Difference between revisions of "2010 AIME I Problems/Problem 8"
Tempaccount (talk | contribs) (Adding problem section) |
(→Solution 2) |
||
(13 intermediate revisions by 5 users not shown) | |||
Line 1: | Line 1: | ||
− | |||
− | |||
== Problem == | == Problem == | ||
− | For a real number <math>a</math>, let <math>\lfloor a \rfloor</math> | + | For a real number <math>a</math>, let <math>\lfloor a \rfloor</math> denote the [[ceiling function|greatest integer]] less than or equal to <math>a</math>. Let <math>\mathcal{R}</math> denote the region in the [[coordinate plane]] consisting of points <math>(x,y)</math> such that <math>\lfloor x \rfloor ^2 + \lfloor y \rfloor ^2 = 25</math>. The region <math>\mathcal{R}</math> is completely contained in a [[disk]] of [[radius]] <math>r</math> (a disk is the union of a [[circle]] and its interior). The minimum value of <math>r</math> can be written as <math>\frac {\sqrt {m}}{n}</math>, where <math>m</math> and <math>n</math> are integers and <math>m</math> is not divisible by the square of any prime. Find <math>m + n</math>. |
== Solution == | == Solution == | ||
− | The desired region consists of 12 boxes, whose lower-left corners are integers solutions of <math>x^2 + y^2 = 25</math>, namely <math>(\pm5,0), (0,\pm5), (\pm3,\pm4), (\pm4,\pm3).</math> Since the points themselves are symmetric about <math>(0,0)</math>, the boxes are symmetric about <math>\left(\frac12,\frac12\right)</math>. The distance from <math>\left(\frac12,\frac12\right)</math> to the furthest point on an axis | + | The desired region consists of 12 boxes, whose lower-left corners are integers solutions of <math>x^2 + y^2 = 25</math>, namely <math>(\pm5,0), (0,\pm5), (\pm3,\pm4), (\pm4,\pm3).</math> Since the points themselves are symmetric about <math>(0,0)</math>, the boxes are symmetric about <math>\left(\frac12,\frac12\right)</math>. The distance from <math>\left(\frac12,\frac12\right)</math> to the furthest point on a box that lays on an axis, for instance <math>(6,1)</math>, is <math>\sqrt {\frac {11}2^2 + \frac12^2} = \sqrt {\frac {122}4}.</math> The distance from <math>\left(\frac12,\frac12\right)</math> to the furthest point on a box in the middle of a quadrant, for instance <math>(5,4)</math>, is <math>\sqrt {\frac92^2 + \frac72^2} = \sqrt {\frac {130}4}.</math> The latter is the larger, and is <math>\frac {\sqrt {130}}2</math>, giving an answer of <math>130 + 2 = \boxed{132}</math>. |
<center><asy>import graph; size(10.22cm); real lsf=0.5; pen dps=linewidth(0.7)+fontsize(10); defaultpen(dps); pen ds=black; real xmin=-5.68,xmax=6.54,ymin=-5.52,ymax=6.5; | <center><asy>import graph; size(10.22cm); real lsf=0.5; pen dps=linewidth(0.7)+fontsize(10); defaultpen(dps); pen ds=black; real xmin=-5.68,xmax=6.54,ymin=-5.52,ymax=6.5; | ||
Line 16: | Line 14: | ||
dot((0,5),ds); dot((3,4),ds); dot((4,3),ds); dot((5,0),ds); dot((4,-3),ds); dot((3,-4),ds); dot((0,-5),ds); dot((-3,-4),ds); dot((-4,-3),ds); dot((-4,3),ds); dot((-3,4),ds); dot((-2,4),ds); dot((-2,5),ds); dot((-3,5),ds); dot((4,4),ds); dot((4,5),ds); dot((3,5),ds); dot((5,3),ds); dot((5,4),ds); dot((4,4),ds); dot((6,0),ds); dot((6,1),ds); dot((5,1),ds); dot((5,-3),ds); dot((5,-2),ds); dot((4,-2),ds); dot((3,-3),ds); dot((4,-4),ds); dot((4,-3),ds); dot((1,-5),ds); dot((1,-4),ds); dot((0,-4),ds); dot((-2,-4),ds); dot((-2,-3),ds); dot((-3,-3),ds); dot((-3,-2),ds); dot((-4,-2),ds); dot((-3,3),ds); dot((-3,4),ds); dot((-4,4),ds); dot((-5,0),ds); dot((-4,0),ds); dot((-4,1),ds); dot((-5,1),ds); dot((0,6),ds); dot((1,5),ds); dot((1,6),ds); | dot((0,5),ds); dot((3,4),ds); dot((4,3),ds); dot((5,0),ds); dot((4,-3),ds); dot((3,-4),ds); dot((0,-5),ds); dot((-3,-4),ds); dot((-4,-3),ds); dot((-4,3),ds); dot((-3,4),ds); dot((-2,4),ds); dot((-2,5),ds); dot((-3,5),ds); dot((4,4),ds); dot((4,5),ds); dot((3,5),ds); dot((5,3),ds); dot((5,4),ds); dot((4,4),ds); dot((6,0),ds); dot((6,1),ds); dot((5,1),ds); dot((5,-3),ds); dot((5,-2),ds); dot((4,-2),ds); dot((3,-3),ds); dot((4,-4),ds); dot((4,-3),ds); dot((1,-5),ds); dot((1,-4),ds); dot((0,-4),ds); dot((-2,-4),ds); dot((-2,-3),ds); dot((-3,-3),ds); dot((-3,-2),ds); dot((-4,-2),ds); dot((-3,3),ds); dot((-3,4),ds); dot((-4,4),ds); dot((-5,0),ds); dot((-4,0),ds); dot((-4,1),ds); dot((-5,1),ds); dot((0,6),ds); dot((1,5),ds); dot((1,6),ds); | ||
clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); </asy></center> | clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); </asy></center> | ||
