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311 results on '"Toyoizumi, Taro"'

1. Modeling flexible behaviour by the interactions between hippocampus and cortex

Author

Ito, Yoshiki and Toyoizumi, Taro

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Animals flexibly change their behaviour depending on context. In theory, such context-dependent behaviour can be explained by model-based reinforcement learning models. However, existing models lack structure underlying context-dependent model selection and thus, a correspondence to neural activity and brain regions. Here, we employ interacting sequential and context-inference modules to drive model-based learning as a means to better understand experimental neuronal activity data, lesion studies, and clinical research. We propose a neural circuit implementation of the sequential module by the hippocampus and the context-inference module by the cortex that together enable flexible behaviour. Our model explains a variety of experimental findings, including impairments in model-based reasoning reported in lesion studies. Furthermore, our model predicts the relationship between deficits in model-based learning and sensory processing, which often co-occur in psychoses such as schizophrenia (SZ) or autism spectrum disorder (ASD).

Published
2024

2. A provable control of sensitivity of neural networks through a direct parameterization of the overall bi-Lipschitzness

Author

Kinoshita, Yuri and Toyoizumi, Taro

Subjects
Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

While neural networks can enjoy an outstanding flexibility and exhibit unprecedented performance, the mechanism behind their behavior is still not well-understood. To tackle this fundamental challenge, researchers have tried to restrict and manipulate some of their properties in order to gain new insights and better control on them. Especially, throughout the past few years, the concept of \emph{bi-Lipschitzness} has been proved as a beneficial inductive bias in many areas. However, due to its complexity, the design and control of bi-Lipschitz architectures are falling behind, and a model that is precisely designed for bi-Lipschitzness realizing a direct and simple control of the constants along with solid theoretical analysis is lacking. In this work, we investigate and propose a novel framework for bi-Lipschitzness that can achieve such a clear and tight control based on convex neural networks and the Legendre-Fenchel duality. Its desirable properties are illustrated with concrete experiments. We also apply this framework to uncertainty estimation and monotone problem settings to illustrate its broad range of applications.

Published
2024

3. Causal Graph in Language Model Rediscovers Cortical Hierarchy in Human Narrative Processing

Author

He, Zhengqi and Toyoizumi, Taro

Subjects
Computer Science - Computation and Language
Abstract

Understanding how humans process natural language has long been a vital research direction. The field of natural language processing (NLP) has recently experienced a surge in the development of powerful language models. These models have proven to be invaluable tools for studying another complex system known to process human language: the brain. Previous studies have demonstrated that the features of language models can be mapped to fMRI brain activity. This raises the question: is there a commonality between information processing in language models and the human brain? To estimate information flow patterns in a language model, we examined the causal relationships between different layers. Drawing inspiration from the workspace framework for consciousness, we hypothesized that features integrating more information would more accurately predict higher hierarchical brain activity. To validate this hypothesis, we classified language model features into two categories based on causal network measures: 'low in-degree' and 'high in-degree'. We subsequently compared the brain prediction accuracy maps for these two groups. Our results reveal that the difference in prediction accuracy follows a hierarchical pattern, consistent with the cortical hierarchy map revealed by activity time constants. This finding suggests a parallel between how language models and the human brain process linguistic information., Comment: 15 pages, 16 figures

Published
2023

6. Computational role of sleep in memory reorganization

Author

Yoshida, Kensuke and Toyoizumi, Taro

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Sleep is considered to play an essential role in memory reorganization. Despite its importance, classical theoretical models did not focus on some sleep characteristics. Here, we review recent theoretical approaches investigating their roles in learning and discuss the possibility that non-rapid eye movement (NREM) sleep selectively consolidates memory, and rapid eye movement (REM) sleep reorganizes the representations of memories. We first review the possibility that slow waves during NREM sleep contribute to memory selection by using sequential firing patterns and the existence of up and down states. Second, we discuss the role of dreaming during REM sleep in developing neuronal representations. We finally discuss how to develop these points further, emphasizing the connections to experimental neuroscience and machine learning., Comment: Accepted for publication in Current Opinion in Neurobiology

Published
2023
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7. A Hopfield-like model with complementary encodings of memories

Author

Kang, Louis and Toyoizumi, Taro

Subjects
Quantitative Biology - Neurons and Cognition, Condensed Matter - Disordered Systems and Neural Networks
Abstract

