Virtual radioactive source system for exercises modeling high doses

1. ENEA. (2023). INCLUDING EU project. Retrieved June 02, 2023, from https://www.including-h2020. eu/about.html. ENEA . ( 2023 ). INCLUDING EU project . Retrieved June 02, 2023, from https://www.including-h2020.eu/about.html . Search in Google Scholar

2. Kovács-Széles, É., Almási, I., Balaskó, Á., Bíró, Cs., Bodor, K., Csöme, Cs., Kakuja, I., Kreitz, Zs., Papp, K., Tóbi, Cs., & Volarics, J. (2020). How to respond to a crime scene contaminated with radioactive material? Belügyi Szemle, 68, 34–51. https://doi.org/10.38146/BSZ.SPEC.2020.3.3. (In Hungarian). Kovács-Széles É. Almási I. Balaskó Á. Bíró Cs. Bodor K. Csöme Cs. Kakuja I. Kreitz Zs. Papp K. Tóbi Cs. Volarics J. ( 2020 ). How to respond to a crime scene contaminated with radioactive material? Belügyi Szemle , 68 , 34 – 51 https://doi.org/10.38146/BSZ.SPEC.2020.3.3 . (In Hungarian). Search in Google Scholar

3. IFE-Institute for Energy Technology. (2020). HVRC VRdose code [computer software]. Retrieved June 03, 2023, from https://ife.no/en/service/hvrc-vrdose/. IFE-Institute for Energy Technology . ( 2020 ). HVRC VRdose code [computer software] . Retrieved June 03, 2023, from https://ife.no/en/service/hvrc-vrdose/ . Search in Google Scholar

4. Ji, Y., Wang, X., Zou, Y., Li, D., Zhang, Y., & Ning, J. (2022). A simulation system of radiation field and its detection for nuclear and radiological emergency preparedness and response training. J. Radiol. Prot., 42, 021526. https://iopscience.iop.org/article/10.1088/1361-6498/ac7361/pdf. Ji Y. Wang X. Zou Y. Li D. Zhang Y Ning J. ( 2022 ). A simulation system of radiation field and its detection for nuclear and radiological emergency preparedness and response training . J. Radiol. Prot ., 42 , 021526 . https://iopscience.iop.org/article/10.1088/1361-6498/ac7361/pdf . Search in Google Scholar

5. Szőke, A., Louka, N. M., Bryntesen, R. T., Bratteli, J., Edvardsen, T. S., RoEitrheim, K. K., & Bodor, K. (2014). Real-time 3D radiation risk assessment supporting simulation of work in nuclear environments. J. Radiol. Prot., 34(2), 389–416. DOI: 10.1088/09524746/34/2/389. Szőke A. Louka N. M. Bryntesen R. T. Bratteli J. Edvardsen T. S. RoEitrheim K. K. Bodor K. ( 2014 ). Real-time 3D radiation risk assessment supporting simulation of work in nuclear environments . J. Radiol. Prot ., 34 ( 2 ), 389 – 416 DOI: 10.1088/09524746/34/2/389 . Open DOISearch in Google Scholar

6. Marques, L., Vale, A., & Vaz, P. (2021). State-of-the-art mobile radiation detection systems for different scenarios. Sensors, 21, 1051. https://doi.org/10.3390/s21041051. Marques L. Vale A. Vaz P. ( 2021 ). State-of-the-art mobile radiation detection systems for different scenarios . Sensors , 21 , 1051 . https://doi.org/10.3390/s21041051 . Search in Google Scholar

7. Kumar, A. K. P., Sundaram, S. G. A., Sharma, B. K., Venkatesh, S., & Thiruvengadathan, R. (2020). Advances in gamma radiation detection systems for emergency radiation monitoring. Nucl. Eng. Technol., 52, 2151–2161. https://doi.org/10.1016/j.net.2020.03.014. Kumar A. K. P. Sundaram S. G. A. Sharma B. K. Venkatesh S. Thiruvengadathan R. ( 2020 ). Advances in gamma radiation detection systems for emergency radiation monitoring . Nucl. Eng. Technol ., 52 , 2151 – 2161 https://doi.org/10.1016/j.net.2020.03.014 . Search in Google Scholar