+ | |||
+ | == Solution 2 == | ||
+ | |||
+ | When observing the equation <math>\lfloor x \rfloor ^2 + \lfloor y \rfloor ^2 = 25</math>, it is easy to see that it is the graph of a circle. So, we can draw a coordinate plane and find some points. | ||
+ | |||
+ | In quadrant <math>1</math>, <math>x < 6 </math> and <math>y < 6 </math>. Note that <math>\lfloor 5.999...\rfloor = 5</math>, but if we add more <math>9's</math> after the <math>5</math>, it will get infinitely close to <math>6</math>, so we can use <math>6</math> as a bounding line. Also, with the same logic, when <math>x = 6</math>, <math>y = 1</math> (the equal sign represents as <math>x</math> approaches..., not actually equal to...) So, in quadrant one, we have points <math>(6,1)</math> and <math>(1,6)</math>. | ||
+ | |||
+ | Moving to quadrant <math>2</math>, we must note that <math>\lfloor -4.999...\rfloor = -5</math>, so the circle will not be centered at <math>(0,0)</math>. In quadrant 2, <math>y</math> is still positive, so we can have <math>y = 1</math>. When <math>y = 1</math>, <math>x = -5</math>, so we have our next point <math>(-5,1)</math>. With this method, other points can be found in quadrant <math>3</math> and <math>4</math>. | ||
+ | |||
+ | Additionally, <math>3 ^2 + 4 ^2 = 5 ^2</math>, and with the same approaching limit, we know that quadrant <math>1</math> also has lattice points <math>(4,5)</math> and <math>(5,4)</math>. We need a point that passes through the center of the circle (we don't actually need to find the center). If we focus on <math>(5,4)</math>, the "opposite" point is <math>(-4,-3)</math> located in quadrant 3. | ||
+ | |||
+ | Using the distance formula, we find that the distance between the two points is <math>\sqrt {130}</math>. Since the line connected from those two points passes through the center of the circle, it is the diameter. So, the radius can be found by diving <math>\sqrt {130}</math> by <math>2</math> to get <math>\frac {\sqrt {130}}2</math>, and <math>m+n=130 + 2 = \boxed{132}</math>. | ||
+ | |||
+ | ~hwan | ||
== See Also == | == See Also == |
Latest revision as of 21:49, 27 June 2024
Contents
Problem
For a real number , let denote the greatest integer less than or equal to . Let denote the region in the coordinate plane consisting of points such that . The region is completely contained in a disk of radius (a disk is the union of a circle and its interior). The minimum value of can be written as , where and are integers and is not divisible by the square of any prime. Find .
Solution
The desired region consists of 12 boxes, whose lower-left corners are integers solutions of , namely Since the points themselves are symmetric about , the boxes are symmetric about . The distance from to the furthest point on a box that lays on an axis, for instance , is The distance from to the furthest point on a box in the middle of a quadrant, for instance , is The latter is the larger, and is , giving an answer of .
Solution 2
When observing the equation , it is easy to see that it is the graph of a circle. So, we can draw a coordinate plane and find some points.
In quadrant , and . Note that , but if we add more after the , it will get infinitely close to , so we can use as a bounding line. Also, with the same logic, when , (the equal sign represents as approaches..., not actually equal to...) So, in quadrant one, we have points and .
Moving to quadrant , we must note that , so the circle will not be centered at . In quadrant 2, is still positive, so we can have . When , , so we have our next point . With this method, other points can be found in quadrant and .
Additionally, , and with the same approaching limit, we know that quadrant also has lattice points and . We need a point that passes through the center of the circle (we don't actually need to find the center). If we focus on , the "opposite" point is located in quadrant 3.
Using the distance formula, we find that the distance between the two points is . Since the line connected from those two points passes through the center of the circle, it is the diameter. So, the radius can be found by diving by to get , and .
~hwan
See Also
2010 AIME I (Problems • Answer Key • Resources) | ||
Preceded by Problem 7 |
Followed by Problem 9 | |
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.