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Line 3: '''t-distributed stochastic neighbor embedding (t-SNE)''' is a [[machine learning]] algorithm for [[dimensionality reduction]] developed by [[Laurens van der Maaten]] and [[Geoffrey Hinton]].<ref>{{cite journal\|last=van der Maaten\|first=L.J.P.\|author2=Hinton, G.E. \|title=Visualizing High-Dimensional Data Using t-SNE\|journal=Journal of Machine Learning Research \|volume=9\|date=Nov 2008\|pages=2579–2605\|url=http://jmlr.org/papers/volume9/vandermaaten08a/vandermaaten08a.pdf}}</ref> It is a [[nonlinear dimensionality reduction]] technique that is particularly well suited for embedding high-dimensional data into a space of two or three dimensions, which can then be visualized in a scatter plot. Specifically, it models each high-dimensional object by a two- or three-dimensional point in such a way that similar objects are modeled by nearby points and dissimilar objects are modeled by distant points. The t-SNE ~~algorithms~~algorithm comprises two main stages. First, t-SNE constructs a [[probability distribution]] over pairs of high-dimensional objects in such a way that similar objects have a high probability of being picked, whilst dissimilar points have an [[infinitesimal]] probability of being picked. Second, t-SNE defines a similar probability distribution over the points in the low-dimensional map, and it minimizes the [[Kullback–Leibler divergence]] between the two distributions with respect to the locations of the points in the map. Note that whilst the original algorithm uses the [[Euclidean distance]] between objects as the base of its similarity metric, this should be changed as appropriate. t-SNE has been used in a wide range of applications, including [[computer security]] research,<ref>{{cite journal\|last=Gashi\|first=I.\|author2=Stankovic, V. \|author3=Leita, C. \|author4=Thonnard, O. \|title=An Experimental Study of Diversity with Off-the-shelf AntiVirus Engines\|journal=Proceedings of the IEEE International Symposium on Network Computing and Applications\|year=2009\|pages=4–11}}</ref> [[music analysis]],<ref>{{cite journal\|last=Hamel\|first=P.\|author2=Eck, D. \|title=Learning Features from Music Audio with Deep Belief Networks\|journal=Proceedings of the International Society for Music Information Retrieval Conference\|year=2010\|pages=339–344}}</ref> [[cancer research]],<ref>{{cite journal\|last=Jamieson\|first=A.R.\|author2=Giger, M.L. \|author3=Drukker, K. \|author4=Lui, H. \|author5=Yuan, Y. \|author6=Bhooshan, N. \|title=Exploring Nonlinear Feature Space Dimension Reduction and Data Representation in Breast CADx with Laplacian Eigenmaps and t-SNE\|journal=Medical Physics \|issue=1\|year=2010\|pages=339–351\|doi=10.1118/1.3267037\|volume=37}}</ref> and [[bioinformatics]].<ref>{{cite journal\|last=Wallach\|first=I.\|author2=Liliean, R. \|title=The Protein-Small-Molecule Database, A Non-Redundant Structural Resource for the Analysis of Protein-Ligand Binding\|journal=Bioinformatics \|year=2009\|pages=615–620\|doi=10.1093/bioinformatics/btp035\|volume=25\|issue=5}}</ref>

T-distributed stochastic neighbor embedding: Difference between revisions