A cartographic generalization method for 3D visualization of trajectories in space–time cubes: case study of epidemic spread

A cartographic generalization method for 3D visualization of trajectories in space–time cubes: case study of epidemic spread

The widespread adoption of positioning technology and location-based services has resulted in the continuous generation of substantial volumes of accessible spatiotemporal trajectory data. While many studies focus on 2D trajectory visualization, research on visual overload in 3D space remains limite...

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Bibliographic Details
Main Authors: Fei Yang, Jie Shen, Fengzhen Zhu, Junrui Zhang
Format: Article
Language:English
Published: Taylor & Francis Group 2025-08-01
Series:International Journal of Digital Earth
Subjects:
Spatiotemporal visualization
space–time cube
cognitive load theory
cartographic generalization
epidemic spread
Online Access:https://www.tandfonline.com/doi/10.1080/17538947.2025.2474190
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Summary:The widespread adoption of positioning technology and location-based services has resulted in the continuous generation of substantial volumes of accessible spatiotemporal trajectory data. While many studies focus on 2D trajectory visualization, research on visual overload in 3D space remains limited. Thus, there is a need to balance the presentation of spatiotemporal information and to minimize visual occlusions in the 3D representation of trajectories. To address this gap, we propose a global-local cooperative optimization method based on cognitive load theory, which utilizes cartographic generalization to emphasize local features and clarity, while treating 3D visualization as a global opacity optimization problem to enhance visibility and reduce occlusions. We take the spread trajectories of infectious diseases as our research subject, due to their characteristic spatiotemporal patterns, and employ a space–time cube as the visualization tool. The proposed method incorporates a 3D generalization algorithm that mitigates visual stickiness, while leveraging a 3D line field visualization technique to optimize opacity, thereby minimizing visual occlusion and spatial clutter. The experimental results validate the method's effectiveness in reducing occlusion, resolving visual entanglement, and lowering cognitive load, which in turn improving the clarity and usability of epidemic trajectory visualization.
ISSN:1753-8947
1753-8955

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