49,490 research outputs found
Artificial intelligence for improved fitting of trajectories of elementary particles in inhomogeneous dense materials immersed in a magnetic field
In this article, we use artificial intelligence algorithms to show how to
enhance the resolution of the elementary particle track fitting in
inhomogeneous dense detectors, such as plastic scintillators. We use deep
learning to replace more traditional Bayesian filtering methods, drastically
improving the reconstruction of the interacting particle kinematics. We show
that a specific form of neural network, inherited from the field of natural
language processing, is very close to the concept of a Bayesian filter that
adopts a hyper-informative prior. Such a paradigm change can influence the
design of future particle physics experiments and their data exploitation
Approximate Bayesian Deep Learning for Resource-Constrained Environments
Deep learning models have shown promising results in areas including computer vision, natural language processing, speech recognition, and more. However, existing point estimation-based training methods for these models may result in predictive uncertainties that are not well calibrated, including the occurrence of confident errors. Approximate Bayesian inference methods can help address these issues in a principled way by accounting for uncertainty in model parameters. However, these methods are computationally expensive both when computing approximations to the parameter posterior and when using an approximate parameter posterior to make predictions. They can also require significantly more storage than point-estimated models.
In this thesis, we address a range of questions related to trade-offs between the quality of inference and prediction and the computational scalability of Bayesian deep learning methods. We begin by developing a framework for comprehensive evaluation of Bayesian neural network models and applying this framework to a range of existing models and inference methods. Second, we address the problem of providing flexible trade-offs between prediction quality, run time, and storage by developing and evaluating a general framework for distilling expectations with respect to the Bayesian posterior distribution of a deep neural network classifier. Third, we investigate the trade-offs between model sparsity and inference performance for deep neural network models using several approaches to deriving sparse model structures. Fourth, we present a framework for correcting approximate posterior predictive distributions, encouraging them to prefer high-utility decisions. Finally, we investigate the use of approximate Bayesian deep learning in object detection and present an evaluation of approaches for quantifying different facets of uncertainty related to object classes and locations
Symbol Emergence in Robotics: A Survey
Humans can learn the use of language through physical interaction with their
environment and semiotic communication with other people. It is very important
to obtain a computational understanding of how humans can form a symbol system
and obtain semiotic skills through their autonomous mental development.
Recently, many studies have been conducted on the construction of robotic
systems and machine-learning methods that can learn the use of language through
embodied multimodal interaction with their environment and other systems.
Understanding human social interactions and developing a robot that can
smoothly communicate with human users in the long term, requires an
understanding of the dynamics of symbol systems and is crucially important. The
embodied cognition and social interaction of participants gradually change a
symbol system in a constructive manner. In this paper, we introduce a field of
research called symbol emergence in robotics (SER). SER is a constructive
approach towards an emergent symbol system. The emergent symbol system is
socially self-organized through both semiotic communications and physical
interactions with autonomous cognitive developmental agents, i.e., humans and
developmental robots. Specifically, we describe some state-of-art research
topics concerning SER, e.g., multimodal categorization, word discovery, and a
double articulation analysis, that enable a robot to obtain words and their
embodied meanings from raw sensory--motor information, including visual
information, haptic information, auditory information, and acoustic speech
signals, in a totally unsupervised manner. Finally, we suggest future
directions of research in SER.Comment: submitted to Advanced Robotic
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