Search

Your search keyword '"Ellenberger, Benjamin"' showing total 14 results
Start Over Author "Ellenberger, Benjamin"
14 results on '"Ellenberger, Benjamin"'

1. Backpropagation through space, time, and the brain

Author

Ellenberger, Benjamin, Haider, Paul, Jordan, Jakob, Max, Kevin, Jaras, Ismael, Kriener, Laura, Benitez, Federico, and Petrovici, Mihai A.

Subjects
Quantitative Biology - Neurons and Cognition, Computer Science - Artificial Intelligence, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Electrical Engineering and Systems Science - Signal Processing
Abstract

How physical networks of neurons, bound by spatio-temporal locality constraints, can perform efficient credit assignment, remains, to a large extent, an open question. In machine learning, the answer is almost universally given by the error backpropagation algorithm, through both space and time. However, this algorithm is well-known to rely on biologically implausible assumptions, in particular with respect to spatio-temporal (non-)locality. Alternative forward-propagation models such as real-time recurrent learning only partially solve the locality problem, but only at the cost of scaling, due to prohibitive storage requirements. We introduce Generalized Latent Equilibrium (GLE), a computational framework for fully local spatio-temporal credit assignment in physical, dynamical networks of neurons. We start by defining an energy based on neuron-local mismatches, from which we derive both neuronal dynamics via stationarity and parameter dynamics via gradient descent. The resulting dynamics can be interpreted as a real-time, biologically plausible approximation of backpropagation through space and time in deep cortical networks with continuous-time neuronal dynamics and continuously active, local synaptic plasticity. In particular, GLE exploits the morphology of dendritic trees to enable more complex information storage and processing in single neurons, as well as the ability of biological neurons to phase-shift their output rate with respect to their membrane potential, which is essential in both directions of information propagation. For the forward computation, it enables the mapping of time-continuous inputs to neuronal space, effectively performing a spatio-temporal convolution. For the backward computation, it permits the temporal inversion of feedback signals, which consequently approximate the adjoint variables necessary for useful parameter updates., Comment: First authorship shared by Benjamin Ellenberger and Paul Haider

Published
2024

2. Latent Equilibrium: A unified learning theory for arbitrarily fast computation with arbitrarily slow neurons

Author

Haider, Paul, Ellenberger, Benjamin, Kriener, Laura, Jordan, Jakob, Senn, Walter, and Petrovici, Mihai A.

Subjects
Quantitative Biology - Neurons and Cognition, Computer Science - Artificial Intelligence, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Electrical Engineering and Systems Science - Signal Processing, F.1.1, I.2.6, I.5.1, B.8.1
Abstract

The response time of physical computational elements is finite, and neurons are no exception. In hierarchical models of cortical networks each layer thus introduces a response lag. This inherent property of physical dynamical systems results in delayed processing of stimuli and causes a timing mismatch between network output and instructive signals, thus afflicting not only inference, but also learning. We introduce Latent Equilibrium, a new framework for inference and learning in networks of slow components which avoids these issues by harnessing the ability of biological neurons to phase-advance their output with respect to their membrane potential. This principle enables quasi-instantaneous inference independent of network depth and avoids the need for phased plasticity or computationally expensive network relaxation phases. We jointly derive disentangled neuron and synapse dynamics from a prospective energy function that depends on a network's generalized position and momentum. The resulting model can be interpreted as a biologically plausible approximation of error backpropagation in deep cortical networks with continuous-time, leaky neuronal dynamics and continuously active, local plasticity. We demonstrate successful learning of standard benchmark datasets, achieving competitive performance using both fully-connected and convolutional architectures, and show how our principle can be applied to detailed models of cortical microcircuitry. Furthermore, we study the robustness of our model to spatio-temporal substrate imperfections to demonstrate its feasibility for physical realization, be it in vivo or in silico., Comment: Accepted for publication in Advances in Neural Information Processing Systems 34 (NeurIPS 2021); 13 pages, 4 figures; 10 pages of supplementary material, 1 supplementary figure

Published
2021

6. Feasibility, efficacy, and functional relevance of automated auditory closed‐loop suppression of slow‐wave sleep in humans

Author

Fehér, Kristoffer D., primary, Omlin, Ximena, additional, Tarokh, Leila, additional, Schneider, Carlotta L., additional, Morishima, Yosuke, additional, Züst, Marc A., additional, Wunderlin, Marina, additional, Koenig, Thomas, additional, Hertenstein, Elisabeth, additional, Ellenberger, Benjamin, additional, Ruch, Simon, additional, Schmidig, Flavio, additional, Mikutta, Christian, additional, Trinca, Ersilia, additional, Senn, Walter, additional, Feige, Bernd, additional, Klöppel, Stefan, additional, and Nissen, Christoph, additional

Published
2023
Full Text
View/download PDF

10. Extending outbreak investigation with machine learning and graph theory: Benefits of new tools with application to a nosocomial outbreak of a multidrug-resistant organism

Author

Atkinson, Andrew, Ellenberger, Benjamin, Piezzi, Vanja, Kaspar, Tanja, Salazar-Vizcaya, Luisa, Endrich, Olga, Leichtle, Alexander B., and Marschall, Jonas

Abstract

AbstractObjective:From January 1, 2018, until July 31, 2020, our hospital network experienced an outbreak of vancomycin-resistant enterococci (VRE). The goal of our study was to improve existing processes by applying machine-learning and graph-theoretical methods to a nosocomial outbreak investigation.Methods:We assembled medical records generated during the first 2 years of the outbreak period (January 2018 through December 2019). We identified risk factors for VRE colonization using standard statistical methods, and we extended these with a decision-tree machine-learning approach. We then elicited possible transmission pathways by detecting commonalities between VRE cases using a graph theoretical network analysis approach.Results:We compared 560 VRE patients to 86,684 controls. Logistic models revealed predictors of VRE colonization as age (aOR, 1.4 (per 10 years), with 95% confidence interval [CI], 1.3–1.5; P< .001), ICU admission during stay (aOR, 1.5; 95% CI, 1.2–1.9; P< .001), Charlson comorbidity score (aOR, 1.1; 95% CI, 1.1–1.2; P< .001), the number of different prescribed antibiotics (aOR, 1.6; 95% CI, 1.5–1.7; P< .001), and the number of rooms the patient stayed in during their hospitalization(s) (aOR, 1.1; 95% CI, 1.1–1.2; P< .001). The decision-tree machine-learning method confirmed these findings. Graph network analysis established 3 main pathways by which the VRE cases were connected: healthcare personnel, medical devices, and patient rooms.Conclusions:We identified risk factors for being a VRE carrier, along with 3 important links with VRE (healthcare personnel, medical devices, patient rooms). Data science is likely to provide a better understanding of outbreaks, but interpretations require data maturity, and potential confounding factors must be considered.

Published
2023
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results