An Efficient Closed-Form Solution to Full Visual-Inertial State Initialization
Abstract
In this letter, we present a closed-form initialization method that recovers the full visual-inertial state without nonlinear optimization. Unlike previous approaches that rely on iterative solvers, our formulation yields analytical, easy-to-implement, and numerically stable solutions for reliable start-up. Our method builds on small-rotation and constant-velocity approximations, which keep the formulation compact while preserving the essential coupling between motion and inertial measurements. We further propose an observability-driven, two-stage initialization scheme that balances accuracy with initialization latency. Extensive experiments on the EuRoC dataset validate our assumptions: our method achieves 10-20% lower initialization error than optimization-based approaches, while using 4x shorter initialization windows and reducing computational cost by 5x.
Cite
@article{arxiv.2511.18910,
title = {An Efficient Closed-Form Solution to Full Visual-Inertial State Initialization},
author = {Samuel Cerezo and Seong Hun Lee and Javier Civera},
journal= {arXiv preprint arXiv:2511.18910},
year = {2026}
}
Comments
8 pages, 3 figures, 6 tables. Accepted to RA-L