AbstractWe are interested in self-organization and adaptation in intelligent systems that are robustly coupled with the real world. Such systems have a variety of sensory inputs that provide access to the richness, complexity, and noise of real-world signals. Specifically, the systems we design and implement are ab initio simulated spiking neural networks (SSNNs) with cellular resolution and complex network topologies that evolve according to spike-timing dependent plasticity (STDP). We desire to understand how external signals (like speech, vision, etc.) are encoded in the dynamics of such SSNNs. In particular, we are interested in identifying and confirming the extent to which various population-level measurements (or transforms) are info...
The mutual information between stimulus and spike-train response is commonly used to monitor neural ...
The mutual information between stimulus and spike-train response is commonly used to monito...
The coding scheme has been derived elsewhere [1, 2] and is reproduced here for completeness. Unlike ...
AbstractWe are interested in self-organization and adaptation in intelligent systems that are robust...
We are interested in self-organization and adaptation in intelligent systems that are robustly coupl...
We propose a theoretical framework for efficient representation of time-varying sensory information ...
The ventral visual pathway achieves object and face recognition by building transform-invariant repr...
Increasing evidence indicates that biological neurons process information conveyed by the precise ti...
We use unsupervised probabilistic machine learning ideas to try to ex-plain the kinds of learning ob...
Since dynamical systems are an integral part of many scientific domains and can be inherently comput...
How can neural networks learn to represent information optimally? We answer this question by derivin...
In this work we explore encoding strategies learned by statistical models of sensory coding in noisy...
In this work we explore encoding strategies learned by statistical models of sensory coding in noisy...
The ventral visual pathway achieves object and face recognition by building transformation-invariant...
Most existing Spiking Neural Network (SNN) works state that SNNs may utilize temporal information dy...
The mutual information between stimulus and spike-train response is commonly used to monitor neural ...
The mutual information between stimulus and spike-train response is commonly used to monito...
The coding scheme has been derived elsewhere [1, 2] and is reproduced here for completeness. Unlike ...
AbstractWe are interested in self-organization and adaptation in intelligent systems that are robust...
We are interested in self-organization and adaptation in intelligent systems that are robustly coupl...
We propose a theoretical framework for efficient representation of time-varying sensory information ...
The ventral visual pathway achieves object and face recognition by building transform-invariant repr...
Increasing evidence indicates that biological neurons process information conveyed by the precise ti...
We use unsupervised probabilistic machine learning ideas to try to ex-plain the kinds of learning ob...
Since dynamical systems are an integral part of many scientific domains and can be inherently comput...
How can neural networks learn to represent information optimally? We answer this question by derivin...
In this work we explore encoding strategies learned by statistical models of sensory coding in noisy...
In this work we explore encoding strategies learned by statistical models of sensory coding in noisy...
The ventral visual pathway achieves object and face recognition by building transformation-invariant...
Most existing Spiking Neural Network (SNN) works state that SNNs may utilize temporal information dy...
The mutual information between stimulus and spike-train response is commonly used to monitor neural ...
The mutual information between stimulus and spike-train response is commonly used to monito...
The coding scheme has been derived elsewhere [1, 2] and is reproduced here for completeness. Unlike ...