eBook - ePub

Graphs for Pattern Recognition

Name: Graphs for Pattern Recognition
Author: Damir Gainanov

Damir Gainanov

Compartir libro

158 páginas
English
ePUB (apto para móviles)
Disponible en iOS y Android

eBook - ePub

Graphs for Pattern Recognition

Damir Gainanov

Detalles del libro

Vista previa del libro

Índice

Citas

Información del libro

This monograph deals with mathematical constructions that are foundational in such an important area of data mining as pattern recognition. By using combinatorial and graph theoretic techniques, a closer look is taken at infeasible systems of linear inequalities, whose generalized solutions act as building blocks of geometric decision rules for pattern recognition.
Infeasible systems of linear inequalities prove to be a key object in pattern recognition problems described in geometric terms thanks to the committee method. Such infeasible systems of inequalities represent an important special subclass of infeasible systems of constraints with a monotonicity property – systems whose multi-indices of feasible subsystems form abstract simplicial complexes (independence systems), which are fundamental objects of combinatorial topology.
The methods of data mining and machine learning discussed in this monograph form the foundation of technologies like big data and deep learning, which play a growing role in many areas of human-technology interaction and help to find solutions, better solutions and excellent solutions.

Contents:
Preface
Pattern recognition, infeasible systems of linear inequalities, and graphs
Infeasible monotone systems of constraints
Complexes, (hyper)graphs, and inequality systems
Polytopes, positive bases, and inequality systems
Monotone Boolean functions, complexes, graphs, and inequality systems
Inequality systems, committees, (hyper)graphs, and alternative covers
Bibliography
List of notation
Index

Preguntas frecuentes

¿Cómo cancelo mi suscripción?

Simplemente, dirígete a la sección ajustes de la cuenta y haz clic en «Cancelar suscripción». Así de sencillo. Después de cancelar tu suscripción, esta permanecerá activa el tiempo restante que hayas pagado. Obtén más información aquí.

¿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 Graphs for Pattern Recognition un PDF/ePUB en línea?

Sí, puedes acceder a Graphs for Pattern Recognition de Damir Gainanov 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

Editorial

De Gruyter

Año

2016

ISBN

9783110480306

Edición

Categoría

Mathematics

Categoría

Counting & Numeration

1Infeasible monotone systems of constraints

In discrete mathematics, the following research subjects are of prime importance: Let

:= {s1, s2, . . . , sm} be a finite nonempty system of constraints and [m] := {1,2, . . . , m} the set of the indices of constraints with which the elements of the set S are marked. Assigning to the set [m] the Boolean lattice B(m) of all its subsets partially ordered by set-theoretical inclusion, we call an arbitrary element B ∈ B(m) the multiindex of the subsystem {si : i ∈ B} of the system

; in many studies the shorter term index of a subsystem is used. To the relation A ⊆ B of inclusion for the multi-indices A, B ⊆ [m] corresponds the comparison relation A ⪯ B for the elements A and B in the lattice B(m). The set of atoms B(m)(1) := {{1}, {2}, . . . , {m}} of the lattice B(m) is in one-to-one correspondence with the set of constraints

. The least element ô̂ of the lattice B(m) is the multi-index of the empty subsystem 0 of the system

, and the greatest element î̂ of the lattice B(m) is the multi-index [m] of the entire system

Let a map π : B(m) → 2Γ into the family of subsets of some nonempty set Γ be given, with the following properties:

–The empty subsystem of the system S is feasible, that is,

one usually supposes π(ô̂) := Γ.

–Each constraint taken independently is realizable or, in other words, each subsystem consisting of one constraint is feasible:

–Further,

and thus

A, B ∈ 𝔹(m) ⇒π(A) ∩ π(B) ⊇ π(A ∨ B) ,

where A∨B denotes the least upper bound (i.e., the set-union A∪B) of the elements A and B in the lattice 𝔹(m).

–One often considers infeasible systems S such that

We will call any system of constraints

, for which the map π and the range family of this map associated with S satisfy conditions (1.1)–(1.4), a finite infeasible monotone system of constraints.

1.1Structural and combinatorial properties of infeasible monotone systems of constraints

In this chapter, we particularly describe some properties of constraint systems, which are essentially associated with the representativity of sets.

Speaking briefly, the mutual representativity of sets A and B of any kind is related to the answer to the question on the nonemptiness of their intersection A ∩ B.

The subject of this chapter goes back to the standard problem of combinatorial optimization: for a nonempty family A := {A1, . . . , Aα} of nonempty and pairwise distinct subsets of a finite ground set

to describe, from the structural and combinatorial point...