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Main Authors: Lehyeh, Ayesh Abu, Zhang, Xiaohan, Arrabi, Ahmad, Sultani, Waqas, Chen, Chen, Wshah, Safwan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.21943
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author Lehyeh, Ayesh Abu
Zhang, Xiaohan
Arrabi, Ahmad
Sultani, Waqas
Chen, Chen
Wshah, Safwan
author_facet Lehyeh, Ayesh Abu
Zhang, Xiaohan
Arrabi, Ahmad
Sultani, Waqas
Chen, Chen
Wshah, Safwan
contents Accurate and fast localization is vital for safe autonomous navigation in GPS-denied areas. Fine-Grained Cross-View Geolocalization (FG-CVG) aims to estimate the precise 2-Degree-of-Freedom (2-DoF) location of a ground image relative to a satellite image. However, current methods force a difficult trade-off, with high-accuracy models being slow for real-time use. In this paper, we introduce GeoFlow, a new approach that offers a lightweight and highly efficient framework that breaks this accuracy-speed trade-off. Our technique learns a direct probabilistic mapping, predicting the displacement (in distance and direction) required to correct any given location hypothesis. This is complemented by our novel inference algorithm, Iterative Refinement Sampling (IRS). Instead of trusting a single prediction, IRS refines a population of hypotheses, allowing them to iteratively 'flow' from random starting points to a robust, converged consensus. Even its iterative nature, this approach offers flexible inference-time scaling, allowing a direct trade-off between performance and computation without any re-training. Experiments on the KITTI and VIGOR datasets show that GeoFlow achieves state-of-the-art efficiency, running at real-time speeds of 29 FPS while maintaining competitive localization accuracy. This work opens a new path for the development of practical real-time geolocalization systems.
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle GeoFlow: Real-Time Fine-Grained Cross-View Geolocalization via Iterative Flow Prediction
Lehyeh, Ayesh Abu
Zhang, Xiaohan
Arrabi, Ahmad
Sultani, Waqas
Chen, Chen
Wshah, Safwan
Computer Vision and Pattern Recognition
Accurate and fast localization is vital for safe autonomous navigation in GPS-denied areas. Fine-Grained Cross-View Geolocalization (FG-CVG) aims to estimate the precise 2-Degree-of-Freedom (2-DoF) location of a ground image relative to a satellite image. However, current methods force a difficult trade-off, with high-accuracy models being slow for real-time use. In this paper, we introduce GeoFlow, a new approach that offers a lightweight and highly efficient framework that breaks this accuracy-speed trade-off. Our technique learns a direct probabilistic mapping, predicting the displacement (in distance and direction) required to correct any given location hypothesis. This is complemented by our novel inference algorithm, Iterative Refinement Sampling (IRS). Instead of trusting a single prediction, IRS refines a population of hypotheses, allowing them to iteratively 'flow' from random starting points to a robust, converged consensus. Even its iterative nature, this approach offers flexible inference-time scaling, allowing a direct trade-off between performance and computation without any re-training. Experiments on the KITTI and VIGOR datasets show that GeoFlow achieves state-of-the-art efficiency, running at real-time speeds of 29 FPS while maintaining competitive localization accuracy. This work opens a new path for the development of practical real-time geolocalization systems.
title GeoFlow: Real-Time Fine-Grained Cross-View Geolocalization via Iterative Flow Prediction
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2603.21943