| T.R | Title | User | Personal
Name | Date | Lines |
|---|
| 1776.1 | Solution to #1 | TROOA::RITCHE | From the desk of Allen Ritche... | Wed Jul 21 1993 00:27 | 24 |
| > 1. Determine a triangle whose three sides and an altitude are four
> consecutive integers and for which this altitude partitions the
> triangle into two right triangles with integers sides. Show that there
> is only one such triangle.
I believe this problem is the easiest of the 5 to solve.
Let the sides of the triangle be x-1, x, with base x+1.
The altitude (which is consecutive) must be x-2.
The two smaller rt triangles then have bases of sqrt(2x-3) and 4*sqrt(x-1)
which must sum to (x+1).
Solving the radical equation yields only 2 roots x=2 or x=26.
Thus we have one real triangle (25, 26, 27) or a degenerate one (1, 2, 3)
that has no height which we will eliminate.
The smaller rt triangles are (7, 24, 25) and (20, 24, 26).
Q.E.D.
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| 1776.2 | solution to #4 | UTRTSC::BUIJS | | Thu Jul 22 1993 11:45 | 106 |
| problem 4 was't that difficult as well:
> 4. A number of schools took part in a tennis tournament. No two
> players from the same school played against each other. Every two
> players from different schools played exactly one match against each
> other. A match between two boys or between two girls was called a
> _single_ and that between a boy and a girl was called a _mixed single_.
> The total number of boys different from the total number of girls by at
> most 1. The total number of singles differed from the total number of
> mixed singles by at most 1. At most how many schools were represented
> by an odd number of players?
At most 3 schools are represented by an odd number of players
The number of schools with an odd number of players is either 0,1 or 3
The difference between the number of boys and the number of girls from a school
with an odd number of players is 1.
For schools with an even number of players the number of boys is equal to the
number of girls.
Let n be the total number of schools,
g(i) the number of girls who are representing school i
b(i) the number of boys who are representing school i
c(i) the number of childeren who are representing school i,
c(i) = b(i) + g(i)
G = (S i:1<=i<=n: g(i)), the total number of participating girls
B = (S i:1<=i<=n: b(i)), the total number of participating boys
|G - B| <= 1, therefore (G - B)^2 = 0 or (G - B)^2 = 1
Now calculate the total number of singles and of mixed-singles
First calculate the number of singles between girls
a girl representing school j plays against all girls from all other schools so
she plays (S i:1<=i<j v j<i<=n: g(i)) = G - g(j) singles
all girls representing school j together play g(j) * (G- g(j)) singles
so the total number of singles between girls is
(S j:1<=j<=n: g(j)*(G - g(j))/2
=
( G*(S j:1<=j<=n: g(j)) - (S j:1<=j<=n: g(j)^2))/2
=
( G^2 - (S j:1<=j<=n: g(j)^2))/2
The total number of singles for both girls and boys is therefore
( G^2 - (S j:1<=j<=n: g(j)^2) + ( B^2 - (S j:1<=j<=n: b(j)^2))/2
Now calculate the number of mixed-singles
a girl from school j plays against all boys from all other schools so
she plays (S i:1<=i<j v j<i<=n: b(i)) = B - b(j) mixed-singles.
a boy from school j plays againt all girls from all other schools so
he plays (S i:1<=i<j v j<i<=n: g(i)) = G - g(j) mixed-singles.
