GTNet: A Graph–Transformer Neural Network for Robust Ecological Health Monitoring in Smart Cities.
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| Title: | GTNet: A Graph–Transformer Neural Network for Robust Ecological Health Monitoring in Smart Cities. |
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| Authors: | Aldossary, Mohammad |
| Source: | Mathematics (2227-7390); Jan2026, Vol. 14 Issue 1, p64, 43p |
| Subject Terms: | ENVIRONMENTAL monitoring, SMART cities, URBAN ecology, ENVIRONMENTAL management, PREDICTION models, SUSTAINABILITY, TRANSFORMER models |
| Geographic Terms: | MELBOURNE (Vic.) |
| Abstract: | Urban towns and smart city governments face increasing challenges in maintaining ecological balance as urbanization, industrial activity, and climate dynamics evolve. The degradation of ecological gardens, biodiversity parks, and waterways adversely affects ecosystem stability, air and water quality, and community well-being. Conventional urban ecological systems rely on reactive assessment methods that detect damage only after it occurs, leading to delayed interventions, higher maintenance costs, and irreversible environmental harm. This study introduces a Graph–Transformer Neural Network (GTNet) as a data-driven and predictive framework for sustainable urban ecological management. GTNet provides real-time estimation of smart city garden health, addressing the gap in proactive environmental monitoring. The model captures spatial relationships and contextual dependencies among multimodal environmental features using Dynamic Graph Convolutional Neural Network (DGCNN) and Vision Transformer (ViT) layers. The preprocessing pipeline integrates Principal Component Aggregation with Orthogonal Constraints (PCAOC) for dimensionality reduction, Weighted Cross-Variance Selection (WCVS) for feature relevance, and Selective Equilibrium Resampling (SER) for class balancing, ensuring robustness and interpretability across complex ecological datasets. Two new metrics, Contextual Consistency Score (CCS) and Complexity-Weighted Accuracy (CWA), are introduced to evaluate model reliability and performance under diverse environmental conditions. Experimental results on Melbourne's multi-year urban garden datasets demonstrate that GTNet outperforms baseline models such as Predictive Clustering Trees, LSTM networks, and Random Forests, achieving an AUC of 98.9%, CCS of 0.94, and CWA of 0.96. GTNet's scalability, predictive accuracy, and computational efficiency establish it as a powerful framework for AI-driven ecological governance. This research supports the transition of future smart cities from reactive to proactive, transparent, and sustainable environmental management. [ABSTRACT FROM AUTHOR] |
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| Database: | Complementary Index |
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