First note that
$$
\eqalign{
& \sum\limits_{1\, \le \,k\, \le \,n} {{k \over {x^{\,k} }}} = \sum\limits_{1\, \le \,k\, \le \,n} {k\left( {{1 \over x}} \right)} ^{\,k} = \sum\limits_{1\, \le \,k\, \le \,n} {k\,y^{\,k} } = \cr
& = y{d \over {dy}}\sum\limits_{1\, \le \,k\, \le \,n} {y^{\,k} } = y{d \over {dy}}\left( {y\sum\limits_{0\, \le \,k\, \le \,n - 1} {y^{\,k} } } \right) = y{d \over {dy}}\left( {y{{1 - y^{\,n} } \over {1 - y}}} \right) = \cr
& = y\left( {{{\left( {1 - y} \right)\left( {1 - \left( {n + 1} \right)y^{\,n} } \right) + \left( {y - y^{\,n + 1} } \right)} \over {\left( {1 - y} \right)^2 }}} \right) = \cr
& = y\left( {{{1 - \left( {n + 1} \right)y^{\,n} + n\,y^{\,n + 1} } \over {\left( {1 - y} \right)^2 }}} \right) = \cr
& = {1 \over x}\left( {{{1 - \left( {n + 1} \right)\left( {1/x} \right)^{\,n} + n\,\left( {1/x} \right)^{\,n + 1} } \over {\left( {1 - 1/x} \right)^2 }}} \right) = \cr
& = {{x^{\,n + 1} - \left( {n + 1} \right)x + n\,} \over {x^{\,n} \left( {x - 1} \right)^2 }} \cr}
$$
Then it follows easily that
$$
\eqalign{
& \sum\limits_{1\, \le \,k\, \le \,n} {{{2 + k} \over {2^{\,k} }}} = \sum\limits_{1\, \le \,k\, \le \,n} {{2 \over {2^{\,k} }}} + \sum\limits_{1\, \le \,k\, \le \,n} {{k \over {2^{\,k} }}} = \cr
& = \sum\limits_{1\, \le \,k\, \le \,n} {\left( {{1 \over 2}} \right)} ^{\,k - 1} + \sum\limits_{1\, \le \,k\, \le \,n} {{k \over {2^{\,k} }}} = \cr
& = \sum\limits_{0\, \le \,k\, \le \,n - 1} {\left( {{1 \over 2}} \right)} ^{\,k} + \sum\limits_{1\, \le \,k\, \le \,n} {{k \over {2^{\,k} }}} = \cr
& = {{1 - \left( {{1 \over 2}} \right)^{\,n} } \over {1 - \left( {{1 \over 2}} \right)}} + {{2^{\,n + 1} - \left( {n + 1} \right)2 + n\,} \over {2^{\,n} }} = \cr
& = 2 - {1 \over {2^{\,n - 1} }} + {{2^{\,n + 1} - 2 - n\,} \over {2^{\,n} }} = {{2^{\,n + 2} - 4 - n\,} \over {2^{\,n} }} \cr}
$$
