| Title: | A miniaturized radiation monitor for continuous dosimetry and particle identification in space |
| Authors: | Gohl, Stefan Malich, Milan Bergmann, Benedikt Burian, Petr Granja, Carlos Heijne, Erik H. Holík, Michael Jacubek, Jan Janeček, Josef Marek, Lukáš Oancea, Cristina Petro, Maros Pospíšil, Stanislav Smetana, Adam Soukup, Pavel Tureček, Daniel Vuolo, Marco |
| Citation: | GOHL, S. MALICH, M. BERGMANN, B. BURIAN, P. GRANJA, C. HEIJNE, EH. HOLÍK, M. JACUBEK, J. JANEČEK, J. MAREK, L. OANCEA, C. PETRO, M. POSPÍŠIL, S. SMETANA, A. SOUKUP, P. TUREČEK, D. VUOLO, M. A miniaturized radiation monitor for continuous dosimetry and particle identification in space . Journal of Instrumentation, 2022, roč. 17, č. 1, s. nestránkováno. ISSN: 1748-0221 |
| Issue Date: | 2022 |
| Publisher: | IOP Publishing |
| Document type: | článek article |
| URI: | 2-s2.0-85125544438 http://hdl.handle.net/11025/51324 |
| ISSN: | 1748-0221 |
| Keywords in different language: | d E/d x detectors;on-board space electronics;particle tracking detectors;radiation monitoring |
| Abstract: | A Miniaturized Radiation Monitor (MIRAM) has been developed for the continuous measurement of the radiation field composition and ionizing dose rates in near earth orbits. Compared to currently used radiation monitors, the presented device has an order of magnitude lower weight while being comparable in power consumption and functionality. MIRAM is capable of on-board real-time self-diagnostic. Furthermore, it supports on-board analysis of the measured data to be able to work autonomously. The dose rate is calculated continuously based on the energy deposition in the Timepix3 detector. For the estimation of the particle species composition of the radiation environment, two methods are applied depending on the current flux. At lower fluxes (<104 particles per cm2 per s), a track-by-track analysis based on temporal coincidence is applied. At higher fluxes, a less power and memory consuming method is utilized. This method is using the averaged deposited energy per pixel to estimate the electron and proton content of the radiation field. |
| Abstract in different language: | A Miniaturized Radiation Monitor (MIRAM) has been developed for the continuous measurement of the radiation field composition and ionizing dose rates in near earth orbits. Compared to currently used radiation monitors, the presented device has an order of magnitude lower weight while being comparable in power consumption and functionality. MIRAM is capable of on-board real-time self-diagnostic. Furthermore, it supports on-board analysis of the measured data to be able to work autonomously. The dose rate is calculated continuously based on the energy deposition in the Timepix3 detector. For the estimation of the particle species composition of the radiation environment, two methods are applied depending on the current flux. At lower fluxes (<104 particles per cm2 per s), a track-by-track analysis based on temporal coincidence is applied. At higher fluxes, a less power and memory consuming method is utilized. This method is using the averaged deposited energy per pixel to estimate the electron and proton content of the radiation field. |
| Rights: | Plný text není přístupný. © IOP Publishing Ltd and Sissa Medialab |
| Appears in Collections: | Články / Articles (RICE) OBD |
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