Related papers: FastRSR: Efficient and Accurate Road Surface Reconstruction from Bird's Eye View

FastRSR: Efficient and Accurate Road Surface Reconstruction from Bird's Eye View

URL: http://arxiv.org/abs/2504.09535v1
Date: Sun, 13 Apr 2025 11:48:52 GMT
Title: FastRSR: Efficient and Accurate Road Surface Reconstruction from Bird's Eye View
Authors: Yuting Zhao, Yuheng Ji, Xiaoshuai Hao, Shuxiao Li,
Abstract summary: Road Surface Reconstruction is crucial for autonomous driving.<n>Current methods for transforming perspective views to Bird's Eye View (BEV) face challenges such as information loss and representation sparsity.<n>To address these challenges, we propose two efficient and accurate BEV-based RSR models.
Score: 1.4999444543328293
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Road Surface Reconstruction (RSR) is crucial for autonomous driving, enabling the understanding of road surface conditions. Recently, RSR from the Bird's Eye View (BEV) has gained attention for its potential to enhance performance. However, existing methods for transforming perspective views to BEV face challenges such as information loss and representation sparsity. Moreover, stereo matching in BEV is limited by the need to balance accuracy with inference speed. To address these challenges, we propose two efficient and accurate BEV-based RSR models: FastRSR-mono and FastRSR-stereo. Specifically, we first introduce Depth-Aware Projection (DAP), an efficient view transformation strategy designed to mitigate information loss and sparsity by querying depth and image features to aggregate BEV data within specific road surface regions using a pre-computed look-up table. To optimize accuracy and speed in stereo matching, we design the Spatial Attention Enhancement (SAE) and Confidence Attention Generation (CAG) modules. SAE adaptively highlights important regions, while CAG focuses on high-confidence predictions and filters out irrelevant information. FastRSR achieves state-of-the-art performance, exceeding monocular competitors by over 6.0% in elevation absolute error and providing at least a 3.0x speedup by stereo methods on the RSRD dataset. The source code will be released.

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