A Low-Cost Robotic Platform for Radiation Mapping

William Younger; Joshua Handley; Haori Yang

doi:10.53941/ic.2026.100001

Abstract

A low-cost robotic platform for radiation mapping has been developed by integrating a commercial off-the-shelf (COTS) radiation detector with a repurposed smart vacuum robot. The equipped reliable dosimeter can effectively measure radiation levels while the smart vacuum provides mobility and operational capabilities, enabling autonomous navigation in areas with potentially harmful radiation, minimizing the risk to human health. The low cost and ease of use of this platform can greatly improve accessibility to robotics technology. Potential applications of this robotic platform extend across various sectors, including routine survey of radiation level at nuclear and medical facilities, and radiation mapping during emergency response.

References

1.
White, S.R.; Megson-Smith, D.A.; Zhang, K.; et al. Radiation mapping and laser profiling using a robotic manipulator. Front. Robot. AI 2020, 7, 499056.
2.
Ryu, B.H.; Park, P.W.; Yu, E.S.; et al. A Study on Real-time Radiation Map Generation System that Combines LIDAR and Survey Meter. In Proceedings of the Transactions of the Korean Nuclear Society Spring Meeting, Jeju, Republic of Korea, 18–19 May 2023.
3.
Adams, J.; Cintas, B.; Sung, N.; Abrahao, A.; et al. A Behavioral Robotics Approach to Radiation Mapping Using Adaptive Sampling. Appl. Sci. 2025, 15, 2076–3417.
4.
Marques, L.; Vale, A.; Vaz, P. State-of-the-art mobile radiation detection systems for different scenarios. Sensors 2021, 21, 1051.
5.
Mascarich, F.; Kulkarni, M.; De Petris, P.; et al. Autonomous mapping and spectroscopic analysis of distributed radiation fields using aerial robots. Auton. Robot. 2023, 47, 139–160.
6.
Sato, Y.; Minemoto, K.; Nemoto, M.; et al. Automatic data acquisition for visualizing radioactive substances by combining a gamma-ray imager and an autonomous mobile robot. J. Instrum. 2021, 16, P01020.
7.
Lee, M.S.; Hanczor, M.; Chu, J.; et al. 3-D volumetric gamma-ray imaging and source localization with a mobile robot. arXiv 2018, arXiv:1802.06072.
8.
Groves, K.; Hernandez, E.; West, A.; et al. Robotic exploration of an unknown nuclear environment using radiation informed autonomous navigation. Robotics 2021, 10, 78.
9.
Martin, P.G.; Kwong, S.; Smith, N.T.; et al. 3D unmanned aerial vehicle radiation mapping for assessing contaminant distribution and mobility. Int. J. Appl. Earth Obs. Geoinf. 2016, 52, 12–19.
10.
Connor, D.; Martin, P.G.; Scott, T.B. Airborne radiation mapping: Overview and application of current and future aerial systems. Int. J. Remote Sens. 2016, 37, 5953–5987.
11.
Han, J.; Xu, Y.; Di, L.; et al. Low-cost multi-UAV technologies for contour mapping of nuclear radiation field. J. Intell. Robot. Syst. 2013, 70, 401–410.
12.
Christie, G.; Shoemaker, A.; Kochersberger, K.; et al. Radiation search operations using scene understanding with autonomous UAV and UGV. J. Field Robot. 2017, 34, 1450–1468.
13.
Woodbridge, E.; Connor, D.T.; Verbelen, Y.; et al. Airborne gamma-ray mapping using fixed-wing vertical take-off and landing (VTOL) uncrewed aerial vehicles. Front. Robot. AI 2023, 10, 1137763.
14.
Kunze, C.; Preugschat, B.; Arndt, R.; et al. Development of a UAV-based gamma spectrometry system for natural radionuclides and field tests at central Asian Uranium legacy sites. Remote Sens. 2022, 14, 2147.
15.
Katreiner, H.; Kovács, B.; Horváth, Á.; et al. Cost-effective drone survey of areas with elevated background radiation. Drones 2024, 9, 19.
16.
