When Perspective Comes for Free: Improving Depth Prediction with Camera Pose Encoding.

Monocular depth prediction is a highly underdetermined problem and recent progress has relied on high-capacity CNNs to effectively learn scene statistics that disambiguate estimation. However, we observe that such models are strongly biased by the distribution of camera poses seen during training and fail to generalize to novel viewpoints, even when the scene geometry distribution remains fixed. To address this challenge, we propose a factored approach that estimates pose first, followed by a conditional depth estimation model that takes an encoding of the camera pose prior (CPP) as input. In many applications, a strong test-time pose prior comes for free, e.g., from inertial sensors or static camera deployment. A factored approach also allows for adapting pose prior estimation to new test domains using only pose supervision, without the need for collecting expensive ground-truth depth required for end-to-end training. We evaluate our pose-conditional depth predictor (trained on synthetic indoor scenes) on a real-world test set. Our factored approach, which only requires camera pose supervision for training, outperforms recent state-of-the-art methods trained with full scene depth supervision on 10x more data.