The question given is quite vague and unclear but in general perpendicular lines meet each other at right angles which is 90 degrees.
It the point is on the line the distance is 0. If the point is not on the line, then it is possible to draw a unique line from the point to the line which is perpendicular to the line. The distance from the point to the line is the distance along this perpendicular to the line.
Perpendicular equation: x+2y = 0 Point of intersection: (2, -1) Perpendicular distance: square root of 5
Displacement includes the distance between the starting and ending points and the direction in which you travel.
The length of a line segment that starts at the point and is perpendicular to the original line.
force x perpendicular distance from a specific, defined point
It the point is on the line the distance is 0. If the point is not on the line, then it is possible to draw a unique line from the point to the line which is perpendicular to the line. The distance from the point to the line is the distance along this perpendicular to the line.
Its perpendicular distance.
the length of a perpendicular segment from the point to the line
Multiply each force acting on the object by its perpendicular distance from the point. Add all these together, making sure that the ones acting in a clockwise direction have the opposite sign to those acting in the counter-clockwise direction.
Perpendicular equation: x+2y = 0 Point of intersection: (2, -1) Perpendicular distance: square root of 5
If a point is on the perpendicular bisector of a segment, then it is equidistant, or the same distance, from the endpoints of the segment.
In which direction? IN the direction perpendicular to the planetary plane it is just plain space. Even in the planetary plane, any point at a distance of 5900 million miles from the sun is empty most of the time.
No it is measured from the edge
the direction of OP is call radial direction of the moving point p while the direction of OQ which is perpendicular to OP in the sense of (theta)angle is called transverse direction of the moving point P.
The arm is perpendicular to the axis of rotation. If you look at the axis along its axis it is only a point. The torque is force times distance tot that point
It is a plane perpendicular to the lens at the focal distance from the lens. All parallel light entering the lens from a certain direction falls on a single point somewhere on this plane. Where the point of light falls depends on what angle the "wall" of light enters the lens.
Displacement includes the distance between the starting and ending points and the direction in which you travel.