Motion-aware 3D Gaussian Splatting for Efficient Dynamic Scene Reconstruction

Motion blur can significantly impact dynamic modeling using optical flow predictions by introducing inaccuracies in the motion estimation process. When there is motion blur in the input images, it can distort the appearance of objects and lead to errors in optical flow calculations. This distortion can result in incorrect or imprecise motion vectors being estimated, affecting the accuracy of dynamic scene reconstruction. In essence, motion blur acts as a noise factor that complicates the extraction of accurate motion information from image sequences.

Breaking through limitations of motion uncertainty in monocular scenes poses several challenges. One key challenge is dealing with ambiguities arising from limited visual cues available in monocular setups. Without multiple viewpoints for reference, accurately estimating complex 3D motions becomes more challenging due to inherent depth ambiguity and occlusions present in single-view scenarios. Additionally, variations in camera movements and scale changes further exacerbate uncertainties related to object motions within the scene.

To enhance dynamic scene reconstruction further, additional priors could be explored to provide supplementary information for improved modeling accuracy. Some potential avenues for exploring additional priors include leveraging semantic segmentation data to guide object boundaries and structures during reconstruction, incorporating temporal consistency constraints based on object dynamics over time, integrating physical constraints such as lighting conditions or material properties into the optimization process, and utilizing contextual cues from auxiliary sensors like IMU data for better understanding spatial relationships between objects within a scene.