We present a Hopfield-like autoassociative network for memories representing examples of concepts. Each memory is encoded by two activity patterns with complementary properties. The first is dense and correlated across examples within concepts, and the second is sparse and exhibits no correlation among examples. The network stores each memory as a linear combination of its encodings. During retrieval, the network recovers sparse or dense patterns with a high or low activity threshold, respectively. As more memories are stored, the dense representation at low threshold shifts from examples to concepts, which are learned from accumulating common example features. Meanwhile, the sparse representation at high threshold maintains distinctions between examples due to the high capacity of sparse, decorrelated patterns. Thus, a single network can retrieve memories at both example and concept scales and perform heteroassociation between them. We obtain our results by deriving macroscopic mean-field equations that yield capacity formulas for sparse examples, dense examples, and dense concepts. We also perform network simulations that verify our theoretical results and explicitly demonstrate the capabilities of the network., Comment: 34 pages including 21 pages of appendices, 9 figures

Published
2023

8. Spontaneous Emerging Preference in Two-tower Language Model

Author

He, Zhengqi and Toyoizumi, Taro

Subjects
Computer Science - Computation and Language, Computer Science - Artificial Intelligence
Abstract

The ever-growing size of the foundation language model has brought significant performance gains in various types of downstream tasks. With the existence of side-effects brought about by the large size of the foundation language model such as deployment cost, availability issues, and environmental cost, there is some interest in exploring other possible directions, such as a divide-and-conquer scheme. In this paper, we are asking a basic question: are language processes naturally dividable? We study this problem with a simple two-tower language model setting, where two language models with identical configurations are trained side-by-side cooperatively. With this setting, we discover the spontaneous emerging preference phenomenon, where some of the tokens are consistently better predicted by one tower while others by another tower. This phenomenon is qualitatively stable, regardless of model configuration and type, suggesting this as an intrinsic property of natural language. This study suggests that interesting properties of natural language are still waiting to be discovered, which may aid the future development of natural language processing techniques.

Published
2022

9. An economic decision-making model of anticipated surprise with dynamic expectation

Author

Chan, Ho Ka and Toyoizumi, Taro

Subjects
Economics - Theoretical Economics
Abstract

When making decisions under risk, people often exhibit behaviors that classical economic theories cannot explain. Newer models that attempt to account for these irrational behaviors often lack neuroscience bases and require the introduction of subjective and problem-specific constructs. Here, we present a decision-making model inspired by the prediction error signals and introspective neuronal replay reported in the brain. In the model, decisions are chosen based on anticipated surprise, defined by a nonlinear average of the differences between individual outcomes and a reference point. The reference point is determined by the expected value of the possible outcomes, which can dynamically change during the mental simulation of decision-making problems involving sequential stages. Our model elucidates the contribution of each stage to the appeal of available options in a decision-making problem. This allows us to explain several economic paradoxes and gambling behaviors. Our work could help bridge the gap between decision-making theories in economics and neurosciences.

Published
2021

10. Progressive Interpretation Synthesis: Interpreting Task Solving by Quantifying Previously Used and Unused Information

Author

He, Zhengqi and Toyoizumi, Taro

Subjects
Computer Science - Artificial Intelligence, Computer Science - Information Theory
Abstract

A deep neural network is a good task solver, but it is difficult to make sense of its operation. People have different ideas about how to form the interpretation about its operation. We look at this problem from a new perspective where the interpretation of task solving is synthesized by quantifying how much and what previously unused information is exploited in addition to the information used to solve previous tasks. First, after learning several tasks, the network acquires several information partitions related to each task. We propose that the network, then, learns the minimal information partition that supplements previously learned information partitions to more accurately represent the input. This extra partition is associated with un-conceptualized information that has not been used in previous tasks. We manage to identify what un-conceptualized information is used and quantify the amount. To interpret how the network solves a new task, we quantify as meta-information how much information from each partition is extracted. We implement this framework with the variational information bottleneck technique. We test the framework with the MNIST and the CLEVR dataset. The framework is shown to be able to compose information partitions and synthesize experience-dependent interpretation in the form of meta-information. This system progressively improves the resolution of interpretation upon new experience by converting a part of the un-conceptualized information partition to a task-related partition. It can also provide a visual interpretation by imaging what is the part of previously un-conceptualized information that is needed to solve a new task., Comment: This is the authors' final version, and the article has been accepted for publication in "Neural Computation"

