Yes. It is used in geometry in relation to lines and graphs.
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.
There are many different lines in geometry
Geometric lines have length and depth that can be endless. A line is typically used when computing linear geometry equations.
Coordinate geometry is mainly used in computers for computer graphics software. Coordinate geometry is two-dimensional, and includes shapes such as lines and polygons.
lines and angles
geometry is used in construction by using angles, paralell lines and ect.
There are infinitely many lines in mathematics and geometry.
A parallelogram in geometry is a quadrilateral with two pairs of parallel lines. A square, rectangle, rhombus, are examples of different types of parallelogram.
Yes. You can use this to prove that two lines are parallel, in analytic geometry, i.e., geometry that uses coordinates.Yes. You can use this to prove that two lines are parallel, in analytic geometry, i.e., geometry that uses coordinates.Yes. You can use this to prove that two lines are parallel, in analytic geometry, i.e., geometry that uses coordinates.Yes. You can use this to prove that two lines are parallel, in analytic geometry, i.e., geometry that uses coordinates.
Yes. It is used in geometry in relation to lines and graphs.
Coplanar lines are when all the points sit in one plane. This is something that is commonly used in geometry.
There are many different lines in geometry
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.
In Euclidean plane geometry, two lines which are perpendicular not only can but must intersect. (I believe the same is true for elliptic geometry and hyperbolic geometry.)
Yeah, parralell, perpendicular, and intersecting, are the only one I could find... There are also convergent and divergent lines (lines that are not parallel converge/diverge at different points).
By definition, perpendicular lines are those which meet in a right angle. So, yes, they have to meet in order to be "perpendicular". Parallel lines may, or may not, meet, depending on how you choose your axioms. In Euclidean geometry, parallel lines never meet. In certain types of non-Euclidean geometry, they can meet.