10
35
To determine the number of triangles in a star inside a hexagon, we need to consider the number of triangles formed by the lines connecting the vertices of the hexagon and the points where the lines of the star intersect. Each intersection point forms a triangle with two adjacent vertices of the hexagon. Therefore, if the star has n points of intersection, the total number of triangles would be n multiplied by 2. Additionally, we need to consider the triangles formed by the lines of the star itself, which would add n triangles to the total count. So, the total number of triangles in a star inside a hexagon would be 3n.
There are six triangles in an octagon. In any convex polygon, there are two less triangles than the number of sides. So a octagon which has 8 sides, contains 6 triangles.
A heptagon has 5 triangles.
There are 3 to 10 triangles in a star.
There is 8 triangles in the Star of David.
Six triangles.
One star has five triangles on the sides, and about three in the middle, if enough lines are drawn.
If it is in the form of two inverted triangles, then there are 8 triangles. If only the outline is used, there are 0 triangles.
10
8 (?)
35
35
10
5
1 triangle = 3 angles so 4 triangles = 4 x 3 = 12 angles unless some triangles are within others