Tancioni, P.; Berger, P.; Chandra, R.; et al. Experimental Characterization of a Lightweight Unmanned Aerial Radiation Detection System equipped with a “Flat Panel” gamma detector. Available online: https://resources.inmm.org/sites/default/files/2023-07/finalpaper_244_0512091715.pdf (accessed on 14 January 2026).
17.
Lazna, T.; Gabrlik, P.; Jilek, T.; et al. Cooperation between an unmanned aerial vehicle and an unmanned ground vehicle in highly accurate localization of gamma radiation hotspots. Int. J. Adv. Robot. Syst. 2018, 15, 1729881417750787.
18.
Gabrlik, P.; Lazna, T.; Jilek, T.; et al. An automated heterogeneous robotic system for radiation surveys: Design and field testing. J. Field Robot. 2021, 38, 657–683.
19.
Chai, R.; Guo, Y.; Zuo, Z.; et al. Cooperative motion planning and control for aerial-ground autonomous systems: Methods and applications. Prog. Aerosp. Sci. 2024, 146, 101005.
20.
Munasinghe, I.; Perera, A.; Deo, R.C. A comprehensive review of uav-ugv collaboration: Advancements and challenges. J. Sens. Actuator Netw. 2024, 13, 81.
21.
Ding, Y.; Xin, B.; Chen, J. A review of recent advances in coordination between unmanned aerial and ground vehicles. Unmanned Syst. 2021, 9, 97–117.
22.
Baca, T.; Jilek, M.; Manek, P.; et al. Timepix radiation detector for autonomous radiation localization and mapping by micro unmanned vehicles. In Proceedings of the 2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Macau, China, 3–8 November 2019.
23.
Villaverde, I.; Urquiza, A.; Outón, J.L. A Reconfigurable UGV for Modular and Flexible Inspection Tasks in Nuclear Sites. Robotics 2024, 13, 110.
24.
Lazna, T. Optimizing the localization of gamma radiation point sources using a UGV. In Proceedings of the 2018 ELEKTRO, Mikulov, Czech Republic, 21–23 May 2018.
25.
Durukan, H.M. Simulation of Radiation Source Localization through Circle Approach and 3-D Visualization of Unknown Environment Using UGV Equipped with 3-D Lidar Based on Rotational 2-D Lidar. Ph.D. Thesis, Texas A&M University, College Station, TX, USA, 28 June 2021.
26.
Baca, T.; Stibinger, P.; Doubravova, D.; et al. Gamma radiation source localization for micro aerial vehicles with a miniature single-detector Compton event camera. In Proceedings of the 2021 International Conference on Unmanned Aircraft Systems (ICUAS), Athens, Greece, 15–18 June 2021.
27.
Roser, J.; Hueso-González, F.; Ros, A.; et al. Compton cameras and their applications. In Radiation Detection Systems; CRC Press: Boca Raton, FL, USA, 2021; pp. 161–198.
28.
Stolkin, R.; Molitor, N.; Berben, P.; et al. Status, barriers and cost-benefits of robotic and remote systems applications in nuclear decommissioning and radioactive waste management. no. NEA/RWM (2022). Available online: https://www.oecd-nea.org/jcms/pl_77051/status-barriers-and-cost-benefits-of-robotic-and-remote-systems-applications-in-nuclear-decommissioning-and-radioactive-waste-management?details=true (accessed on 14 January 2026).
29.
Chiou, M.; Epsimos, G.T.; Nikolaou, G.; et al. Robot-assisted nuclear disaster response: Report and insights from a field exercise. In Proceedings of the 2022 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Kyoto, Japan, 23–27 October 2022.
30.
Lopez Pulgarin, E.J.; Hopper, D.; Montgomerie, J.; et al. From traditional robotic deployments towards assisted robotic deployments in nuclear decommissioning. Front. Robot. AI 2025, 12, 1432845.
31.
Schwaiger, S.; Muster, L.; Novotny, G.; et al. UGV-CBRN: An Unmanned Ground Vehicle for Chemical, Biological, Radiological, and Nuclear Disaster Response. arXiv 2024, arXiv:2406.14385.
32.
Jones, H.; Maley, S.; Mousaei, M.; et al. A Robot for nondestructive assay of holdup deposits in gaseous diffusion piping. arXiv 2019, arXiv:1901.10341.

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