Vanishing Point Aided Hash-Frequency Encoding for Neural Radiance Fields (NeRF) from Sparse 360 Input

Neural Radiance Fields (NeRF) enable novel view synthesis of 3D scenes when trained with a set of 2D images. One of the key components of NeRF is the input encoding, i.e. mapping the coordinates to higher dimensions to learn high-frequency details, which has been proven to increase the quality. Among various input mappings, hash encoding is gaining increasing attention for its efficiency. However, its performance on sparse inputs is limited. To address this limitation, we propose a new input encoding scheme that improves hash-based NeRF for sparse inputs, i.e. few and distant cameras, specifically for 360 degrees view synthesis. In this paper, we combine frequency encoding and hash encoding and show that this combination can increase dramatically the quality of hash-based NeRF for sparse inputs. Additionally, we explore scene geometry by estimating vanishing points in omnidirectional images (ODI) of indoor and city scenes in order to align frequency encoding with scene structures. We demonstrate that our vanishing point-aided scene alignment further improves deterministic and non-deterministic encodings on image regression and NeRF tasks where sharper textures and more accurate geometry of scene structures can be reconstructed.