The absolute value of the difference of their coordinate (if it is in one dimension).
Slope is the change in y (vertical dimension) with the change in x (horizontal dimension). On a Cartesian coordinate system, the slope is equal to infinity for change in x = 0, or a vertical line.
That's the name of the plane with the horizontal x-axis and the vertical y-axis on which equations and inequalities with two variables are graphed. The Cartesian coordinate plane is to two dimensions as the number line is to one dimension.
The two letters for a 2-dimensional plane are X and Y. Each one is known as an axis, therefore being the X axis and the Y axis. The X axis is the horizontal dimension and the Y axis is the vertical dimension.
It is a three dimension vector : (x, y, z). It could be either a row vector or a column vector.
The absolute value of the difference of their coordinate (if it is in one dimension).
If the coordinate of A is x, and that of the midpoint of AB, M, is m then the distance AM is m-x so the distance AB = 2*(m-x) So the coordinate of B is x + 2*(m-x) = 2m-x For coordinates in more than one dimension, apply the above rule separately for each dimension.
Slope is the change in y (vertical dimension) with the change in x (horizontal dimension). On a Cartesian coordinate system, the slope is equal to infinity for change in x = 0, or a vertical line.
That's the name of the plane with the horizontal x-axis and the vertical y-axis on which equations and inequalities with two variables are graphed. The Cartesian coordinate plane is to two dimensions as the number line is to one dimension.
As many as you like. Coordinate systems are arbitrary frameworks used to describe the system configuration (arrangement). The popular coordinate systems are rectangular, polar and spherical. Coordinate systems are not the same as dimensions. A physical problem may have only one dimension and can be described in a three dimensional rectangular coordinate system. Physics since Einstein is believed to be 4 dimensional. A 4 dimensional coordinate system like quaternions would seem to be convenient.
The two letters for a 2-dimensional plane are X and Y. Each one is known as an axis, therefore being the X axis and the Y axis. The X axis is the horizontal dimension and the Y axis is the vertical dimension.
motion of any object in Cartesian coordinate system along x, y, z direction by that same time. eg. flying of bird
Simple...the second dimension has 2 dimensions. Think of a coordinate plane... it has 2 dimensions... height and width. This plane is the only area that they can be on. If they were not on the plane they would be in a different dimension. So to answer your question... if it wasn't flat... it wouldn't be 2 dimensions. Better yet, the reason why the second dimension is flat is simply because only two vectors exist within a two dimensional figure. (up/down, side- side)
It is a three dimension vector : (x, y, z). It could be either a row vector or a column vector.
A Projection is defined as a process which transforms points in a coordinate system of dimension n into points in a coordinate system of dimension less than n.The mapping of 3D objects onto the 2D screen is done by straight projection rays (called projectors) emanating from a center of projection, passing through each point of the object, and intersecting a projection plane to form the projection.Projections can be divided into two basic classes:Perspective or Vanishing Point Method (VPM)Parallel Projection
A Projection is defined as a process which transforms points in a coordinate system of dimension n into points in a coordinate system of dimension less than n.The mapping of 3D objects onto the 2D screen is done by straight projection rays (called projectors) emanating from a center of projection, passing through each point of the object, and intersecting a projection plane to form the projection.Projections can be divided into two basic classes:Perspective or Vanishing Point Method (VPM)Parallel Projection
'Centre of mass' is a place, i.e. a point, in space. It can be described by its coordinates . . . lengths (x, y, z) in Cartesian coordinates, or some combination of lengths and angles in other coordinate systems.