Join Geometries

The main object of this book is to reorient and revitalize classical geometry in a way that will bring it closer to the mainstream of contemporary mathematics. The postulational basis of the subject will be radically revised in order to construct a broad-scale and conceptually unified treatment. The familiar figures of classical geometry-points, segments, lines, planes, triangles, circles, and so on-stem from problems in the physical world and seem to be conceptually unrelated. However, a natural setting for their study is provided by the concept of convex set, which is compara tively new in the history of geometrical ideas. The familiarfigures can then appear as convex sets, boundaries of convex sets, or finite unions of convex sets. Moreover, two basic types of figure in linear geometry are special cases of convex set: linear space (point, line, and plane) and halfspace (ray, halfplane, and halfspace). Therefore we choose convex set to be the central type of figure in our treatment of geometry. How can the wealth of geometric knowledge be organized around this idea? By defini tion, a set is convex if it contains the segment joining each pair of its points; that is, if it is closed under the operation of joining two points to form a segment. But this is precisely the basic operation in Euclid.

Inhalt
1 The Join and Extension Operations in Euclidean Geometry.- 1.1 The Notion of Segment: Closed and Open.- 1.2 The Join of Two Distinct Points.- 1.3 Two Basic Properties of the Join Operation.- 1.4 A Crucial Question.- 1.5 The Join of Two Geometric Figures.- 1.6 Joins of Several Points: Does the Associative Law Hold?.- 1.7 The Join of Two Intersecting Geometric Figures.- 1.8 A Decision Must Be Made.- 1.9 The Join of a Point and Itself.- 1.10 The Unrestricted Applicability of the Join Operation.- 1.11 The Unrestricted Validity of the Associative Law for Join.- 1.12 The Universality of the Associative Law.- 1.13 Alternatives to the Definition aa = a.- 1.14 Convex Sets.- 1.15 A Geometric Proof in Join Terminology.- 1.16 A New Operation: The Idea of Extension.- 1.17 The Notion of Halfline or Ray.- 1.18 Formal Definition of the Extension Operation.- 1.19 Identification of Extension as a Geometrical Figure.- 1.20 Properties of the Extension Operation.- 1.21 The Extension of Two Geometric Figures.- 1.22 The Generation of Unbounded or Endless Figures.- 1.23 Is There an Alternative to Join as Open Segment?.- 2 The Abstract Theory of Join Operations.- 2.1 The Join Operation in Euclidean Geometry.- 2.2 Join Operations in a Set-Join Systems.- 2.3 The Postulates for the Operation Join.- 2.4 Application of the Theory to Euclidean Geometry.- 2.5 Elementary Properties of Join.- 2.6 Generalizations of J1-J4 to Sets.- 2.7 Extension of the Join Operation to n Terms.- 2.8 Comparison with the Conventional View of Geometry.- 2.9 Convex Sets.- 2.10 Joins, Intersections and Unions of Convex Sets.- 2.11 Interiors and Frontiers of Convex Sets.- 2.12 Euclidean Interiors and Frontiers.- 2.13 Interiority Properties of Convex Sets.- 2.14 Absorption by Joining.- 2.15 Closures of Euclidean Convex Sets, Intuitively Treated.- 2.16 The Closure of a Convex Set.- 2.17 Closure Properties of Convex Sets.- 2.18 Composition of the Interior and Closure Functions.- 2.19 The Boundary of a Convex Set.- 2.20 Project: Another Formulation of the Theory of Join.- 2.21 What Does the Theory Apply To?.- 2.22 The Triode Model.- 2.23 A Peculiarity of the Triode Model.- 2.24 The Cartesian Join Model.- 2.25 The Metric Interior of a Set in Euclidean Geometry.- 2.26 The Metric Closure of a Set in Euclidean Geometry.- 3 The Generation of Convex Sets-Convex Hulls.- 3.1 Introduction to Convexification: Two Euclidean Examples.- 3.2 Convexification of an Arbitrary Set.- 3.3 Finitely Generated Convex Sets-the Concept of Polytope.- 3.4 A Formula for a Polytope.- 3.5 A Distributive Law.- 3.6 An Absorption Property of Polytopes.- 3.7 Interiors and Closures of Polytopes.- 3.8 Powers of a Set and Polytopes.