all children from school j together play g(j)*(B - b(j)) + b(j)*(G - g(j))
mixed-singles
so the total number of mixed-singles is
(S j:1<=j<=n: g(j)*(B - b(j) + b(j)*(G - g(j)))/2
=
( B*(S j:1<=j<=n: g(j)) + G*(S j:1<=j<=n: b(j) - 2*(S j:1<=j<=n: g(j)*b(j)))/2
=
( 2*B*G - 2*(S j:1<=j<=n: g(j)*b(j)))/2
the difference between the number of mixed-singles and the singles is
( 2*B*G - 2*(S j:1<=j<=n: g(j)*b(j)))/2
-
( G^2 - (S j:1<=j<=n: g(j)^2) + ( B^2 - (S j:1<=j<=n: b(j)^2))/2
=
((S j:1<=j<=n: (g(j) - b(j))^2) - (G - B)^2)/2
This number D is either 0,1 or -1, furthermore (G-B)^2 is 0 or 1
The formula can be written as:
(S j:1<=j<=n: (g(j) - b(j))^2) = 2 * D + (G - B)^2
so
(S j:1<=j<=n: (g(j) - b(j))^2) = 0 when D = 0 and (G - B)^2 = 0
or
(S j:1<=j<=n: (g(j) - b(j))^2) = 1 when D = 1 and (G - B)^2 = 0
or
(S j:1<=j<=n: (g(j) - b(j))^2) = 3 when D = 1 and (G - B)^2 = 1
So, for all schools (g(j) - b(j))^2 = 0 or (g(j) - b(j))^2 = 1
so
(g(j) - b(j))^2 = 0 => g(j) = b(j) => c(j) = 2*g(j) is even
(g(j) - b(j))^2 = 1 => g(j) = b(j) + 1 v b(j) = g(j) + 1 =>
c(j) = 2 * (min g(j),b(j)) + 1 is odd
Concluding:
for all schools j : (g(j) - b(j))^2 = 0, therefore all schools are represented
by an even number of children
or
there is one school i, with (g(i) - b(i))^2 = 1,
all other schools are represented by an even number of children with the same
number of girls as the number of boys
or
there are 3 schools i, with (g(i) - b(i))^2 = 1,
in this case it's not possible all 3 schools have g(i) = b(i) + 1
or all 3 schools have b(i) = g(i) + 1
all other schools are represented by an even number of children with the same
number of girls as the number of boys
Marjan van den Buijs
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| 1776.3 | #5 | WIBBIN::NOYCE | It's the memory interface, stupid! | Thu Jul 22 1993 15:22 | 26 |
| The sequence in problem 5 is "Gray code."
As i takes on values 1..2^n-1, y[i] also takes on all
the values in 1..2^n-1.
To show that all the values are different:
1<=i & 1<=j & y[i]=y[j] ==> i=j
use induction on
1<=i,j<2^n & y[i]=y[j] ==> i=j.
Clearly true for n=1.
For the induction step,
y[i] = y[j] ==> y[floor(i/2)] = y[floor(j/2)]
==> floor(i/2) = floor(j/2) = k
==> y[i] = y[j] = 2*y[k] or
y[i] = y[j] = 2*y[k]+1
==> i = j
shows it's true for n+1.
To show that it takes on all the values, it suffices to
show that 1 <= i < 2^n ==> 1 <= y[i] < 2^n.
Prove by induction: It's true for n=1;
Assuming it's true for n, then
y[2*i] <= 2*y[i]+1
and y[2*i+1] <= 2*y[i]+1
show it's true for n+1.
|
| 1776.4 | | AUSSIE::GARSON | nouveau pauvre | Fri Jul 23 1993 01:31 | 34 |
| Q2. GP=>RATIONAL [converse remains]
Suppose three distinct terms form a GP from x, x+1, x+2, x+3, ...
Let the terms be x+i, x+j and x+k. (i,j,k integers with 0 <= i < j < k)
By definition of GP
x+j x+k
--- = ---
x+i x+j
=> (x+j)� = (x+i)(x+k)
=> x�+2xj+j� = x�+(i+k)x+ik
=> x(2j-i-k) = ik-j�
Now suppose 2j-i-k = 0 in which case ik-j� = 0
=> 2j = i+k
=> 4j� = (i+k)�
=> 4ik - 4j� = 4ik - (i+k)�
=> 4ik - 4j� = 4ik - i� - 2ik - k�
=> 0 = -(i-k)�
=> i = k
But this is false (i,j,k are distinct)
Hence 2j-i-k <> 0
=> x = (ik-j�)/(2j-i-k)
=> x is rational
|
| 1776.5 | ...and the converse | GEMGRP::NOYCE | It's the memory interface, stupid! | Fri Jul 23 1993 12:14 | 26 |
| Q2. RATIONAL=>GP (it's easy, now that you showed me how!)
