Hyperbolic Secant representation of the logistic function: Application to probabilistic Multiple Instance Learning for CT intracranial hemorrhage detection
Francisco M. Castro-Macías , Pablo Morales-Álvarez , Yunan Wu , Rafael Molina , Aggelos K. Katsaggelos
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引用次数: 0
Abstract
Multiple Instance Learning (MIL) is a weakly supervised paradigm that has been successfully applied to many different scientific areas and is particularly well suited to medical imaging. Probabilistic MIL methods, and more specifically Gaussian Processes (GPs), have achieved excellent results due to their high expressiveness and uncertainty quantification capabilities. One of the most successful GP-based MIL methods, VGPMIL, resorts to a variational bound to handle the intractability of the logistic function. Here, we formulate VGPMIL using Pólya-Gamma random variables. This approach yields the same variational posterior approximations as the original VGPMIL, which is a consequence of the two representations that the Hyperbolic Secant distribution admits. This leads us to propose a general GP-based MIL method that takes different forms by simply leveraging distributions other than the Hyperbolic Secant one. Using the Gamma distribution we arrive at a new approach that obtains competitive or superior predictive performance and efficiency. This is validated in a comprehensive experimental study including one synthetic MIL dataset, two well-known MIL benchmarks, and a real-world medical problem. We expect that this work provides useful ideas beyond MIL that can foster further research in the field.
多实例学习(MIL)是一种弱监督范式,已成功应用于许多不同的科学领域,尤其适用于医学成像。概率 MIL 方法,更具体地说是高斯过程 (GP),因其高度的表现力和不确定性量化能力而取得了卓越的成果。最成功的基于 GP 的 MIL 方法之一 VGPMIL 采用变分约束来处理对数函数的难解性。在此,我们使用 Pólya-Gamma 随机变量来制定 VGPMIL。这种方法能得到与原始 VGPMIL 相同的变分后验近似值,这是双曲 Secant 分布允许的两种表示方法的结果。因此,我们提出了一种基于 GP 的通用 MIL 方法,这种方法只需利用双曲正割分布以外的其他分布,就能获得不同的形式。利用伽马分布,我们得出了一种新方法,它能获得具有竞争力或更优越的预测性能和效率。这在一项综合实验研究中得到了验证,包括一个合成 MIL 数据集、两个著名的 MIL 基准和一个现实世界的医疗问题。我们希望这项工作能提供超越 MIL 的有用想法,从而促进该领域的进一步研究。
期刊介绍:
The Journal of Artificial Intelligence (AIJ) welcomes papers covering a broad spectrum of AI topics, including cognition, automated reasoning, computer vision, machine learning, and more. Papers should demonstrate advancements in AI and propose innovative approaches to AI problems. Additionally, the journal accepts papers describing AI applications, focusing on how new methods enhance performance rather than reiterating conventional approaches. In addition to regular papers, AIJ also accepts Research Notes, Research Field Reviews, Position Papers, Book Reviews, and summary papers on AI challenges and competitions.