-- An infinite number of different planes can intersect the same line. -- The same line can lie in an infinite number of different planes. -- An infinite number of different lines can intersect the same plane.
There is an infinite number of lines.
A minimum of 2, but an infinite number of planes can intersect at the same line.
an infinite number; no limit
Yes, in Euclidean geometry, an infinite number of lines can meet at one point.
false they intersect at a single point
-- An infinite number of different planes can intersect the same line. -- The same line can lie in an infinite number of different planes. -- An infinite number of different lines can intersect the same plane.
There is an infinite number of lines.
A minimum of 2, but an infinite number of planes can intersect at the same line.
an infinite number; no limit
No, the two planes intersect at a line, which is an infinite number of points.
Yes, except when the line is in the plane. In the latter case, they intersect at each point on the line (an infinite number).
None. In conventional geometry, any intersection of two planes defines a line, which is an infinite number of points. Many planes may intersect along a single line, or any pair of planes may intersect creating a unique line, but however they intersect, the number of shared points is infinite. If the the planes do not intersect (if they are parallel), then they share zero points.
How about three things that are infinite. Counted number are infinite. The complete statement of PI is infinite. The result of 1 divided by 3 is infinite.
Yes, in Euclidean geometry, an infinite number of lines can meet at one point.
In Euclidean planar geometry, not unless they're collinear, in which case they intersect an infinite number of times. In other types of geometry ... maybe.
It is possible to construct an infinite number of lines through any line at a given point. You will not be able to physically draw them, but a filled in circle will all have rays that intersect the line at the same point.