7.Sol: It is easy to check (A) by looking at the
sign of f x' for x , 0. Note thatf x x x x x' 54 20 3 30 2 20 3 forx 0.
So f' (^1) 5 20 30 20 3 2 0.
Hence fcannot be increasing on the entire
interval , 0. So (A) is false.
For (B) and (D), we first need to check if
f' 1 exists. This follows because for
0 x f x x1, ' 2 1 which tends to 1
as x 1 . By the Lagrange MVT, the left
handed dervative of fatx 1 exists and
equals 1. The same is true for the right handed
derivative at x 1.
Since f x x x' (^228) 7 1 asx 1 .
Sof'exists and equals 1 atx 1. Note also
that f x'' 2 0 for 0 x 1. Sof' is
increasing on (0,1) by LMVT.
Butf x x'' 4 8 0 for 1 x< 2. Sof'
changes its behaviour from increasing to
decreasing at x 1. Thereforef' has a
local maximum atx 1. That is, (B) is true.
However, as for differentiablility of f' at
x 1 , f x'' ^22 as x 1 while
f x x'' 4 8 4 as x 1 . Hence
f'' 1 does not exist. So (D) is also true.
Finally, for (C), since f 0 1 but
f x (^) as x , by the intermediate
value Property of continuous functions,
f, 0 includes ,1. On the other
hand, for x3, f x' 1 logx 2 1 0.
So f is strictly increasing on 3,and tends
to as x. Also
1
3
3
f . Hence by
the IVP again, all points in
1
,
3
are in
the range of f. Since
7.Sol:
8.Sol:
1
,1 ,
3
R
fis onto.
8.Sol: , are roots of x x^2 1 , then
2 2
2
( r r ) ( r r)
a ar r
( r^2 r) ( r^2 r)
1 1
1
r r
ar
^ a a ar 2 r 1 r
i.e.,
2 2
1 2 2 2
n
r a a a ar n n
an 2 ( ) an 2 1
Now^11
110 10
10n nn n n
n na
10 10
1 1
10 10
10 10
(10 )(10 ) 89
1 1
1 110 10 12
10 10 1 1 89
10 10n n n
n n n nb a a
Further, b a an n 1 n 1
In other words, the number bnsatisfy a very
known Recurrence relation called the
Fibonacci relation.i.e.,( n^1 n^1 ) ( n^1 n^1 )
bn