Published
2021

11. Dimensionality reduction to maximize prediction generalization capability

Author

Isomura, Takuya and Toyoizumi, Taro

Subjects
Statistics - Machine Learning, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning
Abstract

Generalization of time series prediction remains an important open issue in machine learning, wherein earlier methods have either large generalization error or local minima. We develop an analytically solvable, unsupervised learning scheme that extracts the most informative components for predicting future inputs, termed predictive principal component analysis (PredPCA). Our scheme can effectively remove unpredictable noise and minimize test prediction error through convex optimization. Mathematical analyses demonstrate that, provided with sufficient training samples and sufficiently high-dimensional observations, PredPCA can asymptotically identify hidden states, system parameters, and dimensionalities of canonical nonlinear generative processes, with a global convergence guarantee. We demonstrate the performance of PredPCA using sequential visual inputs comprising hand-digits, rotating 3D objects, and natural scenes. It reliably estimates distinct hidden states and predicts future outcomes of previously unseen test input data, based exclusively on noisy observations. The simple architecture and low computational cost of PredPCA are highly desirable for neuromorphic hardware.

Published
2020
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12. Learning poly-synaptic paths with traveling waves

Author

Ito, Yoshiki and Toyoizumi, Taro

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Traveling waves are commonly observed across the brain. While previous studies have suggested the role of traveling waves in learning, the mechanism is still unclear. We adopted a computational approach to investigate the effect of traveling waves on synaptic plasticity. Our results indicate that traveling waves facilitate the learning of poly-synaptic network-paths when combined with a reward-dependent local synaptic plasticity rule. We also demonstrate that traveling waves expedite finding the shortest paths and learning nonlinear input/output-mapping, such as exclusive or (XOR) function., Comment: PLOS Computational Biology Accepted

Published
2019

13. Edge of chaos and avalanches in neural networks with heavy-tailed synaptic weight distribution

Author

Kuśmierz, Łukasz, Ogawa, Shun, and Toyoizumi, Taro

Subjects
Physics - Biological Physics, Condensed Matter - Disordered Systems and Neural Networks
Abstract

We propose an analytically tractable neural connectivity model with power-law distributed synaptic strengths. When threshold neurons with biologically plausible number of incoming connections are considered, our model features a continuous transition to chaos and can reproduce biologically relevant low activity levels and scale-free avalanches, i.e. bursts of activity with power-law distributions of sizes and lifetimes. In contrast, the Gaussian counterpart exhibits a discontinuous transition to chaos and thus cannot be poised near the edge of chaos. We validate our predictions in simulations of networks of binary as well as leaky integrate-and-fire neurons. Our results suggest that heavy-tailed synaptic distribution may form a weakly informative sparse-connectivity prior that can be useful in biological and artificial adaptive systems., Comment: Accepted for publication in Physical Review Letters

Published
2019
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14. Robust random search with scale-free stochastic resetting

Author

Kuśmierz, Łukasz and Toyoizumi, Taro

Subjects
Condensed Matter - Statistical Mechanics, Physics - Data Analysis, Statistics and Probability
Abstract

A new model of search based on stochastic resetting is introduced, wherein rate of resets depends explicitly on time elapsed since the beginning of the process. It is shown that rate inversely proportional to time leads to paradoxical diffusion which mixes self-similarity and linear growth of the mean square displacement with non-locality and non-Gaussian propagator. It is argued that such resetting protocol offers a general and efficient search-boosting method that does not need to be optimized with respect to the scale of the underlying search problem (e.g., distance to the goal) and is not very sensitive to other search parameters. Both subdiffusive and superdiffusive regimes of the mean squared displacement scaling are demonstrated with more general rate functions.

Published
2018
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15. On the achievability of blind source separation for high-dimensional nonlinear source mixtures

Author

Isomura, Takuya and Toyoizumi, Taro

Subjects
Statistics - Machine Learning, Computer Science - Machine Learning
Abstract