8. Ihantola, S., Tengblad, O., Toivonen, H., Csome, C., Borg, J., Paepen, J., Tagziria, H., & Gattinesi, P. (2018). European Reference Network for Critical Infrastructure Protection: Novel detection technologies for nuclear security. Luxembourg: Publications Office of the European Union. Retrieved October 13, 2020, from https://publications.jrc.ec.europa.eu/repository/handle/JRC112304. Ihantola S. Tengblad O. Toivonen H. Csome C. Borg J. Paepen J. Tagziria H. Gattinesi P. ( 2018 ). European Reference Network for Critical Infrastructure Protection: Novel detection technologies for nuclear security . Luxembourg : Publications Office of the European Union . Retrieved October 13, 2020, from https://publications.jrc.ec.europa.eu/repository/handle/JRC112304 . Search in Google Scholar

9. Passos, A. C., Mól, A. C. A., Carvalho, P. V. R., Lima, F. A., & Rocha, T. L. (2015). Use of virtual simulator for agent training in radiation protection actions in major events. In International Nuclear Atlantic Conference (INAC), October 4–9, 2015, Sao Paulo, Brasil. Retrieved January 10, 2022, from https://core.ac.uk/download/pdf/159274409.pdf. Passos A. C. Mól A. C. A. Carvalho P. V. R. Lima F. A. Rocha T. L. ( 2015 ). Use of virtual simulator for agent training in radiation protection actions in major events . In International Nuclear Atlantic Conference (INAC), October 4–9, 2015 , Sao Paulo, Brasil . Retrieved January 10, 2022, from https://core.ac.uk/download/pdf/159274409.pdf . Search in Google Scholar

10. Hungarian Atomic Energy Authority. (2022). Government decree on protection against ionizing radiation and the related licensing, reporting and control system. 2/2022. (IV. 29). Budapest. Retrieved June 07, 2023, from https://net.jogtar.hu/jogszabaly?docid=A2200002.OAH&txtreferer=00000001.txt. Hungarian Atomic Energy Authority . ( 2022 ). Government decree on protection against ionizing radiation and the related licensing, reporting and control system . 2/2022. (IV. 29). Budapest. Retrieved June 07, 2023, from https://net.jogtar.hu/jogszabaly?docid=A2200002.OAH&txtreferer=00000001.txt . Search in Google Scholar

11. Hungarian Atomic Energy Authority. (2015). Government decree on notifications and measures related to missing, found and seized nuclear and other radioactive materials, as well as other measures following notification related to nuclear and other radioactive materials. 490/2015. (XII. 30). Budapest. Retrieved June 21, 2023, from https://net.jogtar.hu/jogszabaly?docid=a1500490.kor. Hungarian Atomic Energy Authority . ( 2015 ). Government decree on notifications and measures related to missing, found and seized nuclear and other radioactive materials, as well as other measures following notification related to nuclear and other radioactive materials . 490/2015. (XII. 30). Budapest. Retrieved June 21, 2023, from https://net.jogtar.hu/jogszabaly?docid=a1500490.kor . Search in Google Scholar

12. Bodor, K., & Zagyvai, P. (2022). Lost radioactive source exploration training capabilities at the Centre for Energy Research (EK). Safety and Security Sciences Review, 4 (4), 81–96. https://biztonsagtudomanyi.szemle.uni-obuda.hu/index.php/home/article/view/252/228. Bodor K. Zagyvai P. ( 2022 ). Lost radioactive source exploration training capabilities at the Centre for Energy Research (EK) . Safety and Security Sciences Review , 4 ( 4 ), 81 – 96 https://biztonsagtudomanyi.szemle.uni-obuda.hu/index.php/home/article/view/252/228 . Search in Google Scholar

