Finite Mixture Models

McLachlan, Geoffrey J.; Lee, Sharon X.; Rathnayake, Suren I.

doi:10.1146/annurev-statistics-031017-100325

Cited by 586 publications

(455 citation statements)

References 121 publications

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“…Readers interested in related techniques are further referred to available books and edited volumes (Bartolucci, Farcomeni, & Pennoni, 2012;Collins & Lanza, 2010;Hagenaars & McCutcheon, 2002;McLachlan & Peel, 2000).…”

Section: Further Model Extensionsmentioning

confidence: 99%

Informative tools for characterizing individual differences in learning: Latent class, latent profile, and latent transition analysis

Hickendorff

Edelsbrunner

McMullen

et al. 2018

Learning and Individual Differences

171

118

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Highlights• learning is often multidimensional, heterogeneous, and discontinuous• traditional statistical analyses are limited in capturing this complexity• latent class and latent profile models identify subgroups of learners• latent transition models characterize discontinuous, non-linear, learning paths• these models contribute to our understanding of learning and individual differences 3 Informative Tools for Characterizing Individual Differences in Learning: Latent Class, Latent Profile, and Latent Transition AnalysisThis article gives an introduction to latent class, latent profile, and latent transition models for researchers interested in investigating individual differences in learning and development. The models allow analyzing how the observed heterogeneity in a group (e.g., individual differences in conceptual knowledge) can be traced back to underlying homogeneous subgroups (e.g., learners differing systematically in their developmental phases). The estimated parameters include a characteristic response pattern for each subgroup, and, in the case of longitudinal data, the probabilities of transitioning from one subgroup to another over time. This article describes the steps involved in using the models, gives practical examples, and discusses limitations and extensions. Overall, the models help to characterize heterogeneous learner populations, multidimensional learning outcomes, nonlinear learning pathways, and changing relations between learning processes. The application of these models can therefore make a substantial contribution to our understanding of learning and individual differences.

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Section: Further Model Extensionsmentioning

confidence: 99%

Informative tools for characterizing individual differences in learning: Latent class, latent profile, and latent transition analysis

Hickendorff

Edelsbrunner

McMullen

et al. 2018

Learning and Individual Differences

171

118

View full text Add to dashboard Cite

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“…Using the language of McLachlan and Peel (2000) and notation of Khalili and Chen (2007), suppose Y i represents the value of a continuous random variable, or response, for subject i = 1, ..., n. Let X ji equal subject i's value for covariate j = 1, ..., p; therefore, X i = (x 1i , x 2i , ..., x pi ) is the vector of covariates for subject i. Next, let f (y; θ k (x), φ k ) for k = 1, .…”

Section: Finite Mixture Of Regressions Modelmentioning

confidence: 99%

A New Semiparametric Approach to Finite Mixture of Regressions using Penalized Regression via Fusion

2020

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Abstract:For some modeling problems a population may be better assessed as an aggregate of unknown subpopulations, each with a distinct relationship between a response and associated variables. The finite mixture of regressions (FMR) model, where an outcome is derived from one of a finite number of linear regression models, is a natural tool in this setting. In this article we first propose a new penalized regression approach, then we demonstrate how it can, in some types of problems, better identify subpopulations and their corresponding models than a semiparametric FMR method. Our new method fits models for each person via grouping pursuit, utilizing a new group truncated L1− penalty (gTLP) that shrinks differences between estimated parameter vectors. The methodology causes the individuals' regression coefficients to cluster into a few common models, in turn revealing previously unknown subpopulations.In fact, by varying the penalty strength, the new method can reveal a hierarchical structure among the subpopulations that can be useful in exploratory analysis. Simulations using FMR models and real data analysis show the performance of the method is promising.

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“…In this study, due to only the target class (i.e., Panax notoginseng fields) is the class of interest, and the task of mapping Panax notoginseng fields can be regarded as a specific single-class data description problem. Hence, 10 SCDDs [47], i.e., the simple Gaussian target distribution data description (SGTD coded as c1) [60]; the robust Gaussian target distribution data description (RGTD coded as c2) [60]; the minimum covariance determinant Gaussian data description (MCDG coded as c3) [60]; the mixture of Gaussian data description (MoG coded as c4) [60]; the auto-encoder neural network data description (AENN coded as c6) [61]; the k-means clustering data description (k-means coded as c7) [62]; the self-organizing map data description (SOM coded as c10) [63]; the minimum spanning tree data description (MST coded as c11) [64]; the k-nearest neighbor data description (K-NN coded as c13) [65]; the incremental support vector data description (IncSVDD coded as c17) [66]; the Parzen density estimator data description (PDE coded as c5, which is a known underestimated descriptor) [67]; and the principal component analysis data description (PCA coded as c9, which is known as an overestimated descriptor) [68].…”

Section: Single-class Data Descriptors (Scdds)mentioning

confidence: 99%

Single-Class Data Descriptors for Mapping Panax notoginseng through P-Learning

Deng

2018

Applied Sciences

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Machine learning-based remote-sensing techniques have been widely used for the production of specific land cover maps at a fine scale. P-learning is a collection of machine learning techniques for training the class descriptors on the positive samples only. Panax notoginseng is a rare medicinal plant, which also has been a highly regarded traditional Chinese medicine resource in China for hundreds of years. Until now, Panax notoginseng has scarcely been observed and monitored from space. Remote sensing of natural resources provides us new insights into the resource inventory of Chinese materia medica resources, particularly of Panax notoginseng. Generally, land-cover mapping involves focusing on a number of landscape classes. However, sometimes a subset or one of the classes will be the only part of interest. In term of this study, the Panax notoginseng field is the right unit class. Such a situation makes single-class data descriptors (SCDDs) especially significant for specific land-cover interpretation. In this paper, we delineated the application such that a stack of SCDDs were trained for remote-sensing mapping of Panax notoginseng fields through P-learning. We employed and compared SCDDs, i.e., the simple Gaussian target distribution, the robust Gaussian target distribution, the minimum covariance determinant Gaussian, the mixture of Gaussian, the auto-encoder neural network, the k-means clustering, the self-organizing map, the minimum spanning tree, the k-nearest neighbor, the incremental support vector data description, the Parzen density estimator, and the principal component analysis; as well as three ensemble classifiers, i.e., the mean, median, and voting combiners. Experiments demonstrate that most SCDDs could achieve promising classification performance. Furthermore, this work utilized a set of the elaborate samples manually collected at a pixel-level by experts, which was intended to be a benchmark dataset for the future work. The measuring performance of SCDDs gives us challenging insights to define the selection criteria and scoring proof for choosing a fine SCDD in mapping a specific landscape class. With the increment of remotely sensed satellite data of the study area, the spatial distribution of Panax notoginseng could be continuously derived in the local area on the basis of SCDDs.

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Finite Mixture Models

Cited by 586 publications

References 121 publications

Informative tools for characterizing individual differences in learning: Latent class, latent profile, and latent transition analysis

Informative tools for characterizing individual differences in learning: Latent class, latent profile, and latent transition analysis

A New Semiparametric Approach to Finite Mixture of Regressions using Penalized Regression via Fusion

Single-Class Data Descriptors for Mapping Panax notoginseng through P-Learning

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