eBook - ePub
Crossing Numbers of Graphs
Marcus Schaefer
This is a test
Compartir libro
- 350 páginas
- English
- ePUB (apto para móviles)
- Disponible en iOS y Android
eBook - ePub
Crossing Numbers of Graphs
Marcus Schaefer
Detalles del libro
Vista previa del libro
Índice
Citas
Información del libro
Crossing Numbers of Graphs is the first book devoted to the crossing number, an increasingly popular object of study with surprising connections. The field has matured into a large body of work, which includes identifiable core results and techniques. The book presents a wide variety of ideas and techniques in topological graph theory, discrete geometry, and computer science.
The first part of the text deals with traditional crossing number, crossing number values, crossing lemma, related parameters, computational complexity, and algorithms. The second part includes the rich history of alternative crossing numbers, the rectilinear crossing number, the pair crossing number, and the independent odd crossing number.It also includes applications of the crossing number outside topological graph theory.
- Aimed at graduate students and professionals in both mathematics and computer science
- The first book of its kind devoted to the topic
- Authored by a noted authority in crossing numbers
Preguntas frecuentes
¿Cómo cancelo mi suscripción?
¿Cómo descargo los libros?
Por el momento, todos nuestros libros ePub adaptables a dispositivos móviles se pueden descargar a través de la aplicación. La mayor parte de nuestros PDF también se puede descargar y ya estamos trabajando para que el resto también sea descargable. Obtén más información aquí.
¿En qué se diferencian los planes de precios?
Ambos planes te permiten acceder por completo a la biblioteca y a todas las funciones de Perlego. Las únicas diferencias son el precio y el período de suscripción: con el plan anual ahorrarás en torno a un 30 % en comparación con 12 meses de un plan mensual.
¿Qué es Perlego?
Somos un servicio de suscripción de libros de texto en línea que te permite acceder a toda una biblioteca en línea por menos de lo que cuesta un libro al mes. Con más de un millón de libros sobre más de 1000 categorías, ¡tenemos todo lo que necesitas! Obtén más información aquí.
¿Perlego ofrece la función de texto a voz?
Busca el símbolo de lectura en voz alta en tu próximo libro para ver si puedes escucharlo. La herramienta de lectura en voz alta lee el texto en voz alta por ti, resaltando el texto a medida que se lee. Puedes pausarla, acelerarla y ralentizarla. Obtén más información aquí.
¿Es Crossing Numbers of Graphs un PDF/ePUB en línea?
Sí, puedes acceder a Crossing Numbers of Graphs de Marcus Schaefer en formato PDF o ePUB, así como a otros libros populares de Mathematics y Counting & Numeration. Tenemos más de un millón de libros disponibles en nuestro catálogo para que explores.
Información
Part II
Crossing Number Variants
Chapter 5
The Rectilinear Crossing Number: Rectilinear and Pseudolinear Drawings
5.1 A First Look
Recall that in a rectilinear (also called geometric or straight-line) drawing of a graph, edges are realized by straight-line segments (without bends). The rectilinear crossing number, , of a graph G is the smallest number of crossings in any rectilinear drawing of G. If , then G is planar, and, as it turns out, the reverse is also true, a result known by many names.
Theorem 5.1 (Fary’s (Wagner’s, Stein’s) Theorem [132, 320, 347]). Every planar graph has a rectilinear embedding.
We use a simple geometric fact: every polygon of length at most 5 is starshaped; that is, it contains a point in its interior which can see all points in the polygon, in the sense that it can be connected by a straight-line segment—lying within the polygon—to any other point inside the polygon. (Triangulate the polygon; there are at most three triangles, so there must be a vertex belonging to all triangles; that vertex, and points in a wedge close to it will do.)
Proof. We prove by induction on the number of vertices that every plane graph has a rectilinear embedding with the same rotation scheme. The result is clear for graphs with n ≤ 3 vertices, so we can assume that there are at least 4 vertices. By Euler’s formula, Corollary A.5, there is a vertex v of degree at most 5. Inductively find a rectilinear embedding of G − v. We need to argue that we can add v back into the face from which it was removed (the face still exists in the rectilinear embedding, since we maintained the rotation system). But this is possible by the geometric fact we outlined before the proof. □
The proof establishes more than we claimed: the rectilinear embedding we construct is isomorphic to the original embedding. A drawing which is isomorphic to a rectilinear drawing is called stretchable. So Fary’s theorem states that every plane embedding is stretchable. If the graph is 3-connected, we can even guarantee that the rectilinear embedding is strictly convex, that is, all inner faces are strictly convex polygons (all inner angles strictly less than π).1 This is Tutte’s celebrated spring theorem.
Theorem 5.2 (Tutte [338]). Every plane, 3-connected graph is isomorphic to a strictly convex, rectilinear embedding.
Tutte’s result implies Fary’s theorem (Exercise (5.1)), but its proof is more intricate; we recommend [333]. Does Fary’s Theorem remain true in the presence of crossings? The answer is a qualified yes.
Theorem 5.3 (Bienstock and Dean [65]). We have if cr(G) ≤ 3.
The strategy for the proof is simple: add crossing-free edges to G to ensure that G without the crossing edges is a plane, 3-connected graph. Take a strictly convex embedding of this graph, and reinsert the crossing edges. This approach works for cr(G) = 1 (c...