Time-lagged autoencoders: Deep learning of slow collective variables for molecular kinetics
About
Inspired by the success of deep learning techniques in the physical and chemical sciences, we apply a modification of an autoencoder type deep neural network to the task of dimension reduction of molecular dynamics data. We can show that our time-lagged autoencoder reliably finds low-dimensional embeddings for high-dimensional feature spaces which capture the slow dynamics of the underlying stochastic processes - beyond the capabilities of linear dimension reduction techniques.
Christoph Wehmeyer, Frank No\'e• 2017
Related benchmarks
| Task | Dataset | Result | Rank | |
|---|---|---|---|---|
| Steered Molecular Dynamics | Chignolin | RMSD1.95 | 4 | |
| Correlation analysis with committor function | Chignolin | Pearson Corr.0.744 | 4 | |
| Dynamic content preservation | BBA DESRES trajectory data | VAMP-11.8902 | 4 | |
| State discrimination analysis | Chignolin Unfolded state, DESRES trajectory | Average MLCV-0.82 | 4 | |
| State discrimination analysis | Trp-cage Folded state, DESRES trajectory | Average MLCV94 | 4 | |
| State discrimination analysis | BBA Unfolded state, DESRES trajectory | Average MLCV-0.9 | 4 | |
| Dynamic content preservation | Chignolin DESRES trajectory data | VAMP-11.9686 | 4 | |
| Dynamic content preservation | Trp-cage DESRES trajectory data | VAMP-11.8787 | 4 | |
| State discrimination analysis | Chignolin Folded state, DESRES trajectory | Average MLCV78 | 4 | |
| State discrimination analysis | Trp-cage Unfolded state DESRES trajectory | Average MLCV-0.95 | 4 |
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