Timezone: »
A new approach to analyzing and training recurrent neural networks (RNNs) has emerged over the last few years. The central idea is to regard a sparsely connected recurrent circuit as a nonlinear, excitable medium, which is driven by input signals (possibly in conjunction with feedbacks from readouts). This recurrent circuit is --like a kernel in Support Vector Machine applications-- not adapted during learning. Rather, very simple (typically linear) readouts are trained to extract desired output signals. Despite its simplicity, it was recently shown that such simple networks have (in combination with feedback from readouts) universal computational power, both for digital and for analog computation. There are currently two main flavours of such networks. Echo state networks were developed from a mathematical and engineering background and are composed of simple sigmoid units, updated in discrete time. Liquid state machines were conceived from a mathematical and computational neuroscience perspective and usually are made of biologically more plausible, spiking neurons with a continuous-time dynamics. Generic cortical microcircuits are seen from this perspective as explicit implementations of kernels (in the sense of SVMs), that therefore are not required to carry out specific nonlinear computations (as long as their individual computations and representations are sufficiently diverse). Obviously this hypothesis provides a new perspective of neural coding, experimental design in neurobiology, and data analysis. This workshop will cover theoretical aspects of this approach, applications to concrete engineering tasks, as well as results of first neurobiological experiments that have tested predictions of this new model for cortical computation.
Author Information
Herbert Jaeger (International University Bremen)
Wolfgang Maass (Graz University of Technology - IGI)
Jose C Principe (University of Florida at Gainesville)
More from the Same Authors
-
2022 : Directed Information for Point Process Systems »
Shailaja Akella · Andre Bastos · Jose C Principe -
2019 : Poster Session »
Pravish Sainath · Mohamed Akrout · Charles Delahunt · Nathan Kutz · Guangyu Robert Yang · Joseph Marino · L F Abbott · Nicolas Vecoven · Damien Ernst · andrew warrington · Michael Kagan · Kyunghyun Cho · Kameron Harris · Leopold Grinberg · John J. Hopfield · Dmitry Krotov · Taliah Muhammad · Erick Cobos · Edgar Walker · Jacob Reimer · Andreas Tolias · Alexander Ecker · Janaki Sheth · Yu Zhang · Maciej Wołczyk · Jacek Tabor · Szymon Maszke · Roman Pogodin · Dane Corneil · Wulfram Gerstner · Baihan Lin · Guillermo Cecchi · Jenna M Reinen · Irina Rish · Guillaume Bellec · Darjan Salaj · Anand Subramoney · Wolfgang Maass · Yueqi Wang · Ari Pakman · Jin Hyung Lee · Liam Paninski · Bryan Tripp · Colin Graber · Alex Schwing · Luke Prince · Gabriel Ocker · Michael Buice · Benjamin Lansdell · Konrad Kording · Jack Lindsey · Terrence Sejnowski · Matthew Farrell · Eric Shea-Brown · Nicolas Farrugia · Victor Nepveu · Jiwoong Im · Kristin Branson · Brian Hu · Ramakrishnan Iyer · Stefan Mihalas · Sneha Aenugu · Hananel Hazan · Sihui Dai · Tan Nguyen · Doris Tsao · Richard Baraniuk · Anima Anandkumar · Hidenori Tanaka · Aran Nayebi · Stephen Baccus · Surya Ganguli · Dean Pospisil · Eilif Muller · Jeffrey S Cheng · Gaël Varoquaux · Kamalaker Dadi · Dimitrios C Gklezakos · Rajesh PN Rao · Anand Louis · Christos Papadimitriou · Santosh Vempala · Naganand Yadati · Daniel Zdeblick · Daniela M Witten · Nicholas Roberts · Vinay Prabhu · Pierre Bellec · Poornima Ramesh · Jakob H Macke · Santiago Cadena · Guillaume Bellec · Franz Scherr · Owen Marschall · Robert Kim · Hannes Rapp · Marcio Fonseca · Oliver Armitage · Jiwoong Im · Thomas Hardcastle · Abhishek Sharma · Wyeth Bair · Adrian Valente · Shane Shang · Merav Stern · Rutuja Patil · Peter Wang · Sruthi Gorantla · Peter Stratton · Tristan Edwards · Jialin Lu · Martin Ester · Yurii Vlasov · Siavash Golkar -
