[Paper
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This work is an extension of "Visual Cross-View Metric Localization with Dense Uncertainty Estimates, ECCV2022"
Demo video of per-frame pose estimation on Oxford RobotCar traversals with different weather and lighting conditions
Pose estimation (localization + orientation estimation) on images with different horizontal field-of-view (HFoV). From left to right: HFoV=
We propose a novel end-to-end method for cross-view pose estimation. Given a ground-level query image and an aerial image that covers the query's local neighborhood, the 3 Degrees-of-Freedom camera pose of the query is estimated by matching its image descriptor to descriptors of local regions within the aerial image. The orientation-aware descriptors are obtained by using a translational equivariant convolutional ground image encoder and contrastive learning. The Localization Decoder produces a dense probability distribution in a coarse-to-fine manner with a novel Localization Matching Upsampling module. A smaller Orientation Decoder produces a vector field to condition the orientation estimate on the localization. Our method is validated on the VIGOR and KITTI datasets, where it surpasses the state-of-the-art baseline by 72% and 36% in median localization error for comparable orientation estimation accuracy. The predicted probability distribution can represent localization ambiguity, and enables rejecting possible erroneous predictions. Without re-training, the model can infer on ground images with different field of views and utilize orientation priors if available. On the Oxford RobotCar dataset, our method can reliably estimate the ego-vehicle's pose over time, achieving a median localization error under 1 meter and a median orientation error of around 1 degree at 14 FPS.
VIGOR dataset can be found at https://github.com/Jeff-Zilence/VIGOR.
We use the revised ground truth from https://github.com/tudelft-iv/SliceMatch
KITTI dataset can be found at https://github.com/shiyujiao/HighlyAccurate
For Oxford RobotCar, the aerial image is provided by https://github.com/tudelft-iv/CrossViewMetricLocalization, the ground images are from https://robotcar-dataset.robots.ox.ac.uk/datasets/
Our trained models are available at: https://surfdrive.surf.nl/files/index.php/s/cbyPn7NQoOOzlqp
Training or testing on VIGOR dataset:
samearea split: python train_VIGOR.py --area samearea
crossarea split: python train_VIGOR.py --area crossarea
For testing, add argument --training False
For testing with an orientation prior that contains up to --ori_noise 72
.
For testing with images with a limited HFoV, e.g. --FoV 180
Training on KITTI dataset: python train_KITTI.py
For testing, add argument --training False
For training or testing with an orientation prior, e.g. --rotation_range 10
We also provide the model trained with test_model_path
in train_KITTI.py
Training or testing on Oxford RobotCar dataset:
python train_OxfordRobotCar.py
or python train_OxfordRobotCar.py --training False
Visualize qualitative results on VIGOR same-area or cross-area test set:
python visualize_qualitative_results_VIGOR.py --area samearea --ori_prior 180 --idx 0
idx
: image index in VIGOR test set
ori_prior
:
@ARTICLE{10373898,
author={Xia, Zimin and Booij, Olaf and Kooij, Julian F. P.},
journal={IEEE Transactions on Pattern Analysis and Machine Intelligence},
title={Convolutional Cross-View Pose Estimation},
year={2024},
volume={46},
number={5},
pages={3813-3831},
keywords={Location awareness;Cameras;Pose estimation;Task analysis;Feature extraction;Image retrieval;Decoding;Aerial imagery;camera pose estimation;cross-view matching;localization;orientation estimation},
doi={10.1109/TPAMI.2023.3346924}}