The number of positive integers satisfying the inequality `C(n+1,n-2) - C(n+1,n-1)<=100` is

The number of positive integers satisfying the inequality : ""^(n+1)C_(n-2)-""^(n+1)C_(n-1)le100 is :

The numbers 1,3,6,10,15,21,28"..." are called triangular numbers. Let t_(n) denote the n^(th) triangular number such that t_(n)=t_(n-1)+n,AA n ge 2 . The number of positive integers lying between t_(100) and t_(101) are:

The positive integer value of n >3 satisfying the equation 1/(sin(pi/n))=1/(sin((2pi)/n))+1/(sin((3pi)/n))i s

If n is a positive integer satisfying the equation 2+(6*2^(2)-4*2)+(6*3^(2)-4*3)+"......."+(6*n^(2)-4*n)=140 then the value of n is

Let n denote the number of all n-digit positive integers formed by the digits 0, 1 or both such that no consecutive digits in them are 0. Let b_n = the number of such n-digit integers ending with digit 1 and c_n = the number of such n-digit integers ending with digit 0. The value of b_6 , is

If n is any positive integer then the value of (i^(4 n+1)-i^(4 m-1))/(2)=

If, for a positive integer n , the quadratic equation, x(x+1)+(x-1)(x+2)++(x+ n-1)(x+n)=10 n has two consecutive integral solutions, then n is equal to : (1) 10 (2) 11 (3) 12 (4) 9

Number of positive terms in the sequence x_n=195/(4.np_n)-(n+3p_3)/(n+1p_(n+1)), n in N (here p_n=|anglen )

If n is a positive integer, then (1+i)^(n)+(1-i)^(n)=

If there are three square matrix A, B, C of same order satisfying the equation A^2=A^-1 and B=A^(2^n) and C=A^(2^((n-2)) , then prove that det .(B-C) = 0, n in N .