13. Hungarian Government. (2011). Government decree on physical protection in the application of nuclear energy and the related licensing, reporting and control system. 190/2011. (IX. 19). Budapest. Retrieved June 07, 2023, from https://net.jogtar.hu/jogszabaly?docid=a1100190.kor. Hungarian Government . ( 2011 ). Government decree on physical protection in the application of nuclear energy and the related licensing, reporting and control system . 190/2011. (IX. 19). Budapest. Retrieved June 07, 2023, from https://net.jogtar.hu/jogszabaly?docid=a1100190.kor . Search in Google Scholar

14. Speicher, M., Hall, B. D., & Nebeling, M. (2019). What is mixed reality? In Proceedings of the 2019 CHI Conference on Human Factors in Computing Systems. https://doi.org/10.1145/3290605.3300767. Speicher M. Hall B. D. Nebeling M. ( 2019 ). What is mixed reality? In Proceedings of the 2019 CHI Conference on Human Factors in Computing Systems . https://doi.org/10.1145/3290605.3300767 . Search in Google Scholar

15. Milgram, P., Takemura, H., Utsumi, A., & Kishino, F. (1995). Augmented reality: A class of displays on the reality-virtuality continuum. Proc. SPIE, 2351, 282–292. https://doi.org/10.1117/12.197321. Milgram P. Takemura H. Utsumi A. Kishino F. ( 1995 ). Augmented reality: A class of displays on the reality-virtuality continuum . Proc. SPIE , 2351 , 282 – 292 https://doi.org/10.1117/12.197321 . Search in Google Scholar

16. Dunston, P., Wang, X., Billinghurst, M., & Hampson, B. (2002). Mixed reality benefits for design perception. In Proceedings of the 19th International Symposium on Automation and Robotics in Construction. http://www.iaarc.org/publications/proceedings_of_the_19th_isarc/mixed_reality_benefits_for_design_perception.html, https://doi.org/10.22260/isarc2002/0030. Dunston P. Wang X. Billinghurst M. Hampson B. ( 2002 ). Mixed reality benefits for design perception . In Proceedings of the 19th International Symposium on Automation and Robotics in Construction . http://www.iaarc.org/publications/proceedings_of_the_19th_isarc/mixed_reality_benefits_for_design_perception.html , https://doi.org/10.22260/isarc2002/0030 . Search in Google Scholar

17. Lee, D., Lee, B. I., Park, Y., & Kim, D. (2018). Application plan for radiological exposure model using virtual reality-based radiological exercise system. Nucl. Eng. Technol., 50, 745–750. https://doi.org/10.1016/j.net.2018.03.009. Lee D. Lee B. I. Park Y. Kim D. ( 2018 ). Application plan for radiological exposure model using virtual reality-based radiological exercise system . Nucl. Eng. Technol ., 50 , 745 – 750 https://doi.org/10.1016/j.net.2018.03.009 . Search in Google Scholar

18. Sato, Y., Minemoto, K., Nemoto, M., & Torii, T. (2020). Construction of virtual reality system for radiation working environment reproduced by gamma-ray imagers combined with SLAM technologies. Nucl. Instrum. Methods Phys. Res. Sect. A-Accel. Spectrom. Dect. Assoc. Equip., 976, 164286. https://doi.org/10.1016/j.nima.2020.164286. Sato Y. Minemoto K. Nemoto M. Torii T. ( 2020 ). Construction of virtual reality system for radiation working environment reproduced by gamma-ray imagers combined with SLAM technologies . Nucl. Instrum. Methods Phys. Res. Sect. A-Accel. Spectrom. Dect. Assoc. Equip ., 976 , 164286 . https://doi.org/10.1016/j.nima.2020.164286 . Search in Google Scholar

19. Brugueras, R. P. (2016). Ultra-wideband positioning systems for industrial environments. Project report. Universitat Politècnica de Catalunya. Retrieved June 10, 2023, from https://upcommons.upc.edu/bitstream/handle/2117/96877/PRB-PFC-UWB-Industrial-Final.pdf. Brugueras R. P. ( 2016 ). Ultra-wideband positioning systems for industrial environments. Project report . Universitat Politècnica de Catalunya . Retrieved June 10, 2023, from https://upcommons.upc.edu/bitstream/handle/2117/96877/PRB-PFC-UWB-Industrial-Final.pdf . Search in Google Scholar

