Learning for Graph Matching and Related Combinatorial Optimization Problems

This survey gives a selective review of recent development of machine learning (ML) for combinatorial optimization (CO), especially for graph matching. The synergy of these two well-developed areas (ML and CO) can potentially give transformative change to artificial intelligence, whose foundation relates to these two building blocks. For its representativeness and wide-applicability, this paper is more focused on the problem of weighted graph matching, especially from the learning perspective. For graph matching, we show that many learning techniques e.g. convolutional neural networks, graph neural networks, reinforcement learning can be effectively incorporated in the paradigm for extracting the node features, graph structure features, and even the matching engine. We further present outlook for the new settings for learning graph matching, and direction towards more integrated combinatorial optimization solvers with prediction models, and also the mutual embrace of traditional solver and machine learning components.

Download Full-text

Neural Networks with the Linked State Transition for Constraint Satisfaction and Their Applications to Combinatorial Optimization Problems

Transactions of the Society of Instrument and Control Engineers ◽

10.9746/sicetr1965.31.622 ◽

1995 ◽

Vol 31 (5) ◽

pp. 622-630

Author(s):

Takuya WAKUTSU ◽

Eitaro AIYOSHI

Keyword(s):

Neural Networks ◽

Combinatorial Optimization ◽

Constraint Satisfaction ◽

State Transition ◽

Optimization Problems ◽

Combinatorial Optimization Problems

Download Full-text

MREM, Discrete Recurrent Network for Optimization

Encyclopedia of Artificial Intelligence ◽

10.4018/978-1-59904-849-9.ch163 ◽

2011 ◽

pp. 1112-1120

Author(s):

Enrique Mérida-Casermeiro ◽

Domingo López-Rodríguez ◽

Juan M. Ortiz-de-Lazcano-Lobato

Keyword(s):

Neural Networks ◽

Combinatorial Optimization ◽

Image Recognition ◽

Single Neuron ◽

Optimization Problems ◽

Neural Model ◽

Recurrent Network ◽

Neural Models ◽

Seminal Work ◽

Combinatorial Optimization Problems

Since McCulloch and Pitts’ seminal work (McCulloch & Pitts, 1943), several models of discrete neural networks have been proposed, many of them presenting the ability of assigning a discrete value (other than unipolar or bipolar) to the output of a single neuron. These models have focused on a wide variety of applications. One of the most important models was developed by J. Hopfield in (Hopfield, 1982), which has been successfully applied in fields such as pattern and image recognition and reconstruction (Sun et al., 1995), design of analogdigital circuits (Tank & Hopfield, 1986), and, above all, in combinatorial optimization (Hopfield & Tank, 1985) (Takefuji, 1992) (Takefuji & Wang, 1996), among others. The purpose of this work is to review some applications of multivalued neural models to combinatorial optimization problems, focusing specifically on the neural model MREM, since it includes many of the multivalued models in the specialized literature.

Download Full-text

Hardware combinatorial optimization problems solver by hysteresis neural networks

ISCAS 2001. The 2001 IEEE International Symposium on Circuits and Systems (Cat. No.01CH37196) ◽

10.1109/iscas.2001.921373 ◽

2002 ◽

Author(s):

T. Nakaguchi ◽

K. Jin'no ◽

M. Tanaka

Keyword(s):

Neural Networks ◽

Combinatorial Optimization ◽

Optimization Problems ◽

Combinatorial Optimization Problems

Download Full-text

Artificial Higher Order Neural Networks for Modeling Combinatorial Optimization Problems

Artificial Higher Order Neural Networks for Modeling and Simulation ◽

10.4018/978-1-4666-2175-6.ch003 ◽

2013 ◽

pp. 44-57

Author(s):

Yuxin Ding

Keyword(s):

Neural Networks ◽

Combinatorial Optimization ◽

Convergence Rates ◽

Optimization Problems ◽

High Order ◽

Hopfield Network ◽

Hopfield Networks ◽

Combinatorial Optimization Problems ◽

Complete Problems ◽

Higher Order Neural Networks

Traditional Hopfield networking has been widely used to solve combinatorial optimization problems. However, high order Hopfiled networks, as an expansion of traditional Hopfield networks, are seldom used to solve combinatorial optimization problems. In theory, compared with low order networks, high order networks have better properties, such as stronger approximations and faster convergence rates. In this chapter, the authors focus on how to use high order networks to model combinatorial optimization problems. Firstly, the high order discrete Hopfield Network is introduced, then the authors discuss how to find the high order inputs of a neuron. Finally, the construction method of energy function and the neural computing algorithm are presented. In this chapter, the N queens problem and the crossbar switch problem, which are NP-complete problems, are used as examples to illustrate how to model practical problems using high order neural networks. The authors also discuss the performance of high order networks for modeling the two combinatorial optimization problems.

Download Full-text