What question did this study set out to answer?

The research aims to enhance air-quality monitoring accuracy by addressing data sparsity and noise issues in urban environments.

April 16, 2026Open Access

Noise-Aware Diffusion for City-Scale Air-Quality Reconstruction from Sparse Monitoring Stations

Key Points

The research aims to enhance air-quality monitoring accuracy by addressing data sparsity and noise issues in urban environments.
Developed a probabilistic framework called STGPD for city-scale pollutant reconstruction.
Employed a graph-structured spatiotemporal field for posterior sampling.
Implemented noise-aware soft consistency through variance-weighted fusion of observations and model prior.
Constructed a dual-view graph combining geographic and functional similarities.
STGPD outperformed deterministic and diffusion-based methods in reconstruction accuracy.
Results showed significant improvements in MAE and RMSE metrics.
Provided better-calibrated uncertainty estimates compared to traditional approaches.

Abstract

Reliable air-quality monitoring is essential for urban exposure assessment and environmental policy, yet many downstream applications are hindered by sparse regulatory stations and noisy real-world measurements. While diffusion models have shown promise for probabilistic spatiotemporal imputation, common conditioning strategies can be brittle: purely input-based conditioning may drift from sparse constraints, whereas hard clamping can introduce a clean–noisy mismatch and propagate corrupted readings during reverse sampling. In this work, we propose STGPD (SpatioTemporal Graph Posterior Diffusion), a probabilistic framework that formulates city-scale pollutant reconstruction as posterior sampling on a graph-structured spatiotemporal field. STGPD enforces noise-aware soft consistency by re-noising visible observations to the current diffusion level and fusing a noise-matched measurement term with the model prior via variance-weighted fusion under an explicit observation-noise model. To improve spatial extrapolation in heterogeneous urban environments, we further construct a dual-view graph that combines geographic proximity with functional similarity derived from static descriptors. Experiments on real-world monitoring data in Augsburg, Germany, for PM10 and NO2 show that STGPD provides a robust probabilistic reconstruction framework under extreme sparsity, station outages, and synthetic sensor-noise injection in this sparse-monitoring case study. Compared with strong deterministic and diffusion-based baselines, STGPD achieves improved reconstruction accuracy (MAE/RMSE) and better-calibrated uncertainty estimates (CRPS) under the current evaluation protocols.

Noise-Aware Diffusion for City-Scale Air-Quality Reconstruction from Sparse Monitoring Stations

Key Points

Abstract

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