n) - C(k)(n-1)
tương tự: C(k-1)(n-2)= C(k)(n-1) - C(k)(n-2)
................C(k-1)(n-3)= C(k)(n-2) -C(k)(n-3)
.........................................
................C(k-1)(k-1)= C(k)(k) (=1)
Cộng 2 vế vào với nhau...-> đpcm

Xét khai triển:

\(\left(1+2x\right)^{2n+1}=C_{2n+1}^0+C_{2n+1}^1.2x+C_{2n+1}^2\left(2x\right)^2+...+C_{2n+1}^{2n+1}\left(2x\right)^{2n+1}\)

Đạo hàm 2 vế:

\(2\left(2n+1\right)\left(1+2x\right)^{2n}=2C_{2n+1}^1+2^2C_{2n+1}^2x+...+\left(2n+1\right)2^{2n+1}C_{2n+1}^{2n+1}x^{2n}\)

\(\Leftrightarrow\left(2n+1\right)\left(1+2x\right)^{2n}=C_{2n+1}^1+2C_{2n+1}^2x+...+\left(2n+1\right)2^{2n}C_{2n+1}^{2n+1}x^{2n}\)

Cho \(x=-1\) ta được:

\(2n+1=C_{2n+1}^1-2C_{2n+1}^2+...+\left(2n+1\right)2^{2n}C_{2n+1}^{2n+1}\)

\(\Rightarrow2n+1=2019\Rightarrow n=1009\)

chỗ nào không cứ hỏi mình nhé

Lời giải:

Theo nhị thức Newton:

$C^k_{2016}$ chính là hệ số của $x^k$ trong khai triển $(x+1)^{2016}(*)$

Lại có:

$(x+1)^{2016}=(x+1)^5.(x+1)^{2011}$

\(=(\sum \limits_{i=0}^5C^i_5x^i)(\sum \limits_{j=0}^{2011}C^i_{2011}x^j)\)

Hệ số $x^k$ trong khai triển này tương ứng với $0\leq i\leq 5; 0\leq j\leq 2011$ thỏa mãn $i+j=k$

Hay hệ số của $x^k$ trong khai triển $(x+1)^{2016}$ là:

$C^0_5.C^k_{2011}+C^1_5.C^{k-1}_{2011}+C^2_5C^{k-2}_{2011}+C^3_5.C^{k-3}_{2011}+C^4_5.C^{k-4}_{2011}+C^5_5.C^{k-5}_{2011}(**)$

Từ $(*); (**)$ ta có đpcm.

\(C_{14}^k+C_{14}^{k+2}=2C_{14}^{k+1}\)

\(\Leftrightarrow\dfrac{14!}{\left(14-k\right)!k!}+\dfrac{14!}{\left(12-k\right)!\left(k+2\right)!}=\dfrac{2.14!}{\left(13-k\right)!\left(k+1\right)!}\)

\(\Leftrightarrow\dfrac{14!}{k!\left(12-k\right)!}\left[\dfrac{1}{\left(14-k\right)\left(13-k\right)}+\dfrac{1}{\left(k+1\right)\left(k+2\right)}\right]=\dfrac{2}{\left(13-k\right)\left(k+1\right)}.\dfrac{14!}{k!\left(12-k\right)!}\)

\(\Leftrightarrow\dfrac{2k^2-24k+184}{\left(14-k\right)\left(k+2\right)\left(13-k\right)\left(k+1\right)}=\dfrac{2}{\left(13-k\right)\left(k+1\right)}\)

\(\Leftrightarrow\dfrac{k^2-12k+92}{-k^2+12k+28}=1\)

\(\Leftrightarrow k^2-12k+92=-k^2+12k+28\)

\(\Leftrightarrow k^2-12k+32=0\)

\(\Leftrightarrow\left[{}\begin{matrix}k=4\\k=8\end{matrix}\right.\)

đề bảo là cm hay tìm k

Xét khai triển:

\(\left(1+x\right)^{2017}=C_{2017}^0+xC_{2017}^1+x^2C_{2017}^2+...+x^{2017}C_{2017}^{2017}\)

Lấy tích phân 2 vế:

\(\int\limits^1_0\left(1+x\right)^{2017}=\int\limits^1_0\left(C_{2017}^0+xC_{2017}^1+...+x^{2017}C_{2017}^{2017}\right)\)

\(\Leftrightarrow\dfrac{2^{2018}-1}{2018}=C_{2017}^0+\dfrac{1}{2}C_{2017}^1+...+\dfrac{1}{2018}C_{2017}^{2017}\)

Vậy \(S=\dfrac{2^{2018}-1}{2018}\)