- 3.9 The Representation of Convex Hulls.- 3.10 Convex Hulls and Powers of a Set.- 3.11 Bounded Sets.- 3.12 Project-the Closed Join Operation.- 3.13 Convex Hulls of Finite Families of Sets-Generalized Polytopes.- 3.14 Properties of Generalized Polytopes.- 3.15 Examples of Generalized Polytopes.- 4 The Operation of Extension.- 4.1 Definition of the Extension Operation.- 4.2 The Extension Operation for Sets.- 4.3 The Monotonic Law for Extension.- 4.4 Distributive Laws for Extension.- 4.5 The Relation "Intersects" or "Meets".- 4.6 The Three Term Transposition Law.- 4.7 The Mixed Associative Law.- 4.8 Three New Postulates.- 4.9 Discussion of the Postulates.- 4.10 Formal Consequences of the Postulate Set J1-J7.- 4.11 Formal Consequences Continued.- 4.12 Joins and Extensions of Rays.- 4.13 Solving Problems.- 4.14 Extreme Points of Convex Sets.- 4.15 Open Convex Sets.- 4.16 The Intersection of Open Sets.- 4.17 The Join of Open Sets.- 4.18 Segments Are Infinite.- 4.19 The Polytope Interior Theorem.- 4.20 The Interior of a Join of Convex Sets.- 4.21 The Generalized Polytope Interior Theorem.- 4.22 Closed Convex Sets.- 4.23 The Theory of Order.- 4.24 Ordered Sets of Points.- 4.25 Separation of Points by a Point.- 4.26 Perspectivity and Precedence of Points.- 5 Join Geometries.- 5.1 The Concept of a Join Geometry.- 5.2 A List of Join Geometries.- 5.3 Deducibility and Counterexamples.- 5.4 The Existence of Points.- 5.5 Isomorphism of Join Systems.- 5.6 A Class of Join Geometries of Arbitrary Dimension.- 5.7 ?n Is Converted into a Vector Space.- 5.8 Restatement of the Definition of Join in ?n.- 5.9 Proof That (?n, ·) Is a Join Geometry.- 5.10 Linear Inequalities and Halfspaces.- 5.11 Pathological Convex Sets.- 5.12 An Infinite Dimensional Join Geometry.- 5.13 Three Pathological Convex Sets.- 5.14 Is There a Simple Way to Construct Pathological Convex Sets?.- 6 Linear Sets.- 6.1 The Notion of Linear Set.- 6.2 The Definition of Linear Set.- 6.3 Conditions for Linearity.- 6.4 Constructing Linear Sets from Linear Sets.- 6.5 The Construction of a Linear Set from a Convex Set.- 6.6 Linear Sets Give Rise to Join Geometries.- 6.7 The Generation of Linear Sets: Two Euclidean Examples.- 6.8 The Generation of Linear Sets: General Case.- 6.9 The Linear Hull of a Finite Set: Finitely Generated Linear Sets.- 6.10 The Definition of Line.- 6.11 The Linear Hull of an Arbitrary Set.- 6.12 The Linear Hull of a Finite Family of Sets.- 6.13 Linear Hulls of Interiors and Closures.- 6.14 Geometric Relations of Points-Linear Dependence and Independence.- 6.15 Properties of Linearly Independent Points.- 6.16 Simplexes.- 6.17 Linear Dependence and Intersection of Joins.- 6.18 Covering in the Family of Linear Sets-Hyperplanes.- 6.19 The Height of a Linear Set-Approach to a Theory of Dimension.- 6.20 Linear Sets and the Interior Operation.- 6.21 Applications: Interiority Properties.- 6.22 The Prevalence of Nonpathological Convex Sets.- 6.23 The Linear Hull of a Pair of Convex Sets.- 6.24 The Interior of the Extension of Two Convex Sets.- 7 Extremal Structure of Convex Sets: Components and Faces.- 7.1 The Notion of an Extreme Set of a Convex Set.- 7.2 The Definition of Extreme Set of a Convex Set.- 7.3 Remarks on the Definition.- 7.4 Elementary Properties of Extreme Sets.- 7.5 The Interior Operation Is Applied to Extreme Sets.- 7.6 The Closure Operation Is Applied to Extreme Sets.- 7.7 Other Characterizations of Extremeness.- 7.8 Is Extremeness Preserved under Join and Extension?.- 7.9 Extreme Sets with a Preassigned Interior Point.- 7.10 Classifying Extreme Sets.- 7.11 Open Extreme Sets: Components.- 7.12 The Partition Theorem for Convex Sets.- 7.13 The Component Structure of a Convex Set.- 7.14 Components as Maximal Open Subsets.- 7.15 Intersection Properties of Components.- 7.16 Components and Perspectivity of Points.- 7.17 Components of Polytopes.- 7.18 The Concept of a Face of a Convex Set.- 7.19 The Nonseparation Property of a Fac…

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