Geometry Module 1, Topic G, Overview
... Make formal geometric constructions with a variety of tools and methods (compass and straightedge, string, reflective devices, paper folding, dynamic geometric software, etc.). Copying a segment; copying an angle; bisecting a segment; bisecting an angle; constructing perpendicular lines, including t ...
... Make formal geometric constructions with a variety of tools and methods (compass and straightedge, string, reflective devices, paper folding, dynamic geometric software, etc.). Copying a segment; copying an angle; bisecting a segment; bisecting an angle; constructing perpendicular lines, including t ...
Toolbox - Ephrata School
... 7-2 Ratios in Similar Polygons Example 1: Describing Similar Polygons Identify the pairs of congruent angles and corresponding sides. ∠N ≅ ∠Q and ∠P ≅ ∠R. By the Third Angles Theorem, ∠M ≅ ∠T. ...
... 7-2 Ratios in Similar Polygons Example 1: Describing Similar Polygons Identify the pairs of congruent angles and corresponding sides. ∠N ≅ ∠Q and ∠P ≅ ∠R. By the Third Angles Theorem, ∠M ≅ ∠T. ...
Unit descriptions
... magnitude of the resultant of two perpendicular vectors by using the Pythagorean theorem. G- 6.8 Carry out a procedure to determine the direction of the resultant of two perpendicular vectors by using a scale drawing and direct ...
... magnitude of the resultant of two perpendicular vectors by using the Pythagorean theorem. G- 6.8 Carry out a procedure to determine the direction of the resultant of two perpendicular vectors by using a scale drawing and direct ...
Holt McDougal Geometry
... Apply properties of similar polygons to solve problems. Holt McDougal Geometry ...
... Apply properties of similar polygons to solve problems. Holt McDougal Geometry ...
Lie sphere geometry
Lie sphere geometry is a geometrical theory of planar or spatial geometry in which the fundamental concept is the circle or sphere. It was introduced by Sophus Lie in the nineteenth century. The main idea which leads to Lie sphere geometry is that lines (or planes) should be regarded as circles (or spheres) of infinite radius and that points in the plane (or space) should be regarded as circles (or spheres) of zero radius.The space of circles in the plane (or spheres in space), including points and lines (or planes) turns out to be a manifold known as the Lie quadric (a quadric hypersurface in projective space). Lie sphere geometry is the geometry of the Lie quadric and the Lie transformations which preserve it. This geometry can be difficult to visualize because Lie transformations do not preserve points in general: points can be transformed into circles (or spheres).To handle this, curves in the plane and surfaces in space are studied using their contact lifts, which are determined by their tangent spaces. This provides a natural realisation of the osculating circle to a curve, and the curvature spheres of a surface. It also allows for a natural treatment of Dupin cyclides and a conceptual solution of the problem of Apollonius.Lie sphere geometry can be defined in any dimension, but the case of the plane and 3-dimensional space are the most important. In the latter case, Lie noticed a remarkable similarity between the Lie quadric of spheres in 3-dimensions, and the space of lines in 3-dimensional projective space, which is also a quadric hypersurface in a 5-dimensional projective space, called the Plücker or Klein quadric. This similarity led Lie to his famous ""line-sphere correspondence"" between the space of lines and the space of spheres in 3-dimensional space.