2019 AMC 10 A

Complete problem set with solutions and individual problem pages

Problem 21 Hard

A sphere with center O has radius 6. A triangle with sides of length 15, 15, and 24 is situated in space so that each of its sides is tangent to the sphere. What is the distance between O and the plane determined by the triangle? (2019 AMC 10A Problem, Question#21)

  • A.

    2\sqrt{3}

  • B.

    4

  • C.

    3\sqrt{2}

  • D.

    2\sqrt{5}

  • E.

    5

Answer:D

3D:

Plane through triangle:

The triangle is placed on the sphere so that its three sides are tangent to the sphere. The cross-section of the sphere created by the plane of the triangle is also the incircle of the triangle. To find the inradius, use area= inradius \cdot semiperimeter. The area of the triangle can be found by drawing an altitude from the vertex between sides with length 15 to the midpoint of the side with length 24. The Pythagorean triple 9-12-15 allows us easily to determine that the base is 24 and the height is 9. The formula \frac{\text{base}\cdot \text{height}}{2} can also be used to find the area of the triangle as 108, while the semiperimeter is simply \frac{15+15+24}{2}=27. After plugging into the equation, we thus get 108=\text{inradius}\cdot27, so the inradius is 4 . Now, let the distance between O and the triangle be x. Choose a point on the incircle and denote it by A. The distance OA is 6, because it is just the radius of the sphere. The distance from point A to the center of the incircle is 4, because it is the radius of the incircle. By using the Pythagorean Theorem, we thus find x=\sqrt{6^2-4^2}=\sqrt{20}=2\sqrt{5}.

As in Solution 1, we note that by the Pythagorean Theorem, the height of the triangle is 9, and that the three sides of the triangle are tangent to the sphere, so the circle in the cross-section of the sphere is the incenter of the triangle.

Recall that the inradius is the intersection of the angle bisectors. To find the inradius of the incircle, we use the Angle Bisector Theorem.

 \frac{AB}{BI}=\frac{AD}{DI}
\Rightarrow\frac{15}{BI}=\frac{12}{DI}
\Rightarrow\frac{BI}{5}=\frac{DI}{4}

Since we know that BI+DI (the height) is equal to 9, DI (the inradius) is 4. From here, the problem can be solved in the same way as in Solution 1. The answer is 2\sqrt{5}

First, we label a few points:

We have that \triangle BDC is a 3-4-5 triangle, so, as in Solution 1, BD=9. From this, we know that \overline{BI}=9-r. Since AB is tangent to circle I, we also know IEB is a right triangle. \triangle BIE and \triangle BDA share angle DBA, so \triangle BIE\sim\triangle BDA since they have two equal angles. Hence, by this similarity, \frac{9-r}{5}=\frac{r}{4}. Cross-multiplying, we get 36-4r=5r, which gives r=4 . We now take another cross section of the sphere, perpendicular to the plane of the triangle.

Using the Pythagorean Theorem, we find that the distance from the center to the plane is 2\sqrt{5}. solution by woofle 628 and GeniusKid 1221.

Test all the answer choices by plugging them into the expression \sqrt{6^2-x^2} to find the inradius of the triangle. Seeing that only \sqrt{20}=2\sqrt{5} gives an integer inradius, we pick 2\sqrt{5}. .

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