29,360 research outputs found
Online Tool Condition Monitoring Based on Parsimonious Ensemble+
Accurate diagnosis of tool wear in metal turning process remains an open
challenge for both scientists and industrial practitioners because of
inhomogeneities in workpiece material, nonstationary machining settings to suit
production requirements, and nonlinear relations between measured variables and
tool wear. Common methodologies for tool condition monitoring still rely on
batch approaches which cannot cope with a fast sampling rate of metal cutting
process. Furthermore they require a retraining process to be completed from
scratch when dealing with a new set of machining parameters. This paper
presents an online tool condition monitoring approach based on Parsimonious
Ensemble+, pENsemble+. The unique feature of pENsemble+ lies in its highly
flexible principle where both ensemble structure and base-classifier structure
can automatically grow and shrink on the fly based on the characteristics of
data streams. Moreover, the online feature selection scenario is integrated to
actively sample relevant input attributes. The paper presents advancement of a
newly developed ensemble learning algorithm, pENsemble+, where online active
learning scenario is incorporated to reduce operator labelling effort. The
ensemble merging scenario is proposed which allows reduction of ensemble
complexity while retaining its diversity. Experimental studies utilising
real-world manufacturing data streams and comparisons with well known
algorithms were carried out. Furthermore, the efficacy of pENsemble was
examined using benchmark concept drift data streams. It has been found that
pENsemble+ incurs low structural complexity and results in a significant
reduction of operator labelling effort.Comment: this paper has been published by IEEE Transactions on Cybernetic
Big Data and Reliability Applications: The Complexity Dimension
Big data features not only large volumes of data but also data with
complicated structures. Complexity imposes unique challenges in big data
analytics. Meeker and Hong (2014, Quality Engineering, pp. 102-116) provided an
extensive discussion of the opportunities and challenges in big data and
reliability, and described engineering systems that can generate big data that
can be used in reliability analysis. Meeker and Hong (2014) focused on large
scale system operating and environment data (i.e., high-frequency multivariate
time series data), and provided examples on how to link such data as covariates
to traditional reliability responses such as time to failure, time to
recurrence of events, and degradation measurements. This paper intends to
extend that discussion by focusing on how to use data with complicated
structures to do reliability analysis. Such data types include high-dimensional
sensor data, functional curve data, and image streams. We first provide a
review of recent development in those directions, and then we provide a
discussion on how analytical methods can be developed to tackle the challenging
aspects that arise from the complexity feature of big data in reliability
applications. The use of modern statistical methods such as variable selection,
functional data analysis, scalar-on-image regression, spatio-temporal data
models, and machine learning techniques will also be discussed.Comment: 28 pages, 7 figure
Aging concrete structures: a review of mechanics and concepts
The safe and cost-efficient management of our built infrastructure is a challenging task considering the expected service life of at least 50 years. In spite of time-dependent changes in material properties, deterioration processes and changing demand by society, the structures need to satisfy many technical requirements related to serviceability, durability, sustainability and bearing capacity. This review paper summarizes the challenges associated with the safe design and maintenance of aging concrete structures and gives an overview of some concepts and approaches that are being developed to address these challenges
Active inference and oculomotor pursuit: the dynamic causal modelling of eye movements.
This paper introduces a new paradigm that allows one to quantify the Bayesian beliefs evidenced by subjects during oculomotor pursuit. Subjects' eye tracking responses to a partially occluded sinusoidal target were recorded non-invasively and averaged. These response averages were then analysed using dynamic causal modelling (DCM). In DCM, observed responses are modelled using biologically plausible generative or forward models - usually biophysical models of neuronal activity
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