Comparing noisy neural population dynamics using optimal transport distances
- URL: http://arxiv.org/abs/2412.14421v1
- Date: Thu, 19 Dec 2024 00:20:24 GMT
- Title: Comparing noisy neural population dynamics using optimal transport distances
- Authors: Amin Nejatbakhsh, Victor Geadah, Alex H. Williams, David Lipshutz,
- Abstract summary: We show that existing metrics can fail to capture key differences between neural systems with noisy dynamic responses.
We then propose a metric for comparing the geometry of noisy neural trajectories.
We use the metric to compare models of neural responses in different regions of the motor system and to compare the dynamics of latent diffusion models for text-to-image synthesis.
- Score: 6.459101467083055
- License:
- Abstract: Biological and artificial neural systems form high-dimensional neural representations that underpin their computational capabilities. Methods for quantifying geometric similarity in neural representations have become a popular tool for identifying computational principles that are potentially shared across neural systems. These methods generally assume that neural responses are deterministic and static. However, responses of biological systems, and some artificial systems, are noisy and dynamically unfold over time. Furthermore, these characteristics can have substantial influence on a system's computational capabilities. Here, we demonstrate that existing metrics can fail to capture key differences between neural systems with noisy dynamic responses. We then propose a metric for comparing the geometry of noisy neural trajectories, which can be derived as an optimal transport distance between Gaussian processes. We use the metric to compare models of neural responses in different regions of the motor system and to compare the dynamics of latent diffusion models for text-to-image synthesis.
Related papers
- Generative Modeling of Neural Dynamics via Latent Stochastic Differential Equations [1.5467259918426441]
We propose a framework for developing computational models of biological neural systems.
We employ a system of coupled differential equations with differentiable drift and diffusion functions.
We show that these hybrid models achieve competitive performance in predicting stimulus-evoked neural and behavioral responses.
arXiv Detail & Related papers (2024-12-01T09:36:03Z) - Expressivity of Neural Networks with Random Weights and Learned Biases [44.02417750529102]
Recent work has pushed the bounds of universal approximation by showing that arbitrary functions can similarly be learned by tuning smaller subsets of parameters.
We provide theoretical and numerical evidence demonstrating that feedforward neural networks with fixed random weights can be trained to perform multiple tasks by learning biases only.
Our results are relevant to neuroscience, where they demonstrate the potential for behaviourally relevant changes in dynamics without modifying synaptic weights.
arXiv Detail & Related papers (2024-07-01T04:25:49Z) - Graph Neural Networks for Learning Equivariant Representations of Neural Networks [55.04145324152541]
We propose to represent neural networks as computational graphs of parameters.
Our approach enables a single model to encode neural computational graphs with diverse architectures.
We showcase the effectiveness of our method on a wide range of tasks, including classification and editing of implicit neural representations.
arXiv Detail & Related papers (2024-03-18T18:01:01Z) - Learning with Chemical versus Electrical Synapses -- Does it Make a
Difference? [61.85704286298537]
Bio-inspired neural networks have the potential to advance our understanding of neural computation and improve the state-of-the-art of AI systems.
We conduct experiments with autonomous lane-keeping through a photorealistic autonomous driving simulator to evaluate their performance under diverse conditions.
arXiv Detail & Related papers (2023-11-21T13:07:20Z) - Inferring Inference [7.11780383076327]
We develop a framework for inferring canonical distributed computations from large-scale neural activity patterns.
We simulate recordings for a model brain that implicitly implements an approximate inference algorithm on a probabilistic graphical model.
Overall, this framework provides a new tool for discovering interpretable structure in neural recordings.
arXiv Detail & Related papers (2023-10-04T22:12:11Z) - Interpretable statistical representations of neural population dynamics and geometry [4.459704414303749]
We introduce a representation learning method, MARBLE, that decomposes on-manifold dynamics into local flow fields and maps them into a common latent space.
In simulated non-linear dynamical systems, recurrent neural networks, and experimental single-neuron recordings from primates and rodents, we discover emergent low-dimensional latent representations.
These representations are consistent across neural networks and animals, enabling the robust comparison of cognitive computations.
arXiv Detail & Related papers (2023-04-06T21:11:04Z) - Data-driven emergence of convolutional structure in neural networks [83.4920717252233]
We show how fully-connected neural networks solving a discrimination task can learn a convolutional structure directly from their inputs.
By carefully designing data models, we show that the emergence of this pattern is triggered by the non-Gaussian, higher-order local structure of the inputs.
arXiv Detail & Related papers (2022-02-01T17:11:13Z) - POPPINS : A Population-Based Digital Spiking Neuromorphic Processor with
Integer Quadratic Integrate-and-Fire Neurons [50.591267188664666]
We propose a population-based digital spiking neuromorphic processor in 180nm process technology with two hierarchy populations.
The proposed approach enables the developments of biomimetic neuromorphic system and various low-power, and low-latency inference processing applications.
arXiv Detail & Related papers (2022-01-19T09:26:34Z) - Drop, Swap, and Generate: A Self-Supervised Approach for Generating
Neural Activity [33.06823702945747]
We introduce a novel unsupervised approach for learning disentangled representations of neural activity called Swap-VAE.
Our approach combines a generative modeling framework with an instance-specific alignment loss.
We show that it is possible to build representations that disentangle neural datasets along relevant latent dimensions linked to behavior.
arXiv Detail & Related papers (2021-11-03T16:39:43Z) - The Neural Coding Framework for Learning Generative Models [91.0357317238509]
We propose a novel neural generative model inspired by the theory of predictive processing in the brain.
In a similar way, artificial neurons in our generative model predict what neighboring neurons will do, and adjust their parameters based on how well the predictions matched reality.
arXiv Detail & Related papers (2020-12-07T01:20:38Z) - Provably Efficient Neural Estimation of Structural Equation Model: An
Adversarial Approach [144.21892195917758]
We study estimation in a class of generalized Structural equation models (SEMs)
We formulate the linear operator equation as a min-max game, where both players are parameterized by neural networks (NNs), and learn the parameters of these neural networks using a gradient descent.
For the first time we provide a tractable estimation procedure for SEMs based on NNs with provable convergence and without the need for sample splitting.
arXiv Detail & Related papers (2020-07-02T17:55:47Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.