Geometry-Aware Spiking Graph Neural Network
- URL: http://arxiv.org/abs/2508.06793v2
- Date: Mon, 25 Aug 2025 10:22:46 GMT
- Title: Geometry-Aware Spiking Graph Neural Network
- Authors: Bowen Zhang, Genan Dai, Hu Huang, Long Lan,
- Abstract summary: We propose a Geometry-Aware Spiking Graph Neural Network that unifies spike-based neural dynamics with adaptive representation learning.<n>Experiments on multiple benchmarks show that GSG achieves superior accuracy, robustness, and energy efficiency compared to both Euclidean SNNs and manifold-based GNNs.
- Score: 24.920334588995072
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Graph Neural Networks (GNNs) have demonstrated impressive capabilities in modeling graph-structured data, while Spiking Neural Networks (SNNs) offer high energy efficiency through sparse, event-driven computation. However, existing spiking GNNs predominantly operate in Euclidean space and rely on fixed geometric assumptions, limiting their capacity to model complex graph structures such as hierarchies and cycles. To overcome these limitations, we propose \method{}, a novel Geometry-Aware Spiking Graph Neural Network that unifies spike-based neural dynamics with adaptive representation learning on Riemannian manifolds. \method{} features three key components: a Riemannian Embedding Layer that projects node features into a pool of constant-curvature manifolds, capturing non-Euclidean structures; a Manifold Spiking Layer that models membrane potential evolution and spiking behavior in curved spaces via geometry-consistent neighbor aggregation and curvature-based attention; and a Manifold Learning Objective that enables instance-wise geometry adaptation through jointly optimized classification and link prediction losses defined over geodesic distances. All modules are trained using Riemannian SGD, eliminating the need for backpropagation through time. Extensive experiments on multiple benchmarks show that GSG achieves superior accuracy, robustness, and energy efficiency compared to both Euclidean SNNs and manifold-based GNNs, establishing a new paradigm for curvature-aware, energy-efficient graph learning.
Related papers
- The Neural Differential Manifold: An Architecture with Explicit Geometric Structure [8.201374511929538]
This paper introduces the Neural Differential Manifold (NDM), a novel neural network architecture that explicitly incorporates geometric structure into its fundamental design.<n>We analyze the theoretical advantages of this approach, including its potential for more efficient optimization, enhanced continual learning, and applications in scientific discovery and controllable generative modeling.
arXiv Detail & Related papers (2025-10-29T02:24:27Z) - Adaptive Riemannian Graph Neural Networks [29.859977834688625]
We introduce a novel framework that learns a continuous and anisotropic metric tensor field over the graph.<n>It allows each node to determine its optimal local geometry, enabling the model to fluidly adapt to the graph's structural landscape.<n>Our method demonstrates superior performance on both homophilic and heterophilic benchmark geometries.
arXiv Detail & Related papers (2025-08-04T16:55:02Z) - Can we ease the Injectivity Bottleneck on Lorentzian Manifolds for Graph Neural Networks? [0.0]
Lorentzian Graph Isomorphic Network (LGIN) is a novel HGNN designed for enhanced discrimination within the Lorentzian model.<n>LGIN is the first to adapt principles of powerful, highly discriminative GNN architectures to a Riemannian manifold.
arXiv Detail & Related papers (2025-03-31T18:49:34Z) - Spiking Graph Neural Network on Riemannian Manifolds [51.15400848660023]
Graph neural networks (GNNs) have become the dominant solution for learning on graphs.
Existing spiking GNNs consider graphs in Euclidean space, ignoring the structural geometry.
We present a Manifold-valued Spiking GNN (MSG)
MSG achieves superior performance to previous spiking GNNs and energy efficiency to conventional GNNs.
arXiv Detail & Related papers (2024-10-23T15:09:02Z) - Spatiotemporal Learning on Cell-embedded Graphs [6.8090864965073274]
We introduce a learnable cell attribution to the node-edge message passing process, which better captures the spatial dependency of regional features.
Experiments on various PDE systems and one real-world dataset demonstrate that CeGNN achieves superior performance compared with other baseline models.
arXiv Detail & Related papers (2024-09-26T16:22:08Z) - DeepRicci: Self-supervised Graph Structure-Feature Co-Refinement for
Alleviating Over-squashing [72.70197960100677]
Graph Structure Learning (GSL) plays an important role in boosting Graph Neural Networks (GNNs) with a refined graph.
GSL solutions usually focus on structure refinement with task-specific supervision (i.e., node classification) or overlook the inherent weakness of GNNs themselves.
We propose to study self-supervised graph structure-feature co-refinement for effectively alleviating the issue of over-squashing in typical GNNs.
arXiv Detail & Related papers (2024-01-23T14:06:08Z) - Torsion Graph Neural Networks [21.965704710488232]
We propose TorGNN, an analytic torsion enhanced Graph Neural Network model.
In our TorGNN, for each edge, a corresponding local simplicial complex is identified, then the analytic torsion is calculated.
It has been found that our TorGNN can achieve superior performance on both tasks, and outperform various state-of-the-art models.
arXiv Detail & Related papers (2023-06-23T15:02:23Z) - Convolutional Neural Networks on Manifolds: From Graphs and Back [122.06927400759021]
We propose a manifold neural network (MNN) composed of a bank of manifold convolutional filters and point-wise nonlinearities.
To sum up, we focus on the manifold model as the limit of large graphs and construct MNNs, while we can still bring back graph neural networks by the discretization of MNNs.
arXiv Detail & Related papers (2022-10-01T21:17:39Z) - Learnable Filters for Geometric Scattering Modules [64.03877398967282]
We propose a new graph neural network (GNN) module based on relaxations of recently proposed geometric scattering transforms.
Our learnable geometric scattering (LEGS) module enables adaptive tuning of the wavelets to encourage band-pass features to emerge in learned representations.
arXiv Detail & Related papers (2022-08-15T22:30:07Z) - ACE-HGNN: Adaptive Curvature Exploration Hyperbolic Graph Neural Network [72.16255675586089]
We propose an Adaptive Curvature Exploration Hyperbolic Graph NeuralNetwork named ACE-HGNN to adaptively learn the optimal curvature according to the input graph and downstream tasks.
Experiments on multiple real-world graph datasets demonstrate a significant and consistent performance improvement in model quality with competitive performance and good generalization ability.
arXiv Detail & Related papers (2021-10-15T07:18:57Z) - Curvature Graph Neural Network [8.477559786537919]
We introduce discrete graph curvature (the Ricci curvature) to quantify the strength of structural connection of pairwise nodes.
We propose Curvature Graph Neural Network (CGNN), which effectively improves the adaptive locality ability of GNNs.
The experimental results on synthetic datasets show that CGNN effectively exploits the topology structure information.
arXiv Detail & Related papers (2021-06-30T00:56:03Z) - Data-Driven Learning of Geometric Scattering Networks [74.3283600072357]
We propose a new graph neural network (GNN) module based on relaxations of recently proposed geometric scattering transforms.
Our learnable geometric scattering (LEGS) module enables adaptive tuning of the wavelets to encourage band-pass features to emerge in learned representations.
arXiv Detail & Related papers (2020-10-06T01:20:27Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.