For many years, a combination of principal component analysis (PCA) and independent component analysis (ICA) has been used for blind source separation (BSS). However, it remains unclear why these linear methods work well with real-world data that involve nonlinear source mixtures. This work theoretically validates that a cascade of linear PCA and ICA can solve a nonlinear BSS problem accurately -- when the sensory inputs are generated from hidden sources via nonlinear mappings with sufficient dimensionality. Our proposed theorem, termed the asymptotic linearization theorem, theoretically guarantees that applying linear PCA to the inputs can reliably extract a subspace spanned by the linear projections from every hidden source as the major components -- and thus projecting the inputs onto their major eigenspace can effectively recover a linear transformation of the hidden sources. Then, subsequent application of linear ICA can separate all the true independent hidden sources accurately. Zero-element-wise-error nonlinear BSS is asymptotically attained when the source dimensionality is large and the input dimensionality is sufficiently larger than the source dimensionality. Our proposed theorem is validated analytically and numerically. Moreover, the same computation can be performed by using Hebbian-like plasticity rules, implying the biological plausibility of this nonlinear BSS strategy. Our results highlight the utility of linear PCA and ICA for accurately and reliably recovering nonlinearly mixed sources -- and further suggest the importance of employing sensors with sufficient dimensionality to identify true hidden sources of real-world data.

Published
2018

18. Emergence of L\'evy walks from second order stochastic optimization

Author

Kuśmierz, Łukasz and Toyoizumi, Taro

Subjects
Condensed Matter - Statistical Mechanics, Nonlinear Sciences - Adaptation and Self-Organizing Systems, Physics - Biological Physics
Abstract

In natural foraging, many organisms seem to perform two different types of motile search: directed search (taxis) and random search. The former is observed when the environment provides cues to guide motion towards a target. The latter involves no apparent memory or information processing and can be mathematically modeled by random walks. We show that both types of search can be generated by a common mechanism in which L\'evy flights or L\'evy walks emerge from a second-order gradient-based search with noisy observations. No explicit switching mechanism is required -- instead, continuous transitions between the directed and random motions emerge depending on the Hessian matrix of the cost function. For a wide range of scenarios the L\'evy tail index is $\alpha=1$, consistent with previous observations in foraging organisms. These results suggest that adopting a second-order optimization method can be a useful strategy to combine efficient features of directed and random search., Comment: 6 pages, 1 figure

Published
2017
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19. Locally embedded presages of global network bursts

Author

Tajima, Satohiro, Mita, Takeshi, Bakkum, Douglas J., Takahashi, Hirokazu, and Toyoizumi, Taro

Subjects
Quantitative Biology - Neurons and Cognition, Mathematics - Dynamical Systems, Nonlinear Sciences - Chaotic Dynamics, I.2.0
Abstract

Spontaneous, synchronous bursting of neural population is a widely observed phenomenon in nervous networks, which is considered important for functions and dysfunctions of the brain. However, how the global synchrony across a large number of neurons emerges from an initially non-bursting network state is not fully understood. In this study, we develop a new state-space reconstruction method combined with high-resolution recordings of cultured neurons. This method extracts deterministic signatures of upcoming global bursts in "local" dynamics of individual neurons during non-bursting periods. We find that local information within a single-cell time series can compare with or even outperform the global mean field activity for predicting future global bursts. Moreover, the inter-cell variability in the burst predictability is found to reflect the network structure realized in the non-bursting periods. These findings demonstrate the deterministic mechanisms underlying the locally concentrated early-warnings of the global state transition in self-organized networks.

Published
2017
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20. Reinforced stochastic gradient descent for deep neural network learning

Author

Huang, Haiping and Toyoizumi, Taro

Subjects
Computer Science - Learning, Computer Science - Neural and Evolutionary Computing
Abstract

Stochastic gradient descent (SGD) is a standard optimization method to minimize a training error with respect to network parameters in modern neural network learning. However, it typically suffers from proliferation of saddle points in the high-dimensional parameter space. Therefore, it is highly desirable to design an efficient algorithm to escape from these saddle points and reach a parameter region of better generalization capabilities. Here, we propose a simple extension of SGD, namely reinforced SGD, which simply adds previous first-order gradients in a stochastic manner with a probability that increases with learning time. As verified in a simple synthetic dataset, this method significantly accelerates learning compared with the original SGD. Surprisingly, it dramatically reduces over-fitting effects, even compared with state-of-the-art adaptive learning algorithm---Adam. For a benchmark handwritten digits dataset, the learning performance is comparable to Adam, yet with an extra advantage of requiring one-fold less computer memory. The reinforced SGD is also compared with SGD with fixed or adaptive momentum parameter and Nesterov's momentum, which shows that the proposed framework is able to reach a similar generalization accuracy with less computational costs. Overall, our method introduces stochastic memory into gradients, which plays an important role in understanding how gradient-based training algorithms can work and its relationship with generalization abilities of deep networks., Comment: 12 pages and 9 figures, nearly final version as a technical report