20. Jachimczyk, B. (2019). Real-time locating systems for indoor applications. The methodological customization approach. PhD thesis, Blekinge Tekniska Högskola. Retrieved June 19, 2023, from http://www.diva-portal.org/smash/get/diva2:1298734/FULL-TEXT02.pdf. Jachimczyk B. ( 2019 ). Real-time locating systems for indoor applications. The methodological customization approach . PhD thesis, Blekinge Tekniska Högskola . Retrieved June 19, 2023, from http://www.diva-portal.org/smash/get/diva2:1298734/FULL-TEXT02.pdf . Search in Google Scholar

21. Hungarian Standard Board. (2017). Hungarian standard: Protection against ionizing radiation, Part 2: Shielding against photon and electron radiation, Table 6: Dose rate conversion factors. Budapest. (ICS 13.280, MSZ 62-2/2017). Hungarian Standard Board . ( 2017 ). Hungarian standard: Protection against ionizing radiation, Part 2: Shielding against photon and electron radiation, Table 6: Dose rate conversion factors . Budapest. (ICS 13.280, MSZ 62-2/2017). Search in Google Scholar

22. ICRP. (2008). Nuclear decay data for dosimetric calculations. ICRP Publication, 107. Retrieved June 05, 2023, from https://www.icrp.org/publication. asp?id=ICRP%20Publication%20107. ICRP . ( 2008 ). Nuclear decay data for dosimetric calculations . ICRP Publication , 107 . Retrieved June 05, 2023, from https://www.icrp.org/publication. asp?id=ICRP%20Publication%20107 . Search in Google Scholar

23. Shi, Q., Zhao, S., Cui, X., Lu, M., & Jia, M. (2019). Anchor self-localization algorithm based on UWB ranging and inertial measurements. Tsinghua Science and Technology, 24(6), 728–736. DOI: 10.26599/TST.2018.9010102. Shi Q. Zhao S. Cui X. Lu M. Jia M. ( 2019 ). Anchor self-localization algorithm based on UWB ranging and inertial measurements . Tsinghua Science and Technology , 24 ( 6 ), 728 – 736 DOI: 10.26599/TST.2018.9010102 . Open DOISearch in Google Scholar

24. Pozyx-Powered by Scroll Viewport & Atlassian Confluence. (2020). Pozyx documentation. Greenville S.C. USA. Retrieved June 03, 2023, from https://docs.pozyx.io/creator/. Pozyx-Powered by Scroll Viewport & Atlassian Confluence . ( 2020 ). Pozyx documentation . Greenville S.C. USA . Retrieved June 03, 2023, from https://docs.pozyx.io/creator/ . Search in Google Scholar

25. Pakari, O., Lopez, R., Druckman, I., Meng, E., Zhou, E., Wang, Z., Clarke, D. S., & Pozzi, A. S. (2023). Real-time mixed reality display of dual particle radiation detector data. Sci. Rep., 13, 362. https://doi.org/10.1038/s41598-023-27632-1. Pakari O. Lopez R. Druckman I. Meng E. Zhou E. Wang Z. Clarke D. S. Pozzi A. S. ( 2023 ). Real-time mixed reality display of dual particle radiation detector data . Sci. Rep ., 13 , 362 . https://doi.org/10.1038/s41598-023-27632-1 . Search in Google Scholar

