Difference between revisions of "1994 AIME Problems/Problem 7"
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The equation <math>x^2+y^2=50</math> is that of a circle of radius <math>\sqrt{50}</math>, centered at the origin. By testing integers until the left side becomes too big, we see that the lattice points on this circle are <math>(\pm1,\pm7)</math>, <math>(\pm5,\pm5)</math>, and <math>(\pm7,\pm1)</math> where the signs are all independent of each other, for a total of <math>3\cdot 2\cdot 2=12</math> lattice points. They are indicated by the blue dots below. | The equation <math>x^2+y^2=50</math> is that of a circle of radius <math>\sqrt{50}</math>, centered at the origin. By testing integers until the left side becomes too big, we see that the lattice points on this circle are <math>(\pm1,\pm7)</math>, <math>(\pm5,\pm5)</math>, and <math>(\pm7,\pm1)</math> where the signs are all independent of each other, for a total of <math>3\cdot 2\cdot 2=12</math> lattice points. They are indicated by the blue dots below. |
Revision as of 18:11, 19 September 2023
Contents
[hide]Problem
For certain ordered pairs of real numbers, the system of equations
has at least one solution, and each solution is an ordered pair of integers. How many such ordered pairs are there?
Solution (the original was kinda wrong) (the original was not wrong)
bro whoever made this problem must've been smoking the best weed I've ever heard of because, even though the solution says there are 72 solutions, there are actually infinite. proof here:
ok, so we know that, for the second equation alone, (x, y) = (5, 5) is a solution. if we plug this into the first equation, we get 5a+5b=1. then we simplify to get a+b=1/5. As we can see, this equation by itself obviously has infinite solutions, and, just to confirm my point, i put 100 solutions (way more than 72) below right here, given there are more than 72:
(x, y) = (5, 5) in every solution, these are the solutions for (a, b):
(0.00, 0.20) (0.01, 0.19) (0.02, 0.18) (0.03, 0.17) (0.04, 0.16) (0.05, 0.15) (0.06, 0.14) (0.07, 0.13) (0.08, 0.12) (0.09, 0.11) (0.10, 0.10) (0.11, 0.09) (0.12, 0.08) (0.13, 0.07) (0.14, 0.06) (0.15, 0.05) (0.16, 0.04) (0.17, 0.03) (0.18, 0.02) (0.19, 0.01) (0.20, 0.00) (0.21, -0.01) (0.22, -0.02) (0.23, -0.03) (0.24, -0.04) (0.25, -0.05) (0.26, -0.06) (0.27, -0.07) (0.28, -0.08) (0.29, -0.09) (0.30, -0.10) (0.31, -0.11) (0.32, -0.12) (0.33, -0.13) (0.34, -0.14) (0.35, -0.15) (0.36, -0.16) (0.37, -0.17) (0.38, -0.18) (0.39, -0.19) (0.40, -0.20) (0.41, -0.21) (0.42, -0.22) (0.43, -0.23) (0.44, -0.24) (0.45, -0.25) (0.46, -0.26) (0.47, -0.27) (0.48, -0.28) (0.49, -0.29) (0.50, -0.30) (0.51, -0.31) (0.52, -0.32) (0.53, -0.33) (0.54, -0.34) (0.55, -0.35) (0.56, -0.36) (0.57, -0.37) (0.58, -0.38) (0.59, -0.39) (0.60, -0.40) (0.61, -0.41) (0.62, -0.42) (0.63, -0.43) (0.64, -0.44) (0.65, -0.45) (0.66, -0.46) (0.67, -0.47) (0.68, -0.48) (0.69, -0.49) (0.70, -0.50) (0.71, -0.51) (0.72, -0.52) (0.73, -0.53) (0.74, -0.54) (0.75, -0.55) (0.76, -0.56) (0.77, -0.57) (0.78, -0.58) (0.79, -0.59) (0.80, -0.60) (0.81, -0.61) (0.82, -0.62) (0.83, -0.63) (0.84, -0.64) (0.85, -0.65) (0.86, -0.66) (0.87, -0.67) (0.88, -0.68) (0.89, -0.69) (0.90, -0.70) (0.91, -0.71) (0.92, -0.72) (0.93, -0.73) (0.94, -0.74) (0.95, -0.75) (0.96, -0.76) (0.97, -0.77) (0.98, -0.78) (0.99, -0.79)
NOTE:
Disproving the "proof" above: To be honest, I also thought that there would be infinite solutions for this problem when I first read it, just like the "proof" above. However, if there is one solution, then the line will touch the circle at one point, and this will be a tangent line at a lattice point on the circle. There is only one tangent line for each lattice point on the circle, and there are 12 lattice points on the circle. If there are two solutions, then the line will intersect the circle at two points, and both of these points must have integer coordinates, so we have to pick two points from our 12 lattice points to connect. Continue as the solution below.
Solution
The equation is that of a circle of radius , centered at the origin. By testing integers until the left side becomes too big, we see that the lattice points on this circle are , , and where the signs are all independent of each other, for a total of lattice points. They are indicated by the blue dots below.
[asy] size(150); draw(circle((0,0),sqrt(50)));
draw((1,7)--(-1,-7),red); draw((7,1)--(5,-5), green);
dot((0,0));
dot((1,7),blue); dot((1,-7),blue); dot((-1,7),blue); dot((-1,-7),blue);
dot((5,5),blue); dot((5,-5),blue); dot((-5,5),blue); dot((-5,-5),blue);
dot((7,1),blue); dot((7,-1),blue); dot((-7,1),blue); dot((-7,-1),blue); [/asy]
Since yields , we know that is the equation of a line that does not pass through the origin. So, we are looking for the number of lines which pass through at least one of the lattice points on the circle, but do not pass through the origin or through any non-lattice point on the circle. An example is the green line above. It is straightforward to show that a line passes through the origin precisely when there exist two opposite points and through which it passes. And example is the red line above.
There are ways to pick two distinct lattice points, and subsequently distinct lines which pass through two distinct lattice points on the circle. Then we subtract the lines which pass through the origin by noting that the lattice points on the circle can be grouped into opposite pairs and , for a total of lines. Finally, we add the unique tangent lines to the circle at each of the lattice points.
Therefore, our final count of distinct lines which pass through one or two of the lattice points on the circle, but do not pass through the origin, is
See also
1994 AIME (Problems • Answer Key • Resources) | ||
Preceded by Problem 6 |
Followed by Problem 8 | |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15 | ||
All AIME Problems and Solutions |
The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.