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Protein FID: Improved Evaluation of Protein Structure Generative Models

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arxiv 2505.08041 v3 pith:CL6ZWZYQ submitted 2025-05-12 q-bio.BM

Protein FID: Improved Evaluation of Protein Structure Generative Models

classification q-bio.BM
keywords proteinmodelsstructurecurrentgenerativeevaluatingspacethey
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Protein structure generative models have seen a recent surge of interest, but meaningfully evaluating them computationally is an active area of research. While current metrics have driven useful progress, they do not capture how well models sample the design space represented by the training data. We argue for a protein Frechet Inception Distance (FID) metric to supplement current evaluations with a measure of distributional similarity in a semantically meaningful latent space. Our FID behaves desirably under protein structure perturbations and correctly recapitulates similarities between protein samples: it correlates with optimal transport distances and recovers FoldSeek clusters and the CATH hierarchy. Evaluating current protein structure generative models with FID shows that they fall short of modeling the distribution of PDB proteins.

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Cited by 1 Pith paper

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  1. Spectral Diffusion for Protein Dynamics

    q-bio.BM 2026-07 conditional novelty 6.5

    Diffusion over DCT spectral volumes of Cα displacements yields fast, temperature-conditioned protein trajectories with RMSF Pearson r of 0.844 on held-out mdCATH.