19,478 research outputs found
A systematic review of data quality issues in knowledge discovery tasks
Hay un gran crecimiento en el volumen de datos porque las organizaciones capturan permanentemente la cantidad colectiva de datos para lograr un mejor proceso de toma de decisiones. El desafío mas fundamental es la exploración de los grandes volúmenes de datos y la extracción de conocimiento útil para futuras acciones por medio de tareas para el descubrimiento del conocimiento; sin embargo, muchos datos presentan mala calidad. Presentamos una revisión sistemática de los asuntos de calidad de datos en las áreas del descubrimiento de conocimiento y un estudio de caso aplicado a la enfermedad agrícola conocida como la roya del café.Large volume of data is growing because the organizations are continuously capturing the collective amount of data for better decision-making process. The most fundamental challenge is to explore the large volumes of data and extract useful knowledge for future actions through knowledge discovery tasks, nevertheless many data has poor quality. We presented a systematic review of the data quality issues in knowledge discovery tasks and a case study applied to agricultural disease named coffee rust
CleanML: A Study for Evaluating the Impact of Data Cleaning on ML Classification Tasks
Data quality affects machine learning (ML) model performances, and data
scientists spend considerable amount of time on data cleaning before model
training. However, to date, there does not exist a rigorous study on how
exactly cleaning affects ML -- ML community usually focuses on developing ML
algorithms that are robust to some particular noise types of certain
distributions, while database (DB) community has been mostly studying the
problem of data cleaning alone without considering how data is consumed by
downstream ML analytics. We propose a CleanML study that systematically
investigates the impact of data cleaning on ML classification tasks. The
open-source and extensible CleanML study currently includes 14 real-world
datasets with real errors, five common error types, seven different ML models,
and multiple cleaning algorithms for each error type (including both commonly
used algorithms in practice as well as state-of-the-art solutions in academic
literature). We control the randomness in ML experiments using statistical
hypothesis testing, and we also control false discovery rate in our experiments
using the Benjamini-Yekutieli (BY) procedure. We analyze the results in a
systematic way to derive many interesting and nontrivial observations. We also
put forward multiple research directions for researchers.Comment: published in ICDE 202
A robust approach to model-based classification based on trimming and constraints
In a standard classification framework a set of trustworthy learning data are
employed to build a decision rule, with the final aim of classifying unlabelled
units belonging to the test set. Therefore, unreliable labelled observations,
namely outliers and data with incorrect labels, can strongly undermine the
classifier performance, especially if the training size is small. The present
work introduces a robust modification to the Model-Based Classification
framework, employing impartial trimming and constraints on the ratio between
the maximum and the minimum eigenvalue of the group scatter matrices. The
proposed method effectively handles noise presence in both response and
exploratory variables, providing reliable classification even when dealing with
contaminated datasets. A robust information criterion is proposed for model
selection. Experiments on real and simulated data, artificially adulterated,
are provided to underline the benefits of the proposed method
Basics of Feature Selection and Statistical Learning for High Energy Physics
This document introduces basics in data preparation, feature selection and
learning basics for high energy physics tasks. The emphasis is on feature
selection by principal component analysis, information gain and significance
measures for features. As examples for basic statistical learning algorithms,
the maximum a posteriori and maximum likelihood classifiers are shown.
Furthermore, a simple rule based classification as a means for automated cut
finding is introduced. Finally two toolboxes for the application of statistical
learning techniques are introduced.Comment: 12 pages, 8 figures. Part of the proceedings of the Track
'Computational Intelligence for HEP Data Analysis' at iCSC 200
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