Skip to content

lindermanlab/gpslds

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

13 Commits
 
 
 
 
 
 
 
 

Repository files navigation

gpSLDS

This repository contains an implementation of Gaussian Process Switching Linear Dynamical Systems (gpSLDS), described in our paper here. The current recommended citation for this paper is:

Hu, A., Zoltowski, D., Nair, A., Anderson, D., Duncker, L., & Linderman, S. (2024). Modeling Latent Neural Dynamics with Gaussian Process Switching Linear Dynamical Systems. arXiv preprint arXiv:2408.03330.

Repo structure

gpslds/                         Source code for gpSLDS model implementation.
    em.py                           Implements variational EM and contains the main gpSLDS fitting function.
    initialization.py               Functions for initializing model parameters.
    kernels.py                      GP kernel functions, including our smoothly switching linear kernel.
    likelihoods.py                  Gaussian and Poisson observation models.
    quadrature.py                   Quadrature object for approximating kernel expectations.
    simulate_data.py                Helper functions for sampling from the model.
    transition.py                   Defines GP object for model fitting.
    utils.py                        Variety of helper functions.
data/                           Code and data files for main synthetic data example.
    fit_plds.py                     Script for fitting Poisson LDS to initialize Poisson Process observation model parameters.
    generate_synthetic_data.py      Script for generating synthetic data.
    synthetic_data.pkl              Pickle file containing synthetic data.
    synthetic_plds_emissions.pkl    Pickle file containing initial observation model parameters for synthetic data.
synthetic_data_demo.ipynb       Demo notebook fitting gpSLDS to synthetic data.

Data format

To use the gpSLDS on your own data, you will need to ensure that you have:

  • A JAX array ys_binned of shape (n_trials, n_timesteps, n_output_dims). To process data in effectively continuous-time, n_timesteps should represent the number of time bins at a small discretization step relative to the data sampling rate. We assume that data has been zero-padded in the case of varying length trials.
  • A JAX array t_mask of shape (n_trials, n_timesteps). This is 1 for observed timesteps and 0 for unobserved timesteps.
  • A JAX array trial_mask of shape (n_trials, n_timesteps). This is 1 for timesteps in an observed trial and 0 for a zero-padded timestep.
  • (Optional) A JAX array inputs of shape (n_trials, n_timesteps, n_input_dims) consisting of external stimuli.

For an example, please see synthetic_data_demo.ipynb which demonstrates data formatting and model fitting on a synthetic example.

How to run

The current recommended way to run this code is by using a NVIDIA A100 GPU. The fastest way to get this running is by using Google colab with an A100 GPU runtime, which is demonstrated in synthetic_data_demo.ipynb.

Releases

No releases published

Packages

No packages published