Merging Two Cultures: Deep and Statistical Learning

dc.contributor.authorBhadra, Anindyaen
dc.contributor.authorDatta, Jyotishkaen
dc.contributor.authorPolson, Nicken
dc.contributor.authorSokolov, Vadimen
dc.contributor.authorXu, Jianengen
dc.date.accessioned2024-01-19T14:52:20Zen
dc.date.available2024-01-19T14:52:20Zen
dc.date.issued2021-10-21en
dc.description.abstractMerging the two cultures of deep and statistical learning provides insights into structured high-dimensional data. Traditional statistical modeling is still a dominant strategy for structured tabular data. Deep learning can be viewed through the lens of generalized linear models (GLMs) with composite link functions. Sufficient dimensionality reduction (SDR) and sparsity performs nonlinear feature engineering. We show that prediction, interpolation and uncertainty quantification can be achieved using probabilistic methods at the output layer of the model. Thus a general framework for machine learning arises that first generates nonlinear features (a.k.a factors) via sparse regularization and stochastic gradient optimisation and second uses a stochastic output layer for predictive uncertainty. Rather than using shallow additive architectures as in many statistical models, deep learning uses layers of semi affine input transformations to provide a predictive rule. Applying these layers of transformations leads to a set of attributes (a.k.a features) to which predictive statistical methods can be applied. Thus we achieve the best of both worlds: scalability and fast predictive rule construction together with uncertainty quantification. Sparse regularisation with un-supervised or supervised learning finds the features. We clarify the duality between shallow and wide models such as PCA, PPR, RRR and deep but skinny architectures such as autoencoders, MLPs, CNN, and LSTM. The connection with data transformations is of practical importance for finding good network architectures. By incorporating probabilistic components at the output level we allow for predictive uncertainty. For interpolation we use deep Gaussian process and ReLU trees for classification. We provide applications to regression, classification and interpolation. Finally, we conclude with directions for future research.en
dc.description.notesarXiv admin note: text overlap with arXiv:2106.14085en
dc.description.versionAccepted versionen
dc.format.mimetypeapplication/pdfen
dc.identifier.doihttps://doi.org/10.48550/arxiv.2110.11561en
dc.identifier.orcidDatta, Jyotishka [0000-0001-5991-5182] [0000-0002-5052-7586]en
dc.identifier.otherarXiv:2110.11561en
dc.identifier.urihttps://hdl.handle.net/10919/117414en
dc.language.isoenen
dc.relation.urihttp://arxiv.org/abs/2110.11561v1en
dc.rightsIn Copyrighten
dc.rights.urihttp://rightsstatements.org/vocab/InC/1.0/en
dc.subjectDeep learningen
dc.titleMerging Two Cultures: Deep and Statistical Learningen
dc.title.serialWIREs Computational Statisticsen
dc.typeArticle - Refereeden
dc.type.dcmitypeTexten
dc.type.otherArticleen
dcterms.dateAccepted2023-12-13en
pubs.organisational-group/Virginia Techen
pubs.organisational-group/Virginia Tech/Scienceen
pubs.organisational-group/Virginia Tech/Science/Statisticsen
pubs.organisational-group/Virginia Tech/All T&R Facultyen
pubs.organisational-group/Virginia Tech/Science/COS T&R Facultyen
pubs.organisational-group/Virginia Tech/Science/Statistics/Center for Biostatistics & Health Data Science (CBHDS)en

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