a 0 0 so3 1^2010
n 2
a
. As we have 3 1^5 mod (11), that is 32010 (3 ) 15 402 mod(11).
Therefore 3 1 0^2010 mod(11). hence the
reminder is 0.Vectors
1.Sol: We get around the problem a bit. If we
can take the circum-centre (0) as origin and
we simply write centroid
3a b c
G
. Wee
then form a relation between centriod(G),
Circum- center(O), and Ortho-center(H).
That is the distance between the centroid and
the ortho-center is twice the distance between
the centroid and the circum-center.Therefore
H is a b c
. Since N is a mid point of OH,
we get
2Na b c
.Now, we have
2a b c
NA
, similarly2b a c
NB
and
2c a b
NC
byadding these three vectors ,we get the desiredvector
2 2a b c b a c
NA NB NC
1
2 2 2c a b a b c
HO
2.Sol: We take (^) v to be the circum-centre but
with respect to any origin. Reader may
observe the given information carefully ,you
can see interesting fact that v is equidistant
from the vectors (^) i i,2
and j
. Let v x y( , )
circum-center, and the position vectors be
vertices of triangle ABC. That is A(1,0),
B(2,0) and C(0,1). Now we have
( 1)x ^2 y^2 ( 2)x^2 y x^22 ( 1)y^2.after simplifying, we get3
2x and3
2y ,therefore the desired vector is3 3
2 2v i j
.Hence3
2v
which lies in the interval2,3.3.Sol: Given a i j k 6 3 6
and d i j k We want to write a b c
. Where (^) b
is
parallel to d
and (^) c is perpendicular to d
.
For this , we need (^) b
to be the projection of
a
onto d
.
So
a d
b d
d d
Now a d 6 3 6 3
and
(^) d d 1 1 1 3
So,
Vectorsectors
1.Sol:
2.Sol:
3.Sol:
4.Sol:
3
1
3
a d
d d
Therefore b d i j k
and
c a b (6 3 6 ) (i j k i j k)
(^) 7 2 5i j k
4.Sol: We take center to be the origin and two of
the vertices to be
1 1
0,1, , 0, 1,
2 2
.
This gives us an isosceles triangle with sides
3 3
,
2 2
,2 and we can us the cosine rule from
elementary trigonometry
(. .,i e c a b^2 ^22 2 cos )ab to get
3 3 3
4 2 cos
2 2 2
.