Published
2017

23. Unsupervised feature learning from finite data by message passing: discontinuous versus continuous phase transition

Author

Huang, Haiping and Toyoizumi, Taro

Subjects
Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Computer Science - Learning, Quantitative Biology - Neurons and Cognition
Abstract

Unsupervised neural network learning extracts hidden features from unlabeled training data. This is used as a pretraining step for further supervised learning in deep networks. Hence, understanding unsupervised learning is of fundamental importance. Here, we study the unsupervised learning from a finite number of data, based on the restricted Boltzmann machine learning. Our study inspires an efficient message passing algorithm to infer the hidden feature, and estimate the entropy of candidate features consistent with the data. Our analysis reveals that the learning requires only a few data if the feature is salient and extensively many if the feature is weak. Moreover, the entropy of candidate features monotonically decreases with data size and becomes negative (i.e., entropy crisis) before the message passing becomes unstable, suggesting a discontinuous phase transition. In terms of convergence time of the message passing algorithm, the unsupervised learning exhibits an easy-hard-easy phenomenon as the training data size increases. All these properties are reproduced in an approximate Hopfield model, with an exception that the entropy crisis is absent, and only continuous phase transition is observed. This key difference is also confirmed in a handwritten digits dataset. This study deepens our understanding of unsupervised learning from a finite number of data, and may provide insights into its role in training deep networks., Comment: 8 pages, 7 figures (5 pages, 4 figures in the main text and 3 pages of appendix)

Published
2016
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24. Brain State Control by Closed-Loop Environmental Feedback

Author

Buckley, Christopher L., Tajima, Satohiro, Yanagawa, Toru, Takakura, Kana, Nagasaka, Yasuo, Fujii, Naotaka, and Toyoizumi, Taro

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Brain state regulates sensory processing and motor control for adaptive behavior. Internal mechanisms of brain state control are well studied, but the role of external modulation from the environment is not well understood. Here, we examined the role of closed-loop environmental (CLE) feedback, in comparison to open-loop sensory input, on brain state and behavior in diverse vertebrate systems. In fictively swimming zebrafish, CLE feedback for optomotor stability controlled brain state by reducing coherent neuronal activity. The role of CLE feedback in brain state was also shown in a model of rodent active whisking, where brief interruptions in this feedback enhanced signal-to-noise ratio for detecting touch. Finally, in monkey visual fixation, artificial CLE feedback suppressed stimulus-specific neuronal activity and improved behavioral performance. Our findings show that the environment mediates continuous closed-loop feedback that controls neuronal gain, regulating brain state, and that brain function is an emergent property of brain-environment interactions.

Published
2016

25. Clustering of neural codewords revealed by a first-order phase transition

Author

Huang, Haiping and Toyoizumi, Taro

Subjects
Quantitative Biology - Neurons and Cognition, Condensed Matter - Statistical Mechanics, Physics - Biological Physics
Abstract

A network of neurons in the central nervous system collectively represents information by its spiking activity states. Typically observed states, i.e., codewords, occupy only a limited portion of the state space due to constraints imposed by network interactions. Geometrical organization of codewords in the state space, critical for neural information processing, is poorly understood due to its high dimensionality. Here, we explore the organization of neural codewords using retinal data by computing the entropy of codewords as a function of Hamming distance from a particular reference codeword. Specifically, we report that the retinal codewords in the state space are divided into multiple distinct clusters separated by entropy-gaps, and that this structure is shared with well-known associative memory networks in a recallable phase. Our analysis also elucidates a special nature of the all-silent state. The all-silent state is surrounded by the densest cluster of codewords and located within a reachable distance from most codewords. This codeword-space structure quantitatively predicts typical deviation of a state-trajectory from its initial state. Altogether, our findings reveal a non-trivial heterogeneous structure of the codeword-space that shapes information representation in a biological network., Comment: 14 pages, 5 figures in main text plus Supplemental Material (7 pages)

Published
2016
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26. Integrating Hebbian and homeostatic plasticity: the current state of the field and future research directions

