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− | {{AoPSWiki:Sandbox/header}} <!-- Please do not delete this line --> | + | {{/header}} <!-- Please do not delete this line --> |
− | In the computer world, a '''sandbox''' is a place to test and experiment -- essentially, it's a place to play.
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− | This is the AoPSWiki Sandbox. Feel free to experiment here.
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− | Warning: anything you place here is subject to deletion without notice.
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− | [''This was deleted due to its inappropriateness.'']
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− | ==<math>\LaTeX</math> test==
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− | ---experimenthere-----
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− | Please do not delete from this point on until 5:00 PST on 4/2!
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− | We want to find the area of this figure:
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− | <asy>
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− | path rt,tt, tri;
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− | real x, y;
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− | y = 1+sqrt(2);
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− | x = y+(6/1.7);
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− | tt=(0,0)..(y,1)--(y,-1)..cycle;
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− | rt=(y,-1)--(x,-1)--(x,1)--(y,1);
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− | tri=(y,-1)--(y-1,0)--(y,1);
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− | draw(rt);
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− | draw(tt);
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− | draw(tri);
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− | label("1.7", (x, 0), E);
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− | label("3", (y+(3/1.7), -1), S);
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− | label("C", (y-1, -0.1), S);
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− | </asy>
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− | We label the circle as circle C. We can break the figure into three parts, shown as the 3/4 circle, the triangle, and the rectangle.
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− | Lets first take a look at the rectangle.
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− | <asy>
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− | path rt;
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− | real x, y;
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− | y = 1+sqrt(2);
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− | x = y+(6/1.7);
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− | rt=(y,-1)--(x,-1)--(x,1)--(y,1)--cycle;
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− | draw(rt);
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− | label("1.7", (x, 0), E);
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− | label("3", (y+(3/1.7), -1), S);
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− | </asy>
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− | It has an area of <math> 3 * 1.7 = 5.1</math> .
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− | Lets now take a look at the triangle, after drawing the height.
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− | <asy>
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− | unitsize(0.8inch);
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− | path tri, lin;
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− | real x, y;
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− | y = 1+sqrt(2);
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− | x = y+(6/1.7);
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− | tri=(y,-1)--(y-1,0)--(y,1)--cycle;
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− | lin=(y-1, 0)--(y,0);
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− | draw(tri);
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− | draw(lin);
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− | label("1.7", (y, 0), E);
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− | label("C", (y-1, -0.1), S);
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− | </asy>
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− | We see that both the radii are the two shorter sides of the triangle, making this a isosceles 45-45-90 triangle.
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− | We also see that the height that we drew is half the hypotenuse(note the two smaller 45-45-90 isosceles triangles).
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− | Hence, the area of the triangle is <math>\frac{1.7 * \frac{1.7}{2}}{2} = 0.7225</math> .
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− | Now, let's take a look at the 3/4 circle. We know it is 3/4 because there is a 90 degree triangle cut out of it.
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− | <asy>
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− | unitsize(0.8inch);
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− | path tt, tri;
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− | real x, y;
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− | y = 1+sqrt(2);
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− | x = y+(6/1.7);
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− | tt=(0,0)..(y,1)--(y,-1)..cycle;
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− | tri=(y,-1)--(y-1,0)--(y,1);
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− | draw(tt);
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− | draw(tri);
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− | label("1.7", (y, 0), E);
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− | label("C", (y-1, -0.1), S);
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− | </asy>
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− | We find the radius using the 45-45-90 triangle. Since the ratios of the sides are 1:1:<math>\sqrt{2}</math>, we can find the radius to be <math>\frac{1.7}{\sqrt{2}} = \frac{1.7 \sqrt{2}}{2}</math> .
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