InfiniTAM v3: A Framework for Large-Scale 3D Reconstruction with Loop Closure

TL;DR

InfiniTAM v3 introduces a flexible, scalable framework for large-scale 3D reconstruction that integrates loop closure, robust camera tracking, and multiple reconstruction methods, enhancing accuracy and applicability in real-world scenarios.

Contribution

The paper presents InfiniTAM v3, a unified framework enabling flexible large-scale 3D reconstruction with loop closure and multiple scene representation techniques.

Findings

Enhanced camera tracking performance

Implementation of loop closure via scene submaps

Support for various reconstruction approaches

Abstract

Volumetric models have become a popular representation for 3D scenes in recent years. One breakthrough leading to their popularity was KinectFusion, which focuses on 3D reconstruction using RGB-D sensors. However, monocular SLAM has since also been tackled with very similar approaches. Representing the reconstruction volumetrically as a TSDF leads to most of the simplicity and efficiency that can be achieved with GPU implementations of these systems. However, this representation is memory-intensive and limits applicability to small-scale reconstructions. Several avenues have been explored to overcome this. With the aim of summarizing them and providing for a fast, flexible 3D reconstruction pipeline, we propose a new, unifying framework called InfiniTAM. The idea is that steps like camera tracking, scene representation and integration of new data can easily be replaced and adapted to the user's needs. This report describes the technical implementation details of InfiniTAM v3, the third version of our InfiniTAM system. We have added various new features, as well as making numerous enhancements to the low-level code that significantly improve our camera tracking performance. The new features that we expect to be of most interest are (i) a robust camera tracking module; (ii) an implementation of Glocker et al.'s keyframe-based random ferns camera relocaliser; (iii) a novel approach to globally-consistent TSDF-based reconstruction, based on dividing the scene into rigid submaps and optimising the relative poses between them; and (iv) an implementation of Keller et al.'s surfel-based reconstruction approach.