Galaxy morphological classification in deep-wide surveys via unsupervised machine learning

Martin, Garreth; Kaviraj, Sugata; Hocking, Alex; Read, Shaun C.; Geach, J. E.

doi:10.1093/mnras/stz3006

Cited by 79 publications

(61 citation statements)

References 109 publications

(134 reference statements)

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“…A growing literature has emerged in recent years, reporting the results of the application of unsupervised techniques to various astrophysical contexts (see Baron 2019 andBall &Brunner 2010 for comprehensive reviews). Clustering has been used, for example, to partition galaxies on the basis of their pixel data (Hocking et al 2017(Hocking et al , 2018Martin et al 2020), their spectra (Sánchez Almeida et al 2010;de Souza et al 2017), their SEDs (Siudek et al 2018b,a), and their derived astrophysical features (Barchi et al 2016;Turner et al 2019). Dimensionality reduction, which can extract important or discriminative information from large ensembles of input features, has been used, for example, to produce simplified projections of galaxy samples based on their multi-wavelength photometry (Steinhardt et al 2020) and their estimated SEDs (Davidzon et al 2019;Hemmati et al 2019), and to classify their spectra (Yip et al 2004;Marchetti et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Synergies between low- and intermediate-redshift galaxy populations revealed with unsupervised machine learning

Turner

Siudek

Salim

et al. 2021

Monthly Notices of the Royal Astronomical Society

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The colour bimodality of galaxies provides an empirical basis for theories of galaxy evolution. However, the balance of processes that begets this bimodality has not yet been constrained. A more detailed view of the galaxy population is needed, which we achieve in this paper by using unsupervised machine learning to combine multi-dimensional data at two different epochs. We aim to understand the cosmic evolution of galaxy subpopulations by uncovering substructures within the colour bimodality. We choose a clustering algorithm that models clusters using only the most discriminative data available, and apply it to two galaxy samples: one from the second edition of the GALEX-SDSS-WISE Legacy Catalogue (GSWLC-2; z ∼ 0.06), and the other from the VIMOS Public Extragalactic Redshift Survey (VIPERS; z ∼ 0.65). We cluster within a nine-dimensional feature space defined purely by rest-frame ultraviolet-through-near-infrared colours. Both samples are similarly partitioned into seven clusters, breaking down into four of mostly star-forming galaxies (including the vast majority of green valley galaxies) and three of mostly passive galaxies. The separation between these two families of clusters suggests differences in the evolution of their galaxies, and that these differences are strongly expressed in their colours alone. The samples are closely related, with star-forming/green-valley clusters at both epochs forming morphological sequences, capturing the gradual internally-driven growth of galaxy bulges. At high stellar masses, this growth is linked with quenching. However, it is only in our low-redshift sample that additional, environmental processes appear to be involved in the evolution of low-mass passive galaxies.

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Section: Introductionmentioning

confidence: 99%

Synergies between low- and intermediate-redshift galaxy populations revealed with unsupervised machine learning

Turner

Siudek

Salim

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…There is some precedence for this in astronomy. For example, Martin et al (2020) follow Hocking et al (2018) in using growing neural gas and hierarchical clustering directly on pixel data to identify structurally distinct clusters. Almeida et al (2010) and Almeida & Prieto (2013) utilise k-means to classify spectra from SDSS into fewer base types.…”

Section: Unsupervised Clusteringmentioning

confidence: 99%

“…Lahav et al 1995), there has been a recent explosion of studies that apply such techniques to the exploration of galaxy morphology, particularly in large survey datasets (e.g. Huertas-Company et al 2015;Ostrovski et al 2017;Schawinski et al 2017;Hocking et al 2018;Goulding et al 2018;Cheng et al 2019;Martin et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Eigengalaxies: describing galaxy morphology using principal components in image space

Uzeirbegovic

Kaviraj

2020

Monthly Notices of the Royal Astronomical Society

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We demonstrate how galaxy morphologies can be represented by weighted sums of ‘eigengalaxies’ and how eigengalaxies can be used in a probabilistic framework to enable principled and simplified approaches in a variety of applications. Eigengalaxies can be derived from a Principal Component Analysis (PCA) of sets of single- or multi-band images. They encode the image space equivalent of basis vectors that can be combined to describe the structural properties of large samples of galaxies in a massively reduced manner. As an illustration, we show how a sample of 10,243 galaxies in the Hubble Space Telescope CANDELS survey can be represented by just 12 eigengalaxies. We show in some detail how this image space may be derived and tested. We also describe a probabilistic extension to PCA (PPCA) which enables the eigengalaxy framework to assign probabilities to galaxies. We present four practical applications of the probabilistic eigengalaxy framework that are particularly relevant for the next generation of large imaging surveys: we (i) show how low likelihood galaxies make for natural candidates for outlier detection (ii) demonstrate how missing data can be predicted (iii) show how a similarity search can be performed on exemplars (iv) demonstrate how unsupervised clustering of objects can be implemented.

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“…To solve this problem, the clustering algorithms may be a reasonable solution, which has been used to process images in some applications. Reference [17] used the k-means algorithm to classify galaxies into morphological clusters by their visual similarity. In [18], the G-means algorithm was used for intrusion detection.…”

Section: Related Workmentioning

confidence: 99%

“…The mean squared distance is the average of the squared distances of samples to their closest cluster center. Silhouette scores [17] range from −1 to 1: a high silhouette score indicates that the object is well matched to its own cluster and distinct from neighboring clusters. The Calinski-Harabasz score of a clustering is in [0, +∞] and should be maximized [28].…”

Section: Performance With Different Numbers Of Clustersmentioning

confidence: 99%

Color Classification of Wooden Boards Based on Machine Vision and the Clustering Algorithm

et al. 2020

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Color classification of wooden boards is helpful to improve the appearance of wooden furniture that is spliced from multiple wooden boards. Due to the similarity of colors among wooden boards, manual color classification is inaccurate and unstable. Thus, supervised learning algorithms can hardly be used in this scenario. Moreover, wooden boards are long, and their images have a high resolution, which may lead to the growth of computational complexity. To overcome these challenges, in this paper, we propose a new mechanism for color classification of wooden boards based on machine vision. The image of the wooden board is preprocessed to subtract irrelevant colors, and the feature vector is extracted based on 3D color histogram to reduce the computational complexity. In the offline clustering, the feature vector sets are partitioned into different clusters through the K-means algorithm. Then, the clustering result can be used in the online classification to classify the new wood image. Furthermore, to process the abnormal images of wooden boards, we propose an improved algorithm with centroid improvement and image filtering. The experimental results verify the effectiveness of the proposed mechanism.

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Galaxy morphological classification in deep-wide surveys via unsupervised machine learning

Cited by 79 publications

References 109 publications

Synergies between low- and intermediate-redshift galaxy populations revealed with unsupervised machine learning

Synergies between low- and intermediate-redshift galaxy populations revealed with unsupervised machine learning

Eigengalaxies: describing galaxy morphology using principal components in image space

Color Classification of Wooden Boards Based on Machine Vision and the Clustering Algorithm

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