Ensembled Cold-Diffusion Restorations for Unsupervised Anomaly Detection
Marimont, Sergio Naval, Siomos, Vasilis, Baugh, Matthew, Tzelepis, Christos, Kainz, Bernhard, Tarroni, Giacomo
Unsupervised Anomaly Detection (UAD) methods aim to identify anomalies in test samples comparing them with a normative distribution learned from a dataset known to be anomaly-free. Approaches based on generative models offer interpretability by generating anomaly-free versions of test images, but are typically unable to identify subtle anomalies. Alternatively, approaches using feature modelling or self-supervised methods, such as the ones relying on synthetically generated anomalies, do not provide out-of-the-box interpretability. In this work, we present a novel method that combines the strengths of both strategies: a generative cold-diffusion pipeline (i.e., a diffusion-like pipeline which uses corruptions not based on noise) that is trained with the objective of turning synthetically-corrupted images back to their normal, original appearance. To support our pipeline we introduce a novel synthetic anomaly generation procedure, called DAG, and a novel anomaly score which ensembles restorations conditioned with different degrees of abnormality. Our method surpasses the prior state-of-the art for unsupervised anomaly detection in three different Brain MRI datasets.
Jul-9-2024
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- North America > United States
- Louisiana > Orleans Parish > New Orleans (0.04)
- Europe
- United Kingdom > England
- Greater London > London (0.04)
- Germany > Bavaria
- Middle Franconia > Nuremberg (0.04)
- United Kingdom > England
- Africa > Central African Republic
- Ombella-M'Poko > Bimbo (0.04)
- North America > United States
- Genre:
- Research Report (0.84)
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- Health & Medicine
- Therapeutic Area > Neurology (1.00)
- Diagnostic Medicine (0.71)
- Health & Medicine
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