Search

Your search keyword '"Dimitrios Chatziparaschis"' showing total 7 results
Start Over Author "Dimitrios Chatziparaschis"
7 results on '"Dimitrios Chatziparaschis"'

1. Aerial and Ground Robot Collaboration for Autonomous Mapping in Search and Rescue Missions

Author

Dimitrios Chatziparaschis, Michail G. Lagoudakis, and Panagiotis Partsinevelos

Subjects
unmanned aerial vehicles (UAV), humanoid robot, Search and Rescue (SAR), robot operating system (ROS), stereo imaging, simultaneous localization and mapping (SLAM), Motor vehicles. Aeronautics. Astronautics, TL1-4050
Abstract

Humanitarian Crisis scenarios typically require immediate rescue intervention. In many cases, the conditions at a scene may be prohibitive for human rescuers to provide instant aid, because of hazardous, unexpected, and human threatening situations. These scenarios are ideal for autonomous mobile robot systems to assist in searching and even rescuing individuals. In this study, we present a synchronous ground-aerial robot collaboration approach, under which an Unmanned Aerial Vehicle (UAV) and a humanoid robot solve a Search and Rescue scenario locally, without the aid of a commonly used Global Navigation Satellite System (GNSS). Specifically, the UAV uses a combination of Simultaneous Localization and Mapping and OctoMap approaches to extract a 2.5D occupancy grid map of the unknown area in relation to the humanoid robot. The humanoid robot receives a goal position in the created map and executes a path planning algorithm in order to estimate the FootStep navigation trajectory for reaching the goal. As the humanoid robot navigates, it localizes itself in the map while using an adaptive Monte-Carlo Localization algorithm by combining local odometry data with sensor observations from the UAV. Finally, the humanoid robot performs visual human body detection while using camera data through a Darknet pre-trained neural network. The proposed robot collaboration scheme has been tested under a proof of concept setting in an exterior GNSS-denied environment.

Published
2020
Full Text
View/download PDF

2. A Novel UAV-Assisted Positioning System for GNSS-Denied Environments

Author

Panagiotis Partsinevelos, Dimitrios Chatziparaschis, Dimitrios Trigkakis, and Achilleas Tripolitsiotis

Subjects
GNSS, UAS, obstructed environment, accuracy, GPS-denied areas, automatic surveying, Science
Abstract

Global Navigation Satellite Systems (GNSS) are extensively used for location-based services, civil and military applications, precise time reference, atmosphere sensing, and other applications. In surveying and mapping applications, GNSS provides precise three-dimensional positioning all over the globe, day and night, under almost any weather conditions. The visibility of the ground receiver to GNSS satellites constitutes the main driver of accuracy for GNSS positioning. When this visibility is obstructed by buildings, high vegetation, or steep slopes, the accuracy is degraded and alternative techniques have to be assumed. In this study, a novel concept of using an unmanned aerial system (UAS) as an intermediate means for improving the accuracy of ground positioning in GNSS-denied environments is presented. The higher elevation of the UAS provides a clear-sky visibility line towards the GNSS satellites, thus its accuracy is significantly enhanced with respect to the ground GNSS receiver. Thus, the main endeavor is to transfer the order of accuracy of the GNSS on-board the UAS to the ground. The general architecture of the proposed system includes hardware and software components (i.e., camera, gimbal, range finder) for the automation of the procedure. The integration of the coordinate systems for each payload setting is described, while an error budget analysis is carried out to evaluate and identify the system’s critical elements along with the potential of the proposed method.

Published
2020
Full Text
View/download PDF

6. A Novel UAV-Assisted Positioning System for GNSS-Denied Environments

Author

Dimitrios Trigkakis, Achilleas Tripolitsiotis, Dimitrios Chatziparaschis, and Panagiotis Partsinevelos

Subjects
010504 meteorology & atmospheric sciences, Positioning system, Computer science, Science, Real-time computing, Gimbal, 01 natural sciences, Global Navigation Satellite Systems (GNSS), GPS-denied areas, 0502 economics and business, Visibility, Accuracy, 0105 earth and related environmental sciences, automatic surveying, Obstructed environment, 050210 logistics & transportation, Automatic surveying, GNSS, accuracy, Payload, business.industry, Global Position System (GPS)-denied areas, 05 social sciences, Elevation, Automation, GNSS applications, Unmanned aerial system (UAS), General Earth and Planetary Sciences, Satellite, obstructed environment, UAS, business
Abstract

