Leo Rover
Developer | fictionlab sp. z o.o. |
---|---|
Release date | 2017 |
Operating system | Ubuntu 20.04 + ROS Noetic Ninjammys |
CPU | Quad core Cortex-A72 |
Dimensions | 447 x 433 x 249 mm |
Mass | 6.5 kg |
Website | https://www.leorover.tech |
Leo Rover is a small-sized, four-wheeled, open-source robotic platform manufactured and developed in Wrocław, Poland, by fictionlab sp. z o.o.
Design and performance
[edit]The Leo Rover is a small, remotely controlled, four-wheeled rover, measuring 433 mm in length, 447 mm in width, and 249 mm in height. It weighs 6.5 kg and features in-hub DC motors with a 73.2:1 planetary gearbox and 12 CPR encoder to power each wheel. The wheels are made of rubber with foam inserts. The robot is equipped with a 5000 mAh Li-ion battery of 11.1 V DC. It can achieve a maximum linear speed of approximately 0.4 m/s and an angular speed of up to 60 deg/s. The front of the robot's body houses a 5 MPx camera with a 170-degree field of view. The rover's top surface features numerous mounting holes to attach additional hardware, and it has a nominal payload capacity of 5 kg.
The robot is equipped with a 2.4 GHz WiFi access point with an external antenna. The majority of the robot's structural components are 3D-printed, resulting in a watertight design rated at the IP64 level.[1]
Software
[edit]The Leo Rover runs on Ubuntu Linux 20.04 with ROS Noetic Ninjammys, and a Raspberry Pi 4 as its main computer.
European Rover Challenge
[edit]From 2020 to 2022, the Leo Rover was the standard robot used in the remote formula of the European Rover Challenge.
Application area
[edit]Leo Rover serves as a development platform for implementing one’s own technological solutions by connecting external electronics, editing the open-source software, or modifying the robot’s design. Although the product is available to both individuals and companies, the majority of the consumers are universities and research facilities that use the robot for their projects and research.[2][3][4][5][6][7][8][9][10]
References
[edit]- ^ "Robots/Leo Rover - ROS Wiki". wiki.ros.org. Retrieved 2023-07-26.
- ^ "Research - Hunt Lab". 2021-10-14. Retrieved 2023-08-14.
- ^ "Home". Botronics. Retrieved 2023-08-14.
- ^ "Leo Rover in the ISM". SnT FR (in French). Retrieved 2023-08-14.
- ^ Western, Nathan; Kong, Xianwen; Erden, Mustafa Suphi (2021-06-02). "Design of a Train Cleaning Robot for the Train Carriage Interior: 31st CIRP Design Conference 2021". Procedia CIRP. 100: 804–809. doi:10.1016/j.procir.2021.05.040. ISSN 2212-8271.
- ^ Seedhouse, Erik L.; Llanos, Pedro J. (July 9, 2021). "Science and exploration of the moon enabled by surface telerobotics". Journal of Space Safety Engineering. 8 (1): 231–237. Bibcode:2021JSSE....8..231S. doi:10.1016/j.jsse.2021.07.002.
- ^ Banos, A; Hayman, J; Wallace-Smith, T; Bird, B; Lennox, B; Scott, T B (2021-06-01). "An assessment of contamination pickup on ground robotic vehicles for nuclear surveying application". Journal of Radiological Protection. 41 (2): 179–196. doi:10.1088/1361-6498/abd074. ISSN 0952-4746. PMID 33271518.
- ^ Jaskot, Anna; Posiadała, Bogdan (2021). "Experimental studies and modeling of four-wheeled mobile robot motion taking into account wheel slippage". Bulletin of the Polish Academy of Sciences Technical Sciences: e139205. doi:10.24425/bpasts.2021.139205.
- ^ Lim, Yujin; Le, Viet Dinh; Anthyme, Bahati Pierre (November 2021). "Development of a New Pressure-Sinkage Model for Rover Wheel- Lunar Soil Interaction based on Dimensional Analysis and Bevameter Tests". Journal of Astronomy and Space Science. 38 (4): 237–250. doi:10.5140/JASS.2021.38.4.237.
- ^ Karalekas, Georgios; Vologiannidis, Stavros; Kalomiros, John (January 2020). "EUROPA: A Case Study for Teaching Sensors, Data Acquisition and Robotics via a ROS-Based Educational Robot". Sensors. 20 (9): 2469. Bibcode:2020Senso..20.2469K. doi:10.3390/s20092469. ISSN 1424-8220. PMC 7248833. PMID 32349247.