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hierarchical-connectome-phc

Parallelized Hierarchical Connectome (PHC) framework for spatiotemporal recurrent spiking neural networks. Upgrades State-Space Models (SSMs) into spatiotemporal networks with biological constraints including Dale's Law, short-term plasticity, and reward-modulated STDP. Activation: spiking neural networks, SSM, connectome, spatiotemporal modeling, biological neural networks.

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UpdatedJune 4, 2026 at 02:00

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name	hierarchical-connectome-phc
description	Parallelized Hierarchical Connectome (PHC) framework for spatiotemporal recurrent spiking neural networks. Upgrades State-Space Models (SSMs) into spatiotemporal networks with biological constraints including Dale's Law, short-term plasticity, and reward-modulated STDP. Activation: spiking neural networks, SSM, connectome, spatiotemporal modeling, biological neural networks.

Parallelized Hierarchical Connectome (PHC)

Overview

This work presents the Parallelized Hierarchical Connectome (PHC), a general framework that upgrades temporal-only State-Space Models (SSMs) into spatiotemporal recurrent networks by mapping SSM components to hierarchical neuronal architectures with biological constraints.

Paper Reference

Title: Parallelized Hierarchical Connectome: A Spatiotemporal Recurrent Framework for Spiking State-Space Models
arXiv ID: 2604.01295v1
Authors: Po-Han Chiang
Published: 2026-04-01
Category: q-bio.NC (Neurons and Cognition)
PDF: https://arxiv.org/pdf/2604.01295v1

Core Innovation

PHC maps the diagonal SSM core to a shared Neuron Layer and inter-neuronal communication to a shared Synapse Layer, where neurons are partitioned into hierarchical regions governed by the connectome topology.

Key Features

Multi-Transmission Loop: Enables intra-slice spatial recurrence within each temporal window while preserving O(logT) parallelism
Biological Constraints: Supports intractable neuro-physical priors including:
- Adaptive leaky integrate-and-fire (ALIF) dynamics
- Dale's Law (excitatory/inhibitory neuron separation)
- Short-term plasticity
- Reward-modulated spike-timing-dependent plasticity (STDP)
Parameter Efficiency: Reduces complexity from Θ(D²L) for L-layer stacked architectures to Θ(D²)

PHCSSM Implementation

PHCSSM is the first model to unify:

Recurrent spiking neural network dynamics
Diagonal SSM parallelism
Five biological constraints
Learnable lateral connections
Fully parallelizable training pipeline

Architecture Components

Neuron Layer (NL)

Maps diagonal SSM core to hierarchical neuronal regions

Synapse Layer (SL)

Inter-neuronal communication with connectome topology

Multi-Transmission Loop

Intra-slice spatial recurrence
Preserves parallel scan efficiency
Enables lateral/feedback interactions within single timestep

Biological Constraints Supported

Constraint	Description
ALIF	Adaptive leaky integrate-and-fire dynamics
Dale's Law	Excitatory/inhibitory neuron separation
STP	Short-term plasticity
R-STDP	Reward-modulated spike-timing-dependent plasticity

Empirical Results

Evaluated on physiological benchmarks from the UEA multivariate time-series archive:

Performance: Competitive with state-of-the-art SSMs
Parameter complexity: Reduced from Θ(D²L) to Θ(D²)
Training: Fully parallelizable pipeline

Methodology Applications

Use this framework when:

Building biologically grounded sequence models
Implementing spiking neural networks with SSM efficiency
Researching brain-inspired parameter-efficient architectures
Studying spatiotemporal dynamics in neural systems

Trigger Keywords

spiking neural network
state-space model
connectome
spatiotemporal recurrence
biological neural network
Dale's Law
short-term plasticity
reward-modulated STDP
parallel scan
parameter-efficient SSM

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name	hierarchical-connectome-phc
description	Parallelized Hierarchical Connectome (PHC) framework for spatiotemporal recurrent spiking neural networks. Upgrades State-Space Models (SSMs) into spatiotemporal networks with biological constraints including Dale's Law, short-term plasticity, and reward-modulated STDP. Activation: spiking neural networks, SSM, connectome, spatiotemporal modeling, biological neural networks.

Parallelized Hierarchical Connectome (PHC)

Overview

Paper Reference

Title: Parallelized Hierarchical Connectome: A Spatiotemporal Recurrent Framework for Spiking State-Space Models
arXiv ID: 2604.01295v1
Authors: Po-Han Chiang
Published: 2026-04-01
Category: q-bio.NC (Neurons and Cognition)
PDF: https://arxiv.org/pdf/2604.01295v1

Core Innovation

Key Features

Multi-Transmission Loop: Enables intra-slice spatial recurrence within each temporal window while preserving O(logT) parallelism
Biological Constraints: Supports intractable neuro-physical priors including:
- Adaptive leaky integrate-and-fire (ALIF) dynamics
- Dale's Law (excitatory/inhibitory neuron separation)
- Short-term plasticity
- Reward-modulated spike-timing-dependent plasticity (STDP)
Parameter Efficiency: Reduces complexity from Θ(D²L) for L-layer stacked architectures to Θ(D²)

PHCSSM Implementation

PHCSSM is the first model to unify:

Recurrent spiking neural network dynamics
Diagonal SSM parallelism
Five biological constraints
Learnable lateral connections
Fully parallelizable training pipeline

Architecture Components

Neuron Layer (NL)

Maps diagonal SSM core to hierarchical neuronal regions

Synapse Layer (SL)

Inter-neuronal communication with connectome topology

Multi-Transmission Loop

Intra-slice spatial recurrence
Preserves parallel scan efficiency
Enables lateral/feedback interactions within single timestep

Biological Constraints Supported

Constraint	Description
ALIF	Adaptive leaky integrate-and-fire dynamics
Dale's Law	Excitatory/inhibitory neuron separation
STP	Short-term plasticity
R-STDP	Reward-modulated spike-timing-dependent plasticity

Empirical Results

Evaluated on physiological benchmarks from the UEA multivariate time-series archive:

Performance: Competitive with state-of-the-art SSMs
Parameter complexity: Reduced from Θ(D²L) to Θ(D²)
Training: Fully parallelizable pipeline

Methodology Applications

Use this framework when:

Building biologically grounded sequence models
Implementing spiking neural networks with SSM efficiency
Researching brain-inspired parameter-efficient architectures
Studying spatiotemporal dynamics in neural systems

Trigger Keywords

spiking neural network
state-space model
connectome
spatiotemporal recurrence
biological neural network
Dale's Law
short-term plasticity
reward-modulated STDP
parallel scan
parameter-efficient SSM