Summarization: Global Navigation Satellite Systems (GNSS) are extensively used for location-based services, civil and military applications, precise time reference, atmosphere sensing, and other applications. In surveying and mapping applications, GNSS provides precise three-dimensional positioning all over the globe, day and night, under almost any weather conditions. The visibility of the ground receiver to GNSS satellites constitutes the main driver of accuracy for GNSS positioning. When this visibility is obstructed by buildings, high vegetation, or steep slopes, the accuracy is degraded and alternative techniques have to be assumed. In this study, a novel concept of using an unmanned aerial system (UAS) as an intermediate means for improving the accuracy of ground positioning in GNSS-denied environments is presented. The higher elevation of the UAS provides a clear-sky visibility line towards the GNSS satellites, thus its accuracy is significantly enhanced with respect to the ground GNSS receiver. Thus, the main endeavor is to transfer the order of accuracy of the GNSS on-board the UAS to the ground. The general architecture of the proposed system includes hardware and software components (i.e., camera, gimbal, range finder) for the automation of the procedure. The integration of the coordinate systems for each payload setting is described, while an error budget analysis is carried out to evaluate and identify the system’s critical elements along with the potential of the proposed method. Presented on

Published
2020

7. Aerial and Ground Robot Collaboration for Autonomous Mapping in Search and Rescue Missions

Author

Michail G. Lagoudakis, Dimitrios Chatziparaschis, and Panagiotis Partsinevelos

Subjects
0209 industrial biotechnology, Occupancy grid mapping, simultaneous localization and mapping (SLAM), Computer science, lcsh:Motor vehicles. Aeronautics. Astronautics, Aerospace Engineering, Humanoid robot, 02 engineering and technology, Unmanned aerial vehicles (UAV), Simultaneous localization and mapping, Stereo imaging, unmanned aerial vehicles (UAV), 020901 industrial engineering & automation, Odometry, Artificial Intelligence, Simultaneous localization and mapping (SLAM), 0202 electrical engineering, electronic engineering, information engineering, robotic cooperation, Computer vision, Motion planning, path planning, Path planning, Search and rescue, humanoid robot, business.industry, Mobile robot, Robot operating system (ROS), robot operating system (ROS), Computer Science Applications, Robotic cooperation, Control and Systems Engineering, stereo imaging, Robot, Search and Rescue (SAR), 020201 artificial intelligence & image processing, Artificial intelligence, lcsh:TL1-4050, business, Information Systems
Abstract

Summarization: Humanitarian Crisis scenarios typically require immediate rescue intervention. In many cases, the conditions at a scene may be prohibitive for human rescuers to provide instant aid, because of hazardous, unexpected, and human threatening situations. These scenarios are ideal for autonomous mobile robot systems to assist in searching and even rescuing individuals. In this study, we present a synchronous ground-aerial robot collaboration approach, under which an Unmanned Aerial Vehicle (UAV) and a humanoid robot solve a Search and Rescue scenario locally, without the aid of a commonly used Global Navigation Satellite System (GNSS). Specifically, the UAV uses a combination of Simultaneous Localization and Mapping and OctoMap approaches to extract a 2.5D occupancy grid map of the unknown area in relation to the humanoid robot. The humanoid robot receives a goal position in the created map and executes a path planning algorithm in order to estimate the FootStep navigation trajectory for reaching the goal. As the humanoid robot navigates, it localizes itself in the map while using an adaptive Monte-Carlo Localization algorithm by combining local odometry data with sensor observations from the UAV. Finally, the humanoid robot performs visual human body detection while using camera data through a Darknet pre-trained neural network. The proposed robot collaboration scheme has been tested under a proof of concept setting in an exterior GNSS-denied environment. Presented on: Drones

Published
2020

Catalog

Books, media, physical & digital resources
See catalog results