Bisection

From Wikipedia, the free encyclopedia

For the numerical analysis algorithm, see bisection method. For the musical set theory concept see bisector (music). For the bisection theorem, see ham sandwich theorem.

Line ED bisects line AB at D, line EF is a perpendicular bisector of segment AD at C and the interior bisector of right angle AED

Bisection is the general activity of dividing something into two parts.

In geometry, the concept is limited to divisions into two equal parts, usually by a line, which is then called a bisector. The most often considered types of bisectors are segment bisectors and angle bisectors.

A segment bisector passes through the midpoint of the segment. Particularly important is the perpendicular bisector of a segment, which, according to its name, meets the segment at right angles. The perpendicular bisector of a segment also has the property that each of its points is equidistant from the segment's endpoints. Therefore Voronoi diagram boundaries consist of segments of such lines or planes.

An angle bisector divides the angle into two equal angles. An angle only has one bisector. Each point of an angle bisector is equidistant from the sides of the angle. The interior bisector of an angle is the line or line segment that divides it into two equal angles on the same side as the angle. The exterior bisector of an angle is the line or line segment that divides it into two equal angles on the opposite side as the angle.

In classical geometry, the bisection is a simple compass and straightedge, whose possibility depends on the ability to draw circles of equal radii and different centers.

Finding a perpendicular bisector of a line using a compass and ruler

The segment is bisected by drawing intersecting circles of equal radius, whose centers are the endpoints of the segment. The line determined by the points of intersection is the perpendicular bisector, and crosses our original segment at its center. Alternately, if a line and a point on it are given, we can find a perpendicular bisector by drawing a single circle whose center is that point. The circle intersects the line in two more points, and from here the problem reduces to bisecting the segment defined by these two points.

Bisection of an angle using a compass and ruler

To bisect an angle, one draws a circle whose center is the vertex. The circle meets the angle at two points: one on each leg. Using each of these points as a center, draw two circles of the same size. The intersection of the circles (two points) determines a line that is the angle bisector.

The proof of the correctness of these two constructions is fairly intuitive, relying on the symmetry of the problem. It is interesting to note that the trisection of an angle (dividing it into three equal parts) is somewhat more difficult, and cannot be achieved with the ruler and compass alone (Pierre Wantzel).

The angle bisectors of the angles of a triangle are concurrent in a point called the incenter of the triangle.