User:Oracle96/The Leo Rover

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 – a small-sized, four-wheeled, open-source robotic platform manufactured and developed in Wrocław, Poland, by fictionlab sp. z o.o. (Polish equivalent of LLC).^[1] Originally introduced to the market in 2017 under the name „Turtle”, it was later rebranded as „Leo Rover”.^[2][3]

Design and performance

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.^[4]

Mounting holes on top of the Leo Rover's chassis

Software

The Leo Rover runs on Ubuntu 20.04 with ROS Noetic Ninjammys, and a Raspberry Pi 4 as its main computer.

European Rover Challenge

From 2020 to 2022, the Leo Rover served as the standard robot used in the remote formula of the European Rover Challenge.^[5][6]

Application area

The Leo Rover is predominantly used as a development platform for individuals and organizations to implement their own technological solutions by the connection of external electronics, modification of the open-source software, and adjustments to the robot's design. The primary consumers of this product are universities and research facilities, employing the robot for various projects and research purposes.^{[7][8][9][10][11][12][13][14][15]}

References

[[Category:Electronics]] [[Category:Technology]] [[Category:Robotics]] [[Category:Planetary rovers]]

1. "Leo Rover - Crunchbase Company Profile & Funding". Crunchbase. Retrieved 2023-08-14.
2. Julia Liszniańska, "Turtle Rover – najpierw łaziki marsjańskie, a teraz… ziemskie!", AstroNET – Polski Portal Astronomiczny (in Polish)
3. "Łaziki marsjańskie i ich współkonstruktor – Szymon Dzwończyk". {{cite episode}}: Missing or empty |series= (help)
4. "Robots/LeoRover - ROS Wiki". wiki.ros.org. Retrieved 2023-08-14.
5. Mateusz Bogusz (2021-11-19), "Mars Yard from the perspective of Leo Rover –", roverchallenge.eu
6. "Bohater konkursu łazików marsjańskich. Nie jest szybki, ale wiele potrafi. I trudno go zatrzymać...", www.rmf24.pl (in Polish)
7. "Research - Hunt Lab". 2021-10-14. Retrieved 2023-08-14.
8. "Home". Botronics. Retrieved 2023-08-14.
9. "Leo Rover in the ISM". SnT FR (in French). Retrieved 2023-08-14.
10. 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.
11. Seedhouse, Erik L.; Lianos, Pedro J. (9 July 2021). [353550517_Science_and_exploration_of_the_moon_enabled_by_surface_telerobotics "Science and exploration of the moon enabled by surface telerobotics"]. Journal of Space Safety Engineering. 8 (1). doi:10.1016/j.jsse.2021.07.002. {{cite journal}}: Check |url= value (help)
12. "ShieldSquare Captcha". hcvalidate.perfdrive.com. doi:10.1088/1361-6498/abd074. Retrieved 2023-08-14.
13. 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–e139205.
14. Lim, Yujin; Anthyme, Bahati Pierre; Le, Viet Dinh (November 25, 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.
15. Karalekas, Georgios; Vologiannidis, Stavros; Kalomiros, John (April 27, 2020). "A Case Study for Teaching Sensors, Data Acquisition and Robotics via a ROS-Based Educational Robot". Sensors (Basel). 20 (9). doi:10.3390/s20092469.