2012 239 Open Mathematical Olympiad

Part of 239 Open Math Olympiad

Subcontests

(8)

1

Devisor tetrahedrons

We call a tetrahedron divisor of a parallelepiped if the parallelepiped can be divided into

6

copies of that tetrahedron. Does there exist a parallelepiped that it has at least two different divisor tetrahedrons?

2

Guessing the number

Vasya conceived a two-digit number

a

, and Petya is trying to guess it. To do this, he tells Vasya a natural number

k

, and Vasya tells Petya the sum of the digits of the number

ka

. What is the smallest number of questions that Petya has to ask so that he can certainly be able to determine Vasya’s number?

Circumscribed quadrilateral

A circumscribed quadrilateral

ABCD

is given. It is known that

\angle{ACB} = \angle{ACD}

. On the angle bisector of

\angle{C}

E

is marked such that

AE \bot BD

F

is the foot of the perpendicular line from point

E

BC

AB = BF

2

Stroll on the graph

G

be a planar graph all of whose vertices are of degree

4

. Vasya and Petya walk along its edges. The first time each of them goes as he pleases, and then each of them goes straight (from the three roads they have to choose the middle one). As the result, each vertex was visited by exactly one of them and exactly once. Prove that this graph has an even number of vertices.

Subsets not appearing in the row

n

S

, several subsets

A_1, A_2, \ldots , A_k

are distinguished, each consists of at least two, but not all elements of

S

. What is the largest

k

that it’s possible to write down the elements of

S

in a row in the order such that we don’t find all of the element of an

A_i

set in the consecutive elements of the row?

2

Cyclic trapezoid

M

is the midpoint of the base

AD

ABCD

inscribed in circle

S

AB

DC

intersect at point

P

BM

S

K

. The circumscribed circle of triangle

PBK

intersects line

BC

L

\angle{LDP} = 90^{\circ}

Tangent line to the circumcircle

On the hypotenuse

AB

of the right-angled triangle

ABC

K

is chosen such that

BK = BC

P

be a point on the perpendicular line from point

K

CK

, equidistant from the points

K

B

L

denote the midpoint of the segment

CK

. Prove that line

AP

is tangent to the circumcircle of the triangle

BLP

2

Four variable inequality

For some positive numbers

a

b

c

d

\frac{1}{a^3 + 1}+ \frac{1}{b^3 + 1}+ \frac{1}{c^3 + 1} + \frac{1}{d^3 + 1} = 2.

\frac{1 - a}{a^2 - a + 1} + \frac{1-b}{b^2 - b + 1} + \frac{1-c}{c^2 - c + 1} +\frac{1-d}{d^2 - d + 1} \geq 0.

Three variable inequality with sum of one

For positive real numbers

a

b

c

a+b+c=1

(a-b)^2 + (b-c)^2 + (c-a)^2 \geq \frac{1-27abc}{2}.

1

n point in the space

n

points in the space such that none

4

of them lie on a plane. You can select two points

A

B

A

to the midpoint of line segment

AB

. It turned out that, after several moves, the points took the same places (possibly in a different order). What is the smallest value of

n

that this could happen for some

n

1

Composite sum

Natural numbers

a, b, c, d

are given such that

c>b

. Prove that if

a + b + c + d = ab-cd

a + c

is a composite number.

1

10x10 chessboard

10 \times 10

chessboard, several knights are placed, and in any

2 \times 2

square there is at least one knight. What is the smallest number of cells these knights can threat? (The knight does not threat the square on which it stands, but it does threat the squares on which other knights are standing.)