A) 10
B) 11
C) 12
D) 13
Correct Answer: B
Solution :
Since the number of students giving wrong answers to at least \[i\] question\[(i=1,\ 2,........,n)={{2}^{n-i}}\]. The number of students answering exactly \[i\ (1\le i\le -1)\] questions wrongly = {the number of students answering at least \[i\] questions wrongly, \[i=1,\ 2,\ .........,n)\}\] - {the number of students answering at least \[(i+1)\] questions wrongly\[(2\le i+1\le n)\}\] \[={{2}^{n-i}}-{{2}^{n-(i+1)}}(1\le i\le n-1)\]. Now, the number of students answering all the \[n\] questions wrongly\[={{2}^{n-n}}={{2}^{0}}\]. Thus the total number of wrong answers \[=1({{2}^{n-1}}-{{2}^{n-2}}+2({{2}^{n-2}}-{{2}^{n-3}})+3({{2}^{n-3}}-{{2}^{n-4}})\] \[+..........+(n-1)({{2}^{1}}-{{2}^{0}})+n({{2}^{0}})\] \[={{2}^{n-1}}+{{2}^{n-2}}+{{2}^{n-3}}+.........+{{2}^{0}}\]=\[{{2}^{n}}-1\] \[(\because \ \text{Its}\ \text{a}\ \text{G}\text{.P}\text{.})\] \[\therefore \] As given \[{{2}^{n}}-1=2047\Rightarrow {{2}^{n}}=2048={{2}^{11}}\]\[\Rightarrow n=11\]You need to login to perform this action.
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