Author

Keck, Tara, Toyoizumi, Taro, Chen, Lu, Doiron, Brent, Feldman, Daniel E, Fox, Kevin, Gerstner, Wulfram, Haydon, Philip G, Hübener, Mark, Lee, Hey-Kyoung, Lisman, John E, Rose, Tobias, Sengpiel, Frank, Stellwagen, David, Stryker, Michael P, Turrigiano, Gina G, and van Rossum, Mark C

Subjects
Animals, Brain, Homeostasis, Humans, Neuronal Plasticity, Hebbian plasticity, homeostatic mechanisms, theoretical modelling, Biological Sciences, Medical and Health Sciences, Evolutionary Biology
Abstract

We summarize here the results presented and subsequent discussion from the meeting on Integrating Hebbian and Homeostatic Plasticity at the Royal Society in April 2016. We first outline the major themes and results presented at the meeting. We next provide a synopsis of the outstanding questions that emerged from the discussion at the end of the meeting and finally suggest potential directions of research that we believe are most promising to develop an understanding of how these two forms of plasticity interact to facilitate functional changes in the brain.This article is part of the themed issue 'Integrating Hebbian and homeostatic plasticity'.

Published
2017

28. Structure of attractors in randomly connected networks

Author

Toyoizumi, Taro and Huang, Haiping

Subjects
Condensed Matter - Statistical Mechanics, Nonlinear Sciences - Chaotic Dynamics
Abstract

The deterministic dynamics of randomly connected neural networks are studied, where a state of binary neurons evolves according to a discreet-time synchronous update rule. We give a theoretical support that the overlap of systems' states between the current and a previous time develops in time according to a Markovian stochastic process in large networks. This Markovian process predicts how often a network revisits one of previously visited states, depending on the system size. The state concentration probability, i.e., the probability that two distinct states co-evolve to the same state, is utilized to analytically derive various characteristics that quantify attractors' structure. The analytical predictions about the total number of attractors, the typical cycle length, and the number of states belonging to all attractive cycles match well with numerical simulations for relatively large system sizes., Comment: 13 pages, 7 figures, to be published by Phys Rev E

Published
2015
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29. Advanced Mean Field Theory of Restricted Boltzmann Machine

Author

Huang, Haiping and Toyoizumi, Taro

Subjects
Condensed Matter - Statistical Mechanics, Computer Science - Learning, Quantitative Biology - Neurons and Cognition, Statistics - Machine Learning
Abstract

Learning in restricted Boltzmann machine is typically hard due to the computation of gradients of log-likelihood function. To describe the network state statistics of the restricted Boltzmann machine, we develop an advanced mean field theory based on the Bethe approximation. Our theory provides an efficient message passing based method that evaluates not only the partition function (free energy) but also its gradients without requiring statistical sampling. The results are compared with those obtained by the computationally expensive sampling based method., Comment: 5 pages, 4 figures, accepted by Phys Rev E (Rapid Communication)

Published
2015
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33. Nearly extensive sequential memory lifetime achieved by coupled nonlinear neurons

Author

Toyoizumi, Taro

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Many cognitive processes rely on the ability of the brain to hold sequences of events in short-term memory. Recent studies have revealed that such memory can be read out from the transient dynamics of a network of neurons. However, the memory performance of such a network in buffering past information has only been rigorously estimated in networks of linear neurons. When signal gain is kept low, so that neurons operate primarily in the linear part of their response nonlinearity, the memory lifetime is bounded by the square root of the network size. In this work, I demonstrate that it is possible to achieve a memory lifetime almost proportional to the network size, "an extensive memory lifetime", when the nonlinearity of neurons is appropriately utilized. The analysis of neural activity revealed that nonlinear dynamics prevented the accumulation of noise by partially removing noise in each time step. With this error-correcting mechanism, I demonstrate that a memory lifetime of order $N/\log N$ can be achieved., Comment: 21 pages, 5 figures, the manuscript has been accepted for publication in Neural Computation

Published
2012
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34. State Concentration Exponent as a Measure of Quickness in Kauffman-type Networks

Author

Amari, Shun-ichi, Ando, Hiroyasu, Toyoizumi, Taro, and Masuda, Naoki

Subjects
Condensed Matter - Disordered Systems and Neural Networks, Nonlinear Sciences - Adaptation and Self-Organizing Systems
Abstract

