Related papers: AnchorGK: Anchor-based Incremental and Stratified Graph Learning Framework for Inductive Spatio-Temporal Kriging

AnchorGK: Anchor-based Incremental and Stratified Graph Learning Framework for Inductive Spatio-Temporal Kriging

URL: http://arxiv.org/abs/2512.21569v1
Date: Thu, 25 Dec 2025 08:27:09 GMT
Title: AnchorGK: Anchor-based Incremental and Stratified Graph Learning Framework for Inductive Spatio-Temporal Kriging
Authors: Xiaobin Ren, Kaiqi Zhao, Katerina Taškova, Patricia Riddle,
Abstract summary: We propose AnchorGK, an Anchor-based Incremental and Stratified Graph Learning framework for inductive-temporal kriging.<n>We show that AnchorGK consistently outperforms state-of-the-art baselines for accurate under-temporal kriging.
Score: 2.679123009431667
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Spatio-temporal kriging is a fundamental problem in sensor networks, driven by the sparsity of deployed sensors and the resulting missing observations. Although recent approaches model spatial and temporal correlations, they often under-exploit two practical characteristics of real deployments: the sparse spatial distribution of locations and the heterogeneous availability of auxiliary features across locations. To address these challenges, we propose AnchorGK, an Anchor-based Incremental and Stratified Graph Learning framework for inductive spatio-temporal kriging. AnchorGK introduces anchor locations to stratify the data in a principled manner. Anchors are constructed according to feature availability, and strata are then formed around these anchors. This stratification serves two complementary roles. First, it explicitly represents and continuously updates correlations between unobserved regions and surrounding observed locations within a graph learning framework. Second, it enables the systematic use of all available features across strata via an incremental representation mechanism, mitigating feature incompleteness without discarding informative signals. Building on the stratified structure, we design a dual-view graph learning layer that jointly aggregates feature-relevant and location-relevant information, learning stratum-specific representations that support accurate inference under inductive settings. Extensive experiments on multiple benchmark datasets demonstrate that AnchorGK consistently outperforms state-of-the-art baselines for spatio-temporal kriging.

Related papers

ContextFusion and Bootstrap: An Effective Approach to Improve Slot Attention-Based Object-Centric Learning [53.19029595226767]
Slot attention-based framework has emerged as a leading approach in object-centric learning.<n>Current methods require a stable feature space throughout training to enable reconstruction from slots.<n>We propose a novel ContextFusion stage and a Bootstrap Branch, both of which can be seamlessly integrated into existing slot attention models.
arXiv Detail & Related papers (2025-09-02T07:19:25Z)
Spatial regularisation for improved accuracy and interpretability in keypoint-based registration [5.286949071316761]
Recent approaches based on unsupervised keypoint detection stand out as very promising for interpretability.<n>Here, we propose a three-fold loss to regularise the spatial distribution of the features.<n>Our loss considerably improves the interpretability of the features, which now correspond to precise and anatomically meaningful landmarks.
arXiv Detail & Related papers (2025-03-06T14:48:25Z)
Kriformer: A Novel Spatiotemporal Kriging Approach Based on Graph Transformers [5.4381914710364665]
This study addresses posed by sparse sensor deployment and unreliable data by framing the problem as an environmental challenge. A graphkriformer model, Kriformer, estimates data at locations without sensors by mining spatial and temporal correlations, even with limited resources.
arXiv Detail & Related papers (2024-09-23T11:01:18Z)
Localized Gaussians as Self-Attention Weights for Point Clouds Correspondence [92.07601770031236]
We investigate semantically meaningful patterns in the attention heads of an encoder-only Transformer architecture.<n>We find that fixing the attention weights not only accelerates the training process but also enhances the stability of the optimization.
arXiv Detail & Related papers (2024-09-20T07:41:47Z)
Rethinking Sensors Modeling: Hierarchical Information Enhanced Traffic Forecasting [47.1051445072085]
We argue to rethink the sensor's dependency modeling from two hierarchies: regional and global. We generate representative and common-temporal patterns as global nodes to reflect a global dependency between sensors. In pursuit of the generality of reality of node representations, we incorporate a Meta GCN to propagate and global nodes in the physical data space.
arXiv Detail & Related papers (2023-09-20T13:08:34Z)
pCTFusion: Point Convolution-Transformer Fusion with Semantic Aware Loss for Outdoor LiDAR Point Cloud Segmentation [8.24822602555667]
This study proposes a new architecture, pCTFusion, which combines kernel-based convolutions and self-attention mechanisms. The proposed architecture employs two types of self-attention mechanisms, local and global, based on the hierarchical positions of the encoder blocks. The results are particularly encouraging for minor classes, often misclassified due to class imbalance, lack of space, and neighbor-aware feature encoding.
arXiv Detail & Related papers (2023-07-27T11:12:48Z)
Adaptive Local-Component-aware Graph Convolutional Network for One-shot Skeleton-based Action Recognition [54.23513799338309]
We present an Adaptive Local-Component-aware Graph Convolutional Network for skeleton-based action recognition. Our method provides a stronger representation than the global embedding and helps our model reach state-of-the-art.
arXiv Detail & Related papers (2022-09-21T02:33:07Z)
DenseGAP: Graph-Structured Dense Correspondence Learning with Anchor Points [15.953570826460869]
Establishing dense correspondence between two images is a fundamental computer vision problem. We introduce DenseGAP, a new solution for efficient Dense correspondence learning with a Graph-structured neural network conditioned on Anchor Points. Our method advances the state-of-the-art of correspondence learning on most benchmarks.
arXiv Detail & Related papers (2021-12-13T18:59:30Z)
Spatial-Temporal Correlation and Topology Learning for Person Re-Identification in Videos [78.45050529204701]
We propose a novel framework to pursue discriminative and robust representation by modeling cross-scale spatial-temporal correlation. CTL utilizes a CNN backbone and a key-points estimator to extract semantic local features from human body. It explores a context-reinforced topology to construct multi-scale graphs by considering both global contextual information and physical connections of human body.
arXiv Detail & Related papers (2021-04-15T14:32:12Z)
Spatial-spectral Hyperspectral Image Classification via Multiple Random Anchor Graphs Ensemble Learning [88.60285937702304]
This paper proposes a novel spatial-spectral HSI classification method via multiple random anchor graphs ensemble learning (RAGE) Firstly, the local binary pattern is adopted to extract the more descriptive features on each selected band, which preserves local structures and subtle changes of a region. Secondly, the adaptive neighbors assignment is introduced in the construction of anchor graph, to reduce the computational complexity.
arXiv Detail & Related papers (2021-03-25T09:31:41Z)
Scope Head for Accurate Localization in Object Detection [135.9979405835606]
We propose a novel detector coined as ScopeNet, which models anchors of each location as a mutually dependent relationship. With our concise and effective design, the proposed ScopeNet achieves state-of-the-art results on COCO.
arXiv Detail & Related papers (2020-05-11T04:00:09Z)

This list is automatically generated from the titles and abstracts of the papers in this site.