Global ETD Search

91	Recurrent neural networks in the chemical process industries Lourens, Cecil Albert 04 September 2012 (has links) M.Ing. / This dissertation discusses the results of a literature survey into the theoretical aspects and development of recurrent neural networks. In particular, the various architectures and training algorithms developed for recurrent networks are discussed. The various characteristics of importance for the efficient implementation of recurrent neural networks to model dynamical nonlinear processes have also been investigated and are discussed. Process control has been identified as a field of application where recurrent networks may play an important role. The model based adaptive control strategy is briefly introduced and the application of recurrent networks to both the direct- and the indirect adaptive control strategy highlighted. In conclusion, the important areas of future research for the successful implementation of recurrent networks in adaptive nonlinear control are identified Neural networks (Computer science)
92	Formation of the complex neural networks under multiple constraints Chen, Yuhan 01 January 2013 (has links) No description available. Neural networks (Computer science)
93	A model of adaptive invariance Wood, Jeffrey James January 1995 (has links) This thesis is about adaptive invariance, and a new model of it: the Group Representation Network. We begin by discussing the concept of adaptive invariance. We then present standard background material, mostly from the fields of group theory and neural networks. Following this we introduce the problem of invariant pattern recognition and describe a number of methods for solving various instances of it. Next, we define the Symmetry Network, a connectionist model of permutation invariance, and we develop some new theory of this model. We also extend the applicability of the Symmetry Network to arbitrary finite group actions. We then introduce the Group Representation Network (GRN) as an abstract model, with which in principle we can construct concomitants between arbitrary group representations. We show that the GRN can be regarded as a neural network model, and that it includes the Symmetry Network as a submodel. We apply group representation theory to the analysis of GRNs. This yields general characterizations of the allowable activation functions in a GRN and of their weight matrix structure. We examine various generalizations and restricted cases of the GRN model, and in particular look at the construction of GRNs over infinite groups. We then consider the issue of a GRN's discriminability, which relates to the problem of graph isomorphism. We look next at the computational abilities of the GRN, and postulate that it is capable of approximately computing any group concomitant. We show constructively that any polynomial concomitant can be computed by a GRN. We also prove that a variety of standard models for invariant pattern recognition can be viewed as special instances of the GRN model. Finally, we propose that the GRN model may be biologically plausible and give suggestions for further research. 621.3192 Neural networks
94	The combination of AI modelling techniques for the simulation of manufacturing processes Korn, Stefan January 1998 (has links) No description available. 670.285 Artifical neural networks
95	COLANDER: Convolving Layer Network Derivation for E-recommendations Timokhin, Dmitriy 01 June 2021 (has links) (PDF) Many consumer facing companies have large scale data sets that they use to create recommendations for their users. These recommendations are usually based off information the company has on the user and on the item in question. Based on these two sets of features, models are created and tuned to produce the best possible recommendations. A third set of data that exists in most cases is the presence of past interactions a user may have had with other items. The relationships that a model can identify between this information and the other two types of data, we believe, can improve the prediction of how a user may interact with the given item. We propose a method that can inform the model of these relationships during the training phase while only relying on the user and item data during the prediction phase. Using ideas from convolutional neural networks (CNN) and collaborative filtering approaches, our method manipulated the weights in the first layer of our network design in a way that achieves this goal. Recommender Systems Neural Networks
96	A neural network approach to burst detection Mounce, Steve R., Day, Andrew J., Wood, Alastair S., Khan, Asar, Widdop, Peter D., Machell, James January 2002 (has links) No Neural networks Burst detection
97	The implementation of generalised models of magnetic materials using artificial neural networks Saliah-Hassane, Hamadou 09 1900 (has links) No description available. Artificial neural networks
98	On the trainability, stability, representability, and realizability of artificial neural networks Wang, Jun January 1991 (has links) No description available. artificial neural networks
99	The role of interpretable neural architectures: from image classification to neural fields Sambugaro, Zeno 07 1900 (has links) Neural networks have demonstrated outstanding capabilities, surpassing human expertise across diverse tasks. Despite these advances, their widespread adoption is hindered by the complexity of interpreting their decision-making processes. This lack of transparency raises concerns in critical areas such as autonomous mobility, digital security, and healthcare. This thesis addresses the critical need for more interpretable and efficient neural-based technologies, aiming to enhance their transparency and lower their memory footprint. In the first part of this thesis we introduce Agglomerator and Agglomerator++, two frameworks that embody the principles of hierarchical representation to improve the understanding and interpretability of neural networks. These models aim to bridge the cognitive gap between human visual perception and computational models, effectively enhancing the capability of neural networks to dynamically represent complex data. The second part of the manuscript focuses on addressing the lack of spatial coherency and thereby efficiency of the latest fast-training neural field representations. To address this limitation we propose Lagrangian Hashing, a novel method that combines the efficiency of Eulerian grid-based representations with the spatial flexibility of Lagrangian point-based systems. This method extends the foundational work of hierarchical hashing, allowing for an adaptive allocation of the representation budget. In this way we effectively preserve the coherence of the neural structure with respect to the reconstructed 3D space. Within the context of 3D reconstruction we also conduct a comparative evaluation of the NeRF based reconstruction methodologies against traditional photogrammetry, to assess their usability in practical, real-world settings. NeRF, Neural Networks, Interpretability
100	Computational Complexity of Hopfield Networks Tseng, Hung-Li 08 1900 (has links) There are three main results in this dissertation. They are PLS-completeness of discrete Hopfield network convergence with eight different restrictions, (degree 3, bipartite and degree 3, 8-neighbor mesh, dual of the knight's graph, hypercube, butterfly, cube-connected cycles and shuffle-exchange), exponential convergence behavior of discrete Hopfield network, and simulation of Turing machines by discrete Hopfield Network. Hopfield networks Neural networks Neural networks (Computer science)

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