Difference between revisions of "DVI exam"
(→2022 221 problem 7) |
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<i><b>Solution</b></i> | <i><b>Solution</b></i> | ||
− | Let us consider the uniform triangular prism <math>ABCA'B'C'.</math> Let <math>M</math> be the midpoint of <math>AB, M'</math> be the midpoint of <math>A'B', K</math> be the midpoint of <math>CM, L</math> be the midpoint of <math>C'M'.</math> | + | Let us consider the uniform triangular prism <math>ABCA'B'C'.</math> Let <math>M</math> be the midpoint of <math>AB, M'</math> be the midpoint of <math>A'B', K</math> be the midpoint of <math>CM, L</math> be the midpoint of <math>C'M', 2 FG = AB.</math> |
The area <math>[KED]</math> of <math>\triangle KED</math> in the sum with the areas of triangles <math>[KEL], [EDM'], [KDM]</math> is half the area of rectangle <math>CC'M'M,</math> so | The area <math>[KED]</math> of <math>\triangle KED</math> in the sum with the areas of triangles <math>[KEL], [EDM'], [KDM]</math> is half the area of rectangle <math>CC'M'M,</math> so | ||
− | <cmath> \frac {[KED]}{[CC'M'M]} = \frac {1}{2} - \frac {1}{12}-\frac {1}{8} = \frac {5}{24}.</cmath> | + | <cmath> \frac {[KED]}{[CC'M'M]} = \frac {1}{2} - \frac {1}{12}- \frac {1}{12}-\frac {1}{8} = \frac {5}{24}.</cmath> |
− | <cmath>FG \perp ED | + | <cmath>FG \perp ED.</cmath> Denote the distance between these lines <math>h.</math> The volume of the tetrahedron is <math>U = \frac {ED \cdot h \cdot FG}{6}.</math> |
− | <cmath>\frac {ED \cdot | + | <cmath>\frac {ED \cdot h}{2} = \frac {5}{24} \cdot CC' \cdot CM \implies U =\frac{5}{24 \cdot 3} \cdot CC' \cdot CM \cdot FG.</cmath> |
− | The volume of the prism is <math>V = \frac{CM \cdot AB}{2} \cdot | + | The volume of the prism is <math>V = \frac{CM \cdot AB}{2} \cdot CC' =CC' \cdot CM \cdot FG = 72.</math> |
− | <cmath>\frac {U}{V} = \frac {\frac {5}{72} CC' \cdot CM \cdot FG}{\ | + | <cmath>\frac {U}{V} = \frac {\frac {5}{72} CC' \cdot CM \cdot FG}{CC' \cdot CM \cdot FG} = \frac {5}{24} \implies U = 5.</cmath> |
An arbitrary prism is obtained from a regular one as a result of an affine transformation. | An arbitrary prism is obtained from a regular one as a result of an affine transformation. | ||
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All points on the tetrahedron are defined affinely, which means that the volume ratio will be preserved. | All points on the tetrahedron are defined affinely, which means that the volume ratio will be preserved. | ||
− | <i><b>Answer: | + | <i><b>Answer: 5.</b></i> |
==2022 222 problem 7== | ==2022 222 problem 7== |
Revision as of 04:56, 28 January 2024
2022 221 problem 7
The volume of a triangular prism with base and side edges is equal to Find the volume of the tetrahedron where is the centroid of the face is the point of intersection of the medians of is the midpoint of the edge and is the midpoint of the edge
Solution
Let us consider the uniform triangular prism Let be the midpoint of be the midpoint of be the midpoint of be the midpoint of
The area of in the sum with the areas of triangles is half the area of rectangle so Denote the distance between these lines The volume of the tetrahedron is The volume of the prism is
An arbitrary prism is obtained from a regular one as a result of an affine transformation.
All points on the tetrahedron are defined affinely, which means that the volume ratio will be preserved.
Answer: 5.
2022 222 problem 7