📝 SummarXiv

Abstract

Volume-based indoor scene reconstruction methods demonstrate significant research value due to their superior generalization capability and real-time deployment potential. However, existing methods rely on multi-view pixel back-projection ray intersections as weak geometric constraints to determine spatial positions, causing reconstruction quality to depend heavily on input view density with poor performance in overlapping regions and unobserved areas. To address these issues, the key lies in reducing dependency on inter-view geometric constraints while exploiting rich spatial information within individual views. We propose IPDRecon, an image-plane decoding framework comprising three core components: Pixel-level Confidence Encoder (PCE), Affine Compensation Module (ACM), and Image-Plane Spatial Decoder (IPSD). These modules collaboratively decode 3D structural information encoded in 2D images through physical imaging processes, effectively preserving spatial geometric features including edges, hollow structures, and complex textures while significantly enhancing view-invariant reconstruction. Experiments on ScanNetV2 confirm that IPDRecon achieves superior reconstruction stability, maintaining nearly identical quality when view count reduces by 40%. The method achieves a coefficient of variation of only 0.24%, performance retention rate of 99.7%, and maximum performance drop of merely 0.42%. This demonstrates that exploiting intra-view spatial information provides a robust solution for view-limited scenarios in practical applications.