English

LiDAR-based Dynamic Blockage Prediction: A Data-driven Approach for Learning Interactive Bayesian Models

Signal Processing 2026-05-01 v1

Abstract

Vehicular sensing-based intelligence has made substantial progress in transportation systems, leading to higher levels of safety and sustainability for smart cities and autonomous systems. This paper proposes a new approach to learn an interactive generalized dynamic Bayesian network (I-GDBN) model aiming to predict future LiDAR sensor blockages from time-sequence-based 3D point cloud perception. During learning, separate GDBN models are trained for various vehicles in normal and blockage situations. To perform the interaction between multiple vehicles, a high-level vocabulary is formed. Initially, during testing, the best generative model for either normal or blockage situations is selected. An interactive Markov jump particle filter (I-MJPF) is then proposed to leverage the probabilistic information provided by the I-GDBN to infer the blockages and detect the abnormalities at the high abstraction level. The proposed interactive model allows better self-aware and explainable capabilities that can adapt to blockage scenarios, which is also helpful when sensors fail to provide observations.

Keywords

Cite

@article{arxiv.2604.28040,
  title  = {LiDAR-based Dynamic Blockage Prediction: A Data-driven Approach for Learning Interactive Bayesian Models},
  author = {Saleemullah Memon and Ali Krayani and Pamela Zontone and Lucio Marcenaro and David Martin Gomez and Carlo Regazzoni},
  journal= {arXiv preprint arXiv:2604.28040},
  year   = {2026}
}

Comments

2025 IEEE International Workshop on Technologies for Defense and Security (TechDefense), Rome, Italy

R2 v1 2026-07-01T12:43:53.401Z