Question 1

For positive integer n, defined

$\rm f(n) = n + \frac{16 + 5n - 3 {n}^(2) }{4n + 3 {n}^(2) } + \frac{32 + n - 3 {n}^(2) }{8n + {3n}^(2) } + \frac{48 - 3n - 3 {n}^(2) }{1 2n+3 {n}^(2) } + \cdots + \frac{25 {n} - 7n^(2) }{7 {n}^(2) }$
Then, the value of
$\displaystyle\rm\lim_(n \to \infty )$ is equal to

Question 2

Following the first term
, the
-th term
$\left(k\in\{1,2,3,\ldots,n\}\right)$ in
f(n) is given by

(16k + (9-4k)n - 3n^2)/(4kn + 3n^2)

That is,

$k=1 \implies (16 + (9-4)n - 3n^2)/(4n + 3n^2) = (16 + 5n - 3n^2)/(4n + 3n^2)$

$k=2 \implies (16\cdot2 + (9-8)n - 3n^2)/(4\cdot2n + 3n^2) = (32 + n - 3n^2)/(8n + 3n^2)$

and so on, up to

$k=n \implies (16n + (9-4n)n - 3n^2)/(4n^2 + 3n^2) = (25n - 7n^2)/(7n^2)$

We then have

$\displaystyle f(n) = n + \sum_(k=1)^n (16k + (9-4k)n - 3n^2)/(4kn + 3n^2) \\\\ ~~~~~~~ = n + \frac1n \sum_(k=1)^n (16\frac kn + 9)/(4\frac kn + 3) - \frac1n \sum_(k=1)^n (4kn + 3n^2)/(4k + 3n) \\\\ ~~~~~~~ = n + \frac1n \sum_(k=1)^n (16\frac kn + 9)/(4\frac kn + 3)- \frac1n \sum_(k=1)^n n \\\\ ~~~~~~~ = \frac1n \sum_(k=1)^n (16\frac kn + 9)/(4\frac kn + 3)$

Now as
$n\to\infty$ , the right side converges to a definite integral.

$\displaystyle \lim_(n\to\infty) f(n) = \lim_(n\to\infty) \frac1n \sum_(k=1)^n (16\frac kn + 9)/(4\frac kn + 3) \\\\ ~~~~~~~~~~~~~ \,= \int_0^1 (16x + 9)/(4x + 3) \, dx$

Wrap up by substituting
$x\mapsto\frac{x-3}4$ .

$\displaystyle \lim_(n\to\infty) f(n) = \frac14 \int_0^1 (16x + 9)/(4x + 3) \, dx \\\\ ~~~~~~~~~~~~~\, = \frac14 \int_3^7 \frac{4x - 3}x \, dx \\\\ ~~~~~~~~~~~~~\, = \frac14 \int_3^7 \left(4 - \frac3x\right) \, dx \\\\ ~~~~~~~~~~~~~\, = \left. \frac14 (4x - 3\ln|x|) \right\vert_3^7\\\\ ~~~~~~~~~~~~~\, = \boxed{4 + \frac34 \ln\left(\frac37\right)}$

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