强旋转无序图像的半监督学习:组装纳米粒子库

IF 6.2 Q1 CHEMISTRY, MULTIDISCIPLINARY Digital discovery Pub Date : 2024-05-21 DOI:10.1039/D3DD00196B
Maxim A. Ziatdinov, Muammer Yusuf Yaman, Yongtao Liu, David Ginger and Sergei V. Kalinin
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引用次数: 0

摘要

随着光学显微镜、电子显微镜和扫描探针显微镜的普及,产生了大量的成像数据,这些数据涉及细胞、细菌、花粉、纳米粒子、原子和分子等各种物体。在大多数情况下,实验数据流包含在图像内任意旋转和平移的图像。同时,在许多情况下,少量的标注数据是以先前发表的结果、图像集和目录,甚至理论模型的形式存在的。在此,我们开发了一种方法,可将方向性失调较弱的标注数据子集泛化为方向性(和位置性)失调更强的大型未标注数据集,也就是说,即使在标注和未标注部分之间存在分布偏移的情况下,也能根据少量示例对图像数据进行分类。这种方法基于半监督旋转不变变异自动编码器(ss-rVAE)模型,该模型由编码器-解码器 "块 "和分类器组成,编码器-解码器 "块 "用于学习数据的旋转不变潜表示,分类器用于将数据归类为不同的离散类别。经过训练的 ss-rVAE 的分类器部分继承了旋转(和平移)不变性,可以独立于模型的其他部分进行部署。我们使用已知变异系数的合成数据集说明了 ss-rVAE 的性能。我们还进一步展示了它在纳米粒子实验数据集中的应用,创建了纳米粒子库,并将定义数据中物理变异因子的表征进行了拆分。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Semi-supervised learning of images with strong rotational disorder: assembling nanoparticle libraries†

The proliferation of optical, electron, and scanning probe microscopies gives rise to large volumes of imaging data of objects as diversified as cells, bacteria, and pollen, to nanoparticles and atoms and molecules. In most cases, the experimental data streams contain images having arbitrary rotations and translations within the image. At the same time, for many cases, small amounts of labeled data are available in the form of prior published results, image collections, and catalogs, or even theoretical models. Here we develop an approach that allows generalizing from a small subset of labeled data with a weak orientational disorder to a large unlabeled dataset with a much stronger orientational (and positional) disorder, i.e., it performs a classification of image data given a small number of examples even in the presence of a distribution shift between the labeled and unlabeled parts. This approach is based on the semi-supervised rotationally invariant variational autoencoder (ss-rVAE) model consisting of the encoder–decoder “block” that learns a rotationally-invariant latent representation of data and a classifier for categorizing data into different discrete classes. The classifier part of the trained ss-rVAE inherits the rotational (and translational) invariances and can be deployed independently of the other parts of the model. The performance of the ss-rVAE is illustrated using the synthetic data sets with known factors of variation. We further demonstrate its application for experimental data sets of nanoparticles, creating nanoparticle libraries and disentangling the representations defining the physical factors of variation in the data.

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Back cover ArcaNN: automated enhanced sampling generation of training sets for chemically reactive machine learning interatomic potentials. Sorting polyolefins with near-infrared spectroscopy: identification of optimal data analysis pipelines and machine learning classifiers†‡ High accuracy uncertainty-aware interatomic force modeling with equivariant Bayesian neural networks† Correction: A smile is all you need: predicting limiting activity coefficients from SMILES with natural language processing
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