2019 : Contributed Talk #2: Slow processes of neurons enable a biologically plausible approximation to policy gradient »
Wolfgang Maass -
2019 : Coffee Break & Poster Session »
Samia Mohinta · Andrea Agostinelli · Alexandra Moringen · Jee Hang Lee · Yat Long Lo · Wolfgang Maass · Blue Sheffer · Colin Bredenberg · Benjamin Eysenbach · Liyu Xia · Efstratios Markou · Jan Lichtenberg · Pierre Richemond · Tony Zhang · JB Lanier · Baihan Lin · William Fedus · Glen Berseth · Marta Sarrico · Matthew Crosby · Stephen McAleer · Sina Ghiassian · Franz Scherr · Guillaume Bellec · Darjan Salaj · Arinbjörn Kolbeinsson · Matthew Rosenberg · Jaehoon Shin · Sang Wan Lee · Guillermo Cecchi · Irina Rish · Elias Hajek -
2018 Poster: Smoothed Analysis of Discrete Tensor Decomposition and Assemblies of Neurons »
Nima Anari · Constantinos Daskalakis · Wolfgang Maass · Christos Papadimitriou · Amin Saberi · Santosh Vempala -
2018 Poster: Long short-term memory and Learning-to-learn in networks of spiking neurons »
Guillaume Bellec · Darjan Salaj · Anand Subramoney · Robert Legenstein · Wolfgang Maass -
2016 : Reward-based self-configuration of networks of spiking neurons »
Wolfgang Maass -
2015 Poster: Synaptic Sampling: A Bayesian Approach to Neural Network Plasticity and Rewiring »
David Kappel · Stefan Habenschuss · Robert Legenstein · Wolfgang Maass -
2010 Poster: A novel family of non-parametric cumulative based divergences for point processes »
Sohan Seth · Il Memming Park · Austin J Brockmeier · Mulugeta Semework · John S Choi · Joseph T Francis · Jose C Principe -
2009 Poster: Functional network reorganization in motor cortex can be explained by reward-modulated Hebbian learning »
Robert Legenstein · Steven Chase · Andrew B Schwartz · Wolfgang Maass -
2009 Oral: Functional Network Reorganization In Motor Cortex Can Be Explained by Reward-Modulated Hebbian Learning »
Robert Legenstein · Steven Chase · Andrew B Schwartz · Wolfgang Maass -
2009 Poster: STDP enables spiking neurons to detect hidden causes of their inputs »
Bernhard Nessler · Michael Pfeiffer · Wolfgang Maass -
2009 Spotlight: STDP enables spiking neurons to detect hidden causes of their inputs »
Bernhard Nessler · Michael Pfeiffer · Wolfgang Maass -
2009 Poster: Replacing supervised classification learning by Slow Feature Analysis in spiking neural networks »
Stefan Klampfl · Wolfgang Maass -
2009 Spotlight: Replacing supervised classification learning by Slow Feature Analysis in spiking neural networks »
Stefan Klampfl · Wolfgang Maass -
2008 Poster: Hebbian Learning of Bayes Optimal Decisions »
Bernhard Nessler · Michael Pfeiffer · Wolfgang Maass -
2007 Spotlight: Theoretical Analysis of Learning with Reward-Modulated Spike-Timing-Dependent Plasticity »
Robert Legenstein · Dejan Pecevski · Wolfgang Maass -
2007 Poster: Theoretical Analysis of Learning with Reward-Modulated Spike-Timing-Dependent Plasticity »
Robert Legenstein · Dejan Pecevski · Wolfgang Maass -
2007 Poster: Simplified Rules and Theoretical Analysis for Information Bottleneck Optimization and PCA with Spiking Neurons »
Lars Buesing · Wolfgang Maass -
2006 Poster: Temporal dynamics of information content carried by neurons in the primary visual cortex »
Danko Nikolic · Stefan Haeusler · Wolf Singer · Wolfgang Maass -
2006 Poster: Information Bottleneck Optimization and Independent Component Extraction with Spiking Neurons »
Stefan Klampfl · Robert Legenstein · Wolfgang Maass