We study the dynamics of randomly connected networks composed of binary Boolean elements and those composed of binary majority vote elements. We elucidate their differences in both sparsely and densely connected cases. The quickness of large network dynamics is usually quantified by the length of transient paths, an analytically intractable measure. For discrete-time dynamics of networks of binary elements, we address this dilemma with an alternative unified framework by using a concept termed state concentration, defined as the exponent of the average number of t-step ancestors in state transition graphs. The state transition graph is defined by nodes corresponding to network states and directed links corresponding to transitions. Using this exponent, we interrogate the dynamics of random Boolean and majority vote networks. We find that extremely sparse Boolean networks and majority vote networks with arbitrary density achieve quickness, owing in part to long-tailed in-degree distributions. As a corollary, only relatively dense majority vote networks can achieve both quickness and robustness., Comment: 6 figures

Published
2012
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35. Modeling the Dynamic Interaction of Hebbian and Homeostatic Plasticity

Author

Toyoizumi, Taro, Kaneko, Megumi, Stryker, Michael P, and Miller, Kenneth D

Subjects
Eye Disease and Disorders of Vision, Neurosciences, 1.1 Normal biological development and functioning, Underpinning research, Animals, Dominance, Ocular, Feedback, Homeostasis, Male, Mice, Inbred C57BL, Models, Neurological, Neuronal Plasticity, Neurons, Synapses, Time Factors, Psychology, Cognitive Sciences, Neurology & Neurosurgery
Abstract

Hebbian and homeostatic plasticity together refine neural circuitry, but their interactions are unclear. In most existing models, each form of plasticity directly modifies synaptic strength. Equilibrium is reached when the two are inducing equal and opposite changes. We show that such models cannot reproduce ocular dominance plasticity (ODP) because negative feedback from the slow homeostatic plasticity observed in ODP cannot stabilize the positive feedback of fast Hebbian plasticity. We propose a model in which synaptic strength is the product of a synapse-specific Hebbian factor and a postsynaptic-cell-specific homeostatic factor, with each factor separately arriving at a stable inactive state. This model captures ODP dynamics and has plausible biophysical substrates. We confirm model predictions experimentally that plasticity is inactive at stable states and that synaptic strength overshoots during recovery from visual deprivation. These results highlight the importance of multiple regulatory pathways for interactions of plasticity mechanisms operating over separate timescales.

Published
2014

36. Chaotic neural dynamics facilitate probabilistic computations through sampling.

Author

Terada, Yu and Toyoizumi, Taro

Subjects
*MARGINAL distributions, *RECURRENT neural networks, *SENSORIMOTOR integration, *TIME trials
Abstract

Cortical neurons exhibit highly variable responses over trials and time. Theoretical works posit that this variability arises potentially from chaotic network dynamics of recurrently connected neurons. Here, we demonstrate that chaotic neural dynamics, formed through synaptic learning, allow networks to perform sensory cue integration in a sampling-based implementation. We show that the emergent chaotic dynamics provide neural substrates for generating samples not only of a static variable but also of a dynamical trajectory, where generic recurrent networks acquire these abilities with a biologically plausible learning rule through trial and error. Furthermore, the networks generalize their experience in the stimulus-evoked samples to the inference without partial or all sensory information, which suggests a computational role of spontaneous activity as a representation of the priors as well as a tractable biological computation for marginal distributions. These findings suggest that chaotic neural dynamics may serve for the brain function as a Bayesian generative model. [ABSTRACT FROM AUTHOR]

Published
2024
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39. Optimal Spike-Timing Dependent Plasticity for Precise Action Potential Firing

Author

Pfister, Jean-Pascal, Toyoizumi, Taro, Barber, David, and Gerstner, Wulfram

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

In timing-based neural codes, neurons have to emit action potentials at precise moments in time. We use a supervised learning paradigm to derive a synaptic update rule that optimizes via gradient ascent the likelihood of postsynaptic firing at one or several desired firing times. We find that the optimal strategy of up- and downregulating synaptic efficacies can be described by a two-phase learning window similar to that of Spike-Timing Dependent Plasticity (STDP). If the presynaptic spike arrives before the desired postsynaptic spike timing, our optimal learning rule predicts that the synapse should become potentiated. The dependence of the potentiation on spike timing directly reflects the time course of an excitatory postsynaptic potential. The presence and amplitude of depression of synaptic efficacies for reversed spike timing depends on how constraints are implemented in the optimization problem. Two different constraints, i.e., control of postsynaptic rates or control of temporal locality,are discussed., Comment: 27 pages, 10 figures

Published
2005

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