Toward Robust Visual Perception for Autonomous Systems: Advancements in Cross-View Localisation and Temporal Fusion
Abstract
Autonomous driving systems require robust visual perception to operate safely in diverse and dynamic environments. This thesis advances visual perception by focusing on two key areas: cross-view localisation and temporal fusion, aiming to reduce reliance on expensive sensors and pre-built 3D maps while achieving accurate and reliable performance.
To overcome the limitations of traditional localisation methods, which often depend on costly survey-grade mapping vehicles, we propose a scalable alternative that leverages high-resolution satellite imagery as a global map. By aligning ground-view images from vehicle-mounted cameras with aerial views, we achieve accurate cross-view localisation using only visual inputs.
We introduce three novel localisation solutions:
(1) A visual-LiDAR hybrid method that uses 3D LiDAR points to establish correspondences between views, featuring a geometric-aligned feature extractor and iterative pose refinement.
(2) A purely visual method that detects view-consistent ground keypoints and exploits spatial camera constraints to suppress dynamic and seasonal noise.
(3) An enhanced visual method that aggregates off-ground aerial features onto ground-level pixels via orthogonal-view transformation, improving alignment and orientation estimation.
Beyond localisation, we tackle the challenge of occluded lane markings through a homography-guided temporal fusion module. By combining information from adjacent video frames with a surface-normal estimator, this approach improves lane segmentation under visual occlusions while remaining computationally efficient.
Together, these contributions form a robust visual perception framework. By reducing dependency on external sensors and pre-built maps, our methods enable autonomous systems to achieve accurate, reliable, and scalable perception in real-world conditions.
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