PEN F Problems

Part of PEN Problems

Subcontests

(15)

1

F 16

Prove that for any distinct rational numbers

a, b, c

\frac{1}{(b-c)^{2}}+\frac{1}{(c-a)^{2}}+\frac{1}{(a-b)^{2}}

is the square of some rational number.

1

F 15

Find all rational numbers

k

0 \le k \le \frac{1}{2}

\cos k \pi

1

F 14

k

m

be positive integers. Show that

S(m, k)=\sum_{n=1}^{\infty}\frac{1}{n(mn+k)}

is rational if and only if

m

k

1

F 13

Prove that numbers of the form

\frac{a_{1}}{1!}+\frac{a_{2}}{2!}+\frac{a_{3}}{3!}+\cdots,

0 \le a_{i}\le i-1 \;(i=2, 3, 4, \cdots)

are rational if and only if starting from some

i

a_{i}

's are either equal to

0

( in which case the sum is finite) or all are equal to

i-1

1

F 12

Does there exist a circle and an infinite set of points on it such that the distance between any two points of the set is rational?

1

F 11

S=\{x_0, x_1, \cdots, x_n\} \subset [0,1]

be a finite set of real numbers with

x_{0}=0

x_{1}=1

, such that every distance between pairs of elements occurs at least twice, except for the distance

1

. Prove that all of the

x_i

1

F 10

S

is a finite subset of

[0,1]

with the following property: for all

s\in S

a,b\in S\cup\{0,1\}

a, b\neq s

such that s \equal{}\frac{a\plus{}b}{2}. Prove that all the numbers in

S

1

F 9

Prove that every positive rational number can be represented in the form

\frac{a^{3}+b^{3}}{c^{3}+d^{3}}

for some positive integers

a, b, c

d

1

F 8

Find all polynomials

W

with real coefficients possessing the following property: if

x+y

is a rational number, then

W(x)+W(y)

1

F 7

x

is a positive rational number, show that

x

can be uniquely expressed in the form

x=a_{1}+\frac{a_{2}}{2!}+\frac{a_{3}}{3!}+\cdots,

a_{1}a_{2},\cdots

0 \le a_{n}\le n-1

n>1

, and the series terminates. Show also that

x

can be expressed as the sum of reciprocals of different integers, each of which is greater than

10^{6}

1

F 6

x, y, z

non-zero real numbers such that

xy

yz

zx

are rational. [*] Show that the number

x^{2}+y^{2}+z^{2}

is rational. [*] If the number

x^{3}+y^{3}+z^{3}

is also rational, show that

x

y

z

1

F 5

Prove that there is no positive rational number

x

x^{\lfloor x\rfloor }=\frac{9}{2}.

1

F 4

\tan \alpha =\frac{p}{q}

p

q

are integers and

q \neq 0

. Prove the number

\tan \beta

\tan 2\beta =\tan 3\alpha

is rational only when

p^2 +q^2

is the square of an integer.

1

F 2

x

y

which are rational multiples of

\pi

0<x<y<\frac{\pi}{2}

\tan x+\tan y =2

1

F 1

Suppose that a rectangle with sides

a

b

is arbitrarily cut into

n

squares with sides

x_{1},\ldots,x_{n}

\frac{x_{i}}{a}\in\mathbb{Q}

\frac{x_{i}}{b}\in\mathbb{Q}

i\in\{1,\cdots, n\}