26. Raiola, F., Rozite, A., Goncalves, M., Tagziria, H., Köble, T., Risse, M., Friedrich, H., Bornhöft, M. C., Glabian, J., Deyglun, C., Funk, P., Pepin, N., Weber, A. L., Csöme, Cs., Dósa, G., Kovács, A., Nagy, Gy., Tóth, Cs., Völgyesi, P., Schroettner, T., Strebl, F., Mudri, R., Belin, M., Boucq, C., Convers, M., & Vayre, S. (2019). Capacity building in EU Member States for the testing and assessment of detection equipment in nuclear security within ITRAP+10 Phase II. Luxembourg: Publications Office of the European Union. (EUR 29786). Raiola F. Rozite A. Goncalves M. Tagziria H. Köble T. Risse M. Friedrich H. Bornhöft M. C. Glabian J. Deyglun C. Funk P. Pepin N. Weber A. L. Csöme Cs. Dósa G. Kovács A. Nagy Gy. Tóth Cs. Völgyesi P. Schroettner T. Strebl F. Mudri R. Belin M. Boucq C. Convers M. Vayre S. ( 2019 ). Capacity building in EU Member States for the testing and assessment of detection equipment in nuclear security within ITRAP+10 Phase II . Luxembourg : Publications Office of the European Union . (EUR 29786). Search in Google Scholar

27. Ionactive Consulting Limited. (September 2021). Inverse square law – when is a source a point source? Retrieved June 05, 2023, from https://ionactive.co.uk/resource-hub/guidance/inverse-square-law-when-is-a-source-a-point-source. Ionactive Consulting Limited . ( September 2021 ). Inverse square law – when is a source a point source? Retrieved June 05, 2023, from https://ionactive.co.uk/resource-hub/guidance/inverse-square-law-when-is-a-source-a-point-source . Search in Google Scholar

28. 3rd ENEN European Nuclear Competition for Secondary School Pupils. (2023). Retrieved July 10, 2023, from http://nuclearcompetition2023.enen.bme.hu/. 3rd ENEN European Nuclear Competition for Secondary School Pupils . ( 2023 ). Retrieved July 10, 2023, from http://nuclearcompetition2023.enen.bme.hu/ . Search in Google Scholar

29. EU. (2023). Regulation of transport of radioactive material and fissile material – EU training course INSC T&T Project MC3.01/20 Retrieved November 3, 2023, from https://training.ek-cer.hu/wp-content/uploads/2023/06/INSC_MC3_01_20_Course_an-nouncement_9_1_REG3.pdf. EU . ( 2023 ). Regulation of transport of radioactive material and fissile material – EU training course INSC T&T Project MC3.01/20 Retrieved November 3, 2023, from https://training.ek-cer.hu/wp-content/uploads/2023/06/INSC_MC3_01_20_Course_an-nouncement_9_1_REG3.pdf . Search in Google Scholar

30. Földi, A., Mészáros, M., Sági, L., Deme, S., Dombovári, P., Szántó, A., Tóth, K., & Petőfi-Tóth, K. (2010). Comparison of atmospheric propagation calculation software. Sugárvédelem, 3 (1), 33–41. http://www.sugarvedelem.hu/sugarvedelem/docs/V3i1/Fol_V3_I1.pdf. (In Hungarian). Földi A. Mészáros M. Sági L. Deme S. Dombovári P. Szántó A. Tóth K. Petőfi-Tóth K. ( 2010 ). Comparison of atmospheric propagation calculation software . Sugárvédelem , 3 ( 1 ), 33 – 41 http://www.sugarvedelem.hu/sugarvedelem/docs/V3i1/Fol_V3_I1.pdf . (In Hungarian). Search in Google Scholar

31. ENEA. (2023). INCLUDING – Innovative Cluster for Radiological and Nuclear Emergencies, Rome 6th Joint Action, TEST RED exercise, using the VRSS mounted on a drone to measure and localize the splitted source pieces. Retrieved September 25, 2023, from https://www.including-h2020.eu/movies/51-including-light-h264.html. ENEA . ( 2023 ). INCLUDING – Innovative Cluster for Radiological and Nuclear Emergencies, Rome 6th Joint Action, TEST RED exercise, using the VRSS mounted on a drone to measure and localize the splitted source pieces . Retrieved September 25, 2023, from https://www.including-h2020.eu/movies/51-including-light-h264.html . Search in Google Scholar