Enhancing Monocular Height Estimation via Weak Supervision from Imperfect Labels

Monocular height estimation is considered the most efficient and cost-effective means of 3D perception in remote sensing, and it has attracted much attention since the emergence of deep learning. While training neural networks requires a large amount of data, data with perfect labels are scarce and only available within developed regions. The trained models therefore lack generalizability, which limits the potential for large-scale application of existing methods. We tackle this problem for the first time, by introducing data with imperfect labels into training pixel-wise height estimation networks, including labels that are incomplete, inexact, and inaccurate compared to high-quality labels. We propose an ensemble-based pipeline compatible with any monocular height estimation network. Taking the challenges of noisy labels, domain shift, and long-tailed distribution of height values into consideration, we carefully design the architecture and loss functions to leverage the information concealed in imperfect labels using weak supervision through balanced soft losses and ordinal constraints. We conduct extensive experiments on two datasets with different resolutions, DFC23 (0.5 to 1 m) and GBH (3 m). The results indicate that the proposed pipeline outperforms baselines by achieving more balanced performance across various domains, leading to improvements of average root mean square errors up to 22.94 %, and 18.62 % on DFC23 and GBH, respectively. The efficacy of each design component is validated through ablation studies. Code is available at https://github.com/zhu-xlab/weakim2h.