Yash Barhate , Christopher Boyle , Hossein Salami , Wei-Lee Wu , Nina Taherimakhsousi , Charlie Rabinowitz , Andreas Bommarius , Javier Cardona , Zoltan K. Nagy , Ronald Rousseau , Martha Grover
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However, acquiring high quality data is often time consuming and a major roadblock in developing image analysis models for crystallization processes.</p><p>To address the lack of diverse, high-quality, and publicly available particle image datasets, this paper presents an initiative to create an open-access crystallization-related image database: OpenCrystalData (OCD, at <span>www.kaggle.com/opencrystaldata/datasets</span><svg><path></path></svg>). The datasets consist of images from different crystallization systems with different particle sizes and shapes captured under various conditions. The initial release consists of four different datasets, addressing the estimation of particle size distribution using <em>in-situ</em> images for different categories of particles and detection of anomalous particles for process monitoring purposes. Images are collected using various instruments, followed by case-specific processing steps, such as ground-truth labeling and particle size characterization using offline microscopy. Datasets are released on the online collaborative platform Kaggle, along with specific guidelines for each dataset. These datasets are aimed to serve as a resource for researchers to enable learning, experimentation, development, and evaluation and comparison of different analytical approaches and algorithms. Another goal of this initiative is to encourage researchers to contribute new datasets focusing on various systems and problem statements. 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引用次数: 0
摘要
成像和基于图像的过程分析技术(PAT)彻底改变了结晶过程的设计、开发和操作,通过对粒度、形状和结晶机制的实时表征,让人们对结晶过程有了更深入的了解。相应的 PAT 模型(包括基于机器学习/人工智能(ML/AI)的方法)的性能高度依赖于用于训练或验证的数据质量。然而,获取高质量数据往往非常耗时,是开发结晶过程图像分析模型的主要障碍。为了解决缺乏多样化、高质量和公开可用的粒子图像数据集的问题,本文提出了一项创建开放式结晶相关图像数据库的倡议:OpenCrystalData (OCD, at www.kaggle.com/opencrystaldata/datasets)。这些数据集包括不同结晶系统在不同条件下拍摄的不同颗粒大小和形状的图像。首次发布的数据集包括四个不同的数据集,用于利用不同类别颗粒的原位图像估算颗粒尺寸分布,以及检测异常颗粒以进行过程监控。使用各种仪器收集图像,然后进行特定的处理步骤,例如使用离线显微镜进行地面实况标记和粒度表征。数据集在在线协作平台 Kaggle 上发布,并附有针对每个数据集的具体指导原则。这些数据集旨在为研究人员提供学习、实验、开发、评估和比较不同分析方法和算法的资源。该计划的另一个目标是鼓励研究人员针对各种系统和问题陈述贡献新的数据集。最终,OpenCrystalData 的目的是促进和激励结晶过程中基于成像的 PAT 的新发展,鼓励从耗时的离线分析转向全面的实时过程洞察,从而提高产品质量。
OpenCrystalData: An open-access particle image database to facilitate learning, experimentation, and development of image analysis models for crystallization processes.
Imaging and image-based process analytical technologies (PAT) have revolutionized the design, development, and operation of crystallization processes, providing greater process understanding through the characterization of particle size, shape and crystallization mechanisms in real-time. The performance of corresponding PAT models, including machine learning/artificial intelligence (ML/AI)-based approaches, is highly reliant on the data quality used for training or validation. However, acquiring high quality data is often time consuming and a major roadblock in developing image analysis models for crystallization processes.
To address the lack of diverse, high-quality, and publicly available particle image datasets, this paper presents an initiative to create an open-access crystallization-related image database: OpenCrystalData (OCD, at www.kaggle.com/opencrystaldata/datasets). The datasets consist of images from different crystallization systems with different particle sizes and shapes captured under various conditions. The initial release consists of four different datasets, addressing the estimation of particle size distribution using in-situ images for different categories of particles and detection of anomalous particles for process monitoring purposes. Images are collected using various instruments, followed by case-specific processing steps, such as ground-truth labeling and particle size characterization using offline microscopy. Datasets are released on the online collaborative platform Kaggle, along with specific guidelines for each dataset. These datasets are aimed to serve as a resource for researchers to enable learning, experimentation, development, and evaluation and comparison of different analytical approaches and algorithms. Another goal of this initiative is to encourage researchers to contribute new datasets focusing on various systems and problem statements. Ultimately, OpenCrystalData is intended to facilitate and inspire new developments in imaging-based PAT for crystallization processes, encouraging a shift from time-consuming offline analysis towards comprehensive real-time process insights that drive product quality.