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For each positive integer n, let y(n...

For each positive integer n, let
` y_(n) = 1/n ((n+1)(n+2)…(n+n))^(1/n)`.
For ` x in R`, let [x] be the greatest integer less than or equal to x. If ` lim_( n to infty) y_(n) = L`, then the value of [L] is …………….. .

Text Solution

Verified by Experts

The correct Answer is:
`(1)`
We have,
` y_(n)=1/n [( n+ 1)(n+1)(n+2)...(n+n)]^(1//n) and underset( n to infty) lim y_(n) = L `
` rArr L = underset( n to infty) lim 1/n [(n+1)(n+2)(n+3)...(n+n)]^(1//n) `
` rArr L = underset( n to infty) lim [( 1+1/n)(1+2/n)(1+3/n)...(1+n/n)]^(1/n)`
`rArr log L = underset( n to infty) lim 1/n [log (1+1/n)+ log (1+2/n) ...log(1+n/n)]`
` rArr log L = underset( n to infty) lim 1/n underset( r =1) overset( n) sum log (1+ r/n)`
`rArr log L = int_(0)^(1) underset"II" 1 xx underset("I")log(1+x) dx `
` rArr log L = (x* log (1+ x))_(0)^(1) -int_(0)^(1) [d/(dx)(log(1+x))int dx]dx`
[by using integration by parts]
`rArr log L = [ x log (1+x)]_(0)^(1) - int _(0)^(1) x/(1+x) dx `
` rArr log L = log 2 - int_(0)^(1) ((x+1)/(x+1) -1/(x+1)) dx`
` rArr log L = log 2 - [x]_(0)^(1) + [log(x+1)]_(0)^(1)`
` rArr log L = log 2 -1 + log 2 -0`
` rArr log L = log 4 - log e = log e = log 4/e rArr L = 4/e rArr [L] = [4/e] = 1`
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