Endless Forams: &gt;34,000 Modern Planktonic Foraminiferal Images for Taxonomic Training and Automated Species Recognition Using Convolutional Neural Networks

Hsiang, Allison Y.; Brombacher, Anieke; Rillo, Marina C.; Mleneck‐Vautravers, Maryline J.; Conn, Stephen; Lordsmith, Sian; Jentzen, Anna; Henehan, Michael J.; Metcalfe, Brett; Fenton, Isabel S.; Wade, Bridget S.; Fox, L.R.; Meilland, Julie; Davis, Catherine V.; Baranowski, Ulrike; Groeneveld, Jeroen; Edgar, Kirsty M.; Movellan, Aurore; Aze, Tracy; Dowsett, Harry J.; Miller, C. Giles; Rios, Nelson; Hull, Pincelli M.

doi:10.1029/2019pa003612

Cited by 85 publications

(117 citation statements)

References 53 publications

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“…morphology) (Krizhevsky et al, 2012) and is on par with human performance (Russakovsky et al, 2015). Current popular networks include VGG (Simonyan and Zisserman, 2015), Inception (Szegedy et al, 2015(Szegedy et al, , 2016, ResNet (He et al, 2016a, b;Zagoruyko and Komodakis, 2016;Xie et al, 2017) and DenseNet (Huang et al, 2017).…”

Section: Deep Convolutional Neural Network (Cnns)mentioning

confidence: 99%

“…In the foraminifera domain, one current approach is using transfer learning with pre-trained ResNet and VGG networks to classify foraminifera images coloured according to 3D cues from 16-way lighting (Zhong et al, 2018;Mitra et al, 2019). Hsiang et al (2019) constructed a large planktonic foraminifera image set, Endless Forams, consisting of over 27 000 images classified into 35 species classed by multiple expert taxonomists. They then applied transfer learning using the VGG network to compare CNN-based classification of this dataset with human performance.…”

Section: Deep Convolutional Neural Network (Cnns)mentioning

confidence: 99%

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Automated analysis of foraminifera fossil records by image classification using a convolutional neural network

Marchant

Tetard

Pratiwi

et al. 2020

J. Micropalaeontol.

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Abstract. Manual identification of foraminiferal morphospecies or morphotypes under stereo microscopes is time consuming for micropalaeontologists and not possible for nonspecialists. Therefore, a long-term goal has been to automate this process to improve its efficiency and repeatability. Recent advances in computation hardware have seen deep convolutional neural networks emerge as the state-of-the-art technique for image-based automated classification. Here, we describe a method for classifying large foraminifera image sets using convolutional neural networks. Construction of the classifier is demonstrated on the publicly available Endless Forams image set with a best accuracy of approximately 90 %. A complete automatic analysis is performed for benthic species dated to the last deglacial period for a sediment core from the north-eastern Pacific and for planktonic species dated from the present until 180 000 years ago in a core from the western Pacific warm pool. The relative abundances from automatic counting based on more than 500 000 images compare favourably with manual counting, showing the same signal dynamics. Our workflow opens the way to automated palaeoceanographic reconstruction based on computer image analysis and is freely available for use.

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Section: Deep Convolutional Neural Network (Cnns)mentioning

confidence: 99%

Section: Deep Convolutional Neural Network (Cnns)mentioning

confidence: 99%

Automated analysis of foraminifera fossil records by image classification using a convolutional neural network

Marchant

Tetard

Pratiwi

et al. 2020

J. Micropalaeontol.

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“…We analysed 10 ml aliquots from the 180-2000 um size fraction, samples were stored in a freezer in ethanol. Detailed accounts of the collection methodology can be found in Pesant et al 2015. Species identifications follow the existing understanding of modern foraminiferal taxonomy [37][38][39] . The primary classification is based on the chamber arrangement, wall structure and principally spinose or non-spinose ornamentation 40,41 .…”

Section: Sample Informationmentioning

confidence: 99%

Quantifying the Effect of Anthropogenic Climate Change on Calcifying Plankton

Fox

Stukins

Hill

et al. 2020

Sci Rep

Self Cite

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Widely regarded as an imminent threat to our oceans, ocean acidification has been documented in all oceanic basins. Projected changes in seawater chemistry will have catastrophic biotic effects due to ocean acidification hindering biogenic carbonate production, which will in turn lead to substantial changes in marine ecosystems. However, previous attempts to quantify the effect of acidification on planktonic calcifying organisms has relied on laboratory based studies with substantial methodological limitations. This has been overcome by comparing historic plankton tows from the seminal HMS Challenger Expedition (1872-1876) with the recent Tara Oceans expedition material (2009-2016). Nano CT-scans of selected equatorial Pacific Ocean planktonic foraminifera, have revealed that all modern specimens had up to 76% thinner shells than their historic counterparts. The "Challenger Revisited" project highlights the potential of historic ocean collections as a tool to investigate ocean acidification since the early Industrial Revolution. Further analyses of such biotic archives will enable researchers to quantify the effects of anthropogenic climate change across the globe.

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“…Automated picking systems that take sieved size fractions, separate them into individual particles, and image each particle may greatly reduce picking times (de Garidel-Thoron et al, 2017;Itaki et al, 2020). With samples that have already been picked and mounted, hundreds or thousands of individual microfossils can be imaged simultaneously in three dimensions and algorithmically parsed into individual images from which basic morphometric traits and features can be automatically extracted and ana-lyzed at the assemblage scale (Beaufort et al, 2014;Elder et al, 2018;Hsiang et al, 2018Hsiang et al, , 2019Kahanamoku et al, 2018).…”

Section: Microfossils and The Brave New Anthropocenementioning

confidence: 99%

“…These efforts build on decades of previous automation work that either extracted coarser (size related) data or was relatively more labor intensive (Bollmann et al, 2005;Knappertsbusch et al, 2009). Given sufficient training data sets, convolutional neural nets can now identify planktonic foraminifera, coccolithophores, and radiolarians with accuracy similar to that of taxonomic specialists (Beaufort and Dollfus, 2004;de Garidel-Thoron et al, 2017;Hsiang et al, 2019;Itaki et al, 2020). Given these ongoing developments, it is becoming possible to envision a near future in which the entire sample processing and data extraction workflow is streamlined and largely automated, with taxonomic experts guiding and overseeing the process but spending the majority of their time analyzing data sets that may be far larger, denser, and more data-rich than is currently feasible.…”

Section: Microfossils and The Brave New Anthropocenementioning

confidence: 99%

Time Machine Biology: Cross-Timescale Integration of Ecology, Evolution, and Oceanography

Yasuhara¹,

Huang²,

Hull³

et al. 2020

Oceanog

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Endless Forams: >34,000 Modern Planktonic Foraminiferal Images for Taxonomic Training and Automated Species Recognition Using Convolutional Neural Networks

Cited by 85 publications

References 53 publications

Automated analysis of foraminifera fossil records by image classification using a convolutional neural network

Automated analysis of foraminifera fossil records by image classification using a convolutional neural network

Quantifying the Effect of Anthropogenic Climate Change on Calcifying Plankton

Time Machine Biology: Cross-Timescale Integration of Ecology, Evolution, and Oceanography

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