Given x = p/q (p,q integers) form the sequence
p/q, p/q + p, p/q + 2p + pq, where the ratio is 1+q.
(p/q)*(1+q) = p/q + p
(p/q + p) * (1+q) = p/q + p + p + pq.
===========================================================
To find this, I set
p/q + j p/q + k
------- = -------
p/q p/q + j
and solved for k:
(p/q + j)^2 = (p/q)^2 + (p/q)*k
2j + (q/p)*j^2 = k
Setting j=p yields an integer solution for k.
|
| 1776.6 | Correction | RICKS::D_ELLIS | David Ellis | Fri Jul 23 1993 15:31 | 10 |
| re: .1
> The smaller rt triangles are (7, 24, 25) and (20, 24, 26).
Sorry, but (20, 24, 26) is not a right triangle.
The method looks right, but the details came out wrong.
Correct answer: (13, 14, 15) divided by altitude 12 into (5, 12, 13) and
(9, 12, 15) right triangles.
|
| 1776.7 | egg on face | TROOA::RITCHE | From the desk of Allen Ritche... | Fri Jul 23 1993 17:55 | 21 |
| RE: .6 and .1,
Thanks to Dave for pointing out the late-night error in .1.
I assumed incorrectly that the base was x+1. And also didn't
verify correctly.
Below is the corrected solution given in .1
Let the sides of the triangle be x-1, x+1, with base x.
The altitude (which is consecutive) must be x-2.
The two smaller rt triangles then have bases of sqrt(2x-3) and sqrt(6x-3)
which must sum to x.
Solving the radical equation yields only 1 admissable root x=14.
Thus we have one triangle (13, 14, 15) altitude 12.
The smaller rt triangles are (5, 12, 13) and (9, 12, 15) as per .6
Allen
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| 1776.8 | | AUSSIE::GARSON | nouveau pauvre | Sat Jul 24 1993 03:03 | 21 |
| re .5
Your answer is of course correct but one thing bothers me. You have set
i=0 without apparent justification except that the answer comes out.
In fact more general solutions exist
i = N
j = i(1+Tq)+Tp
k = j(1+Tq)+Tp
N and T integers, N >= 0, T >= 1
but this is still somewhat "rabbit out of a hat".
It can be shown that if r, the ratio of the GP, is an integer then it
must be of the form 1+Tq provided (p,q)=1. Knowing the form of r it is
easy to generate the above solutions.
All that remains is to investigate the possibilities for r not being an
integer.
|
| 1776.9 | | HERON::BUCHANAN | The was not found. | Mon Aug 16 1993 09:12 | 25 |
| > 4. A number of schools took part in a tennis tournament. No two
> players from the same school played against each other. Every two
> players from different schools played exactly one match against each
> other. A match between two boys or between two girls was called a
> _single_ and that between a boy and a girl was called a _mixed single_.
> The total number of boys different from the total number of girls by at
> most 1. The total number of singles differed from the total number of
> mixed singles by at most 1. At most how many schools were represented
> by an odd number of players?
Let �_i be the number of boy players from school i minus the number
of girl players from that school. A school is represented by an odd number
of players exactly if �_i is odd. We are told:
sum(i) �_i = -1,0 or 1
sum(i<j) �_i*�_j = -1,0 or 1
Simple manipulation of these two formulae yields:
sum(i) �_i� = -2,-1,0,1,2 or 3.
But �_i� is a non-negative square, so |�_i| = 0 or 1 for all i, and
less than four of the �_i are non-zero. Hence the result.
Andrew.
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