Your search keyword '"Kourosh Khoshelham"' showing total 4 results

1. Pose-aware monocular localization of occluded pedestrians in 3D scene space

Author

Mohammad Masoud Rahimi, Kourosh Khoshelham, Mark Stevenson, and Stephan Winter

Subjects

Pedestrian localization, Human pose estimation, Occluded pedestrians modelling, Geography (General), G1-922, Surveying, TA501-625

Abstract

Localization of pedestrians in 3D scene space from single RGB images is critical for various downstream applications. Current monocular approaches employ either the bounding box of pedestrians or the visible parts of their bodies for localization. Both approaches introduce additional error to the location estimation in the case of real-world scenarios – crowded environments with multiple occluded pedestrians. To overcome the limitation, this paper proposes a novel human pose-aware pedestrian localization framework to model poses of occluded pedestrians, where this enables accurate localization in image and ground space. This is done by proposing a light-weight neural network architecture, where this ensures a fast and accurate prediction of missing body parts for downstream applications. Comprehensive experiments on two real-world datasets demonstrate the effectiveness of the framework compared to state-of-the-art in predicting pedestrians missing body parts as well as pedestrian localization.

Published

2021

2. Results of the ISPRS benchmark on indoor modelling

Author

Kourosh Khoshelham, Ha Tran, Debaditya Acharya, Lucia Díaz Vilariño, Zhizhong Kang, and Sagi Dalyot

Subjects

Indoor modelling, Reconstruction, Point Cloud, Building Information Model, Scan-to-BIM, Geography (General), G1-922, Surveying, TA501-625

Abstract

This paper reports the results of the ISPRS benchmark on indoor modelling. Reconstructed models submitted by 11 participating teams are evaluated on a dataset comprising 6 point clouds representing indoor environments of different complexity. The evaluation is based on measuring the completeness, correctness, and accuracy of the reconstructed wall elements through comparison with manually generated reference models. The results show that the performance of the methods varies across different datasets, but generally the reconstruction methods achieve better results for the point clouds with higher accuracy and density and fewer gaps, as well as the point clouds representing less complex environments. Filtering clutter points in a pre-processing step contributes to higher correctness, and making strong assumptions on the shape of the reconstructed elements contributes to higher completeness and accuracy for models of Manhattan World environments.

Published

2021

3. Results of the ISPRS benchmark on indoor modelling

Author

Zhizhong Kang, Kourosh Khoshelham, H. Tran, Lucia Díaz Vilariño, Debaditya Acharya, and Sagi Dalyot

Subjects

Geography (General), Correctness, TA501-625, Computer science, Point cloud, Surveying, computer.software_genre, Reconstruction method, Indoor modelling, Completeness (order theory), Point Cloud, Scan-to-BIM, Benchmark (computing), Clutter, G1-922, Data mining, Building Information Model, Reconstruction, Reference model, computer

Abstract

This paper reports the results of the ISPRS benchmark on indoor modelling. Reconstructed models submitted by 11 participating teams are evaluated on a dataset comprising 6 point clouds representing indoor environments of different complexity. The evaluation is based on measuring the completeness, correctness, and accuracy of the reconstructed wall elements through comparison with manually generated reference models. The results show that the performance of the methods varies across different datasets, but generally the reconstruction methods achieve better results for the point clouds with higher accuracy and density and fewer gaps, as well as the point clouds representing less complex environments. Filtering clutter points in a pre-processing step contributes to higher correctness, and making strong assumptions on the shape of the reconstructed elements contributes to higher completeness and accuracy for models of Manhattan World environments.

Published

2021

4. Pose-aware monocular localization of occluded pedestrians in 3D scene space

Author

Mark Stevenson, Stephan Winter, M. M. Rahimi, and Kourosh Khoshelham

Subjects

Geography (General), Monocular, TA501-625, business.industry, Computer science, Human pose estimation, Occluded pedestrians modelling, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Surveying, Pedestrian, Space (commercial competition), Minimum bounding box, Neural network architecture, RGB color model, G1-922, Computer vision, Artificial intelligence, business, Pedestrian localization, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

Localization of pedestrians in 3D scene space from single RGB images is critical for various downstream applications. Current monocular approaches employ either the bounding box of pedestrians or the visible parts of their bodies for localization. Both approaches introduce additional error to the location estimation in the case of real-world scenarios – crowded environments with multiple occluded pedestrians. To overcome the limitation, this paper proposes a novel human pose-aware pedestrian localization framework to model poses of occluded pedestrians, where this enables accurate localization in image and ground space. This is done by proposing a light-weight neural network architecture, where this ensures a fast and accurate prediction of missing body parts for downstream applications. Comprehensive experiments on two real-world datasets demonstrate the effectiveness of the framework compared to state-of-the-art in predicting pedestrians missing body parts as well as pedestrian localization.

Published

2021