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Experimental Characterization of Dosimeter Based on a Wireless Sensor Network for A Radiation Protection Program

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@article{IJASEIT11875,
   author = {Ramacos Fardela and Gede Bayu Suparta and Ahmad Ashari and Kuwat Triyana},
   title = {Experimental Characterization of Dosimeter Based on a Wireless Sensor Network for A Radiation Protection Program},
   journal = {International Journal on Advanced Science, Engineering and Information Technology},
   volume = {11},
   number = {4},
   year = {2021},
   pages = {1468--1473},
   keywords = {Dosimeter; radiation protection; real-time measurement; wireless sensor network; gamma radiation.},
   abstract = {In this paper, we show our instrumental design and experimental results on the use of personal dosimeters for determining the radiation dose received by a radiation worker in real-time. We used the wireless sensor networks (WSN) technology to monitor five personal dosimeters. This instrument includes cost-effective sensors, developed as an alternative efficient method for a radiation protection program. A coordinator node, along with a graphic user interface (GUI) was developed for this purpose. The main component of a sensor node consists of commercial radiation made from photodiode type X-100 7, an Arduino microcontroller as a microprocessor, and a low power consumption Xbee module for wireless communication. Testing has been carried out to see the characteristics of the wireless sensor in an open space and a laboratory building. Based on the analysis of packet error rate (PER) values, the communication between the sensor node and coordinator node can be run properly in open space at a maximum distance of 140 m, whereas in the laboratory building at about 45 m due to the blockage by some concrete walls. The radiation count received by the sensor must be at least 30 seconds, and the counting is stable up to 400 seconds. By determining the radiation dose received in real-time, radiation workers may receive an early notification related to the dose received in their working environment with a better log documentation system.},
   issn = {2088-5334},
   publisher = {INSIGHT - Indonesian Society for Knowledge and Human Development},
   url = {http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=11875},
   doi = {10.18517/ijaseit.11.4.11875}
}

EndNote

%A Fardela, Ramacos
%A Suparta, Gede Bayu
%A Ashari, Ahmad
%A Triyana, Kuwat
%D 2021
%T Experimental Characterization of Dosimeter Based on a Wireless Sensor Network for A Radiation Protection Program
%B 2021
%9 Dosimeter; radiation protection; real-time measurement; wireless sensor network; gamma radiation.
%! Experimental Characterization of Dosimeter Based on a Wireless Sensor Network for A Radiation Protection Program
%K Dosimeter; radiation protection; real-time measurement; wireless sensor network; gamma radiation.
%X In this paper, we show our instrumental design and experimental results on the use of personal dosimeters for determining the radiation dose received by a radiation worker in real-time. We used the wireless sensor networks (WSN) technology to monitor five personal dosimeters. This instrument includes cost-effective sensors, developed as an alternative efficient method for a radiation protection program. A coordinator node, along with a graphic user interface (GUI) was developed for this purpose. The main component of a sensor node consists of commercial radiation made from photodiode type X-100 7, an Arduino microcontroller as a microprocessor, and a low power consumption Xbee module for wireless communication. Testing has been carried out to see the characteristics of the wireless sensor in an open space and a laboratory building. Based on the analysis of packet error rate (PER) values, the communication between the sensor node and coordinator node can be run properly in open space at a maximum distance of 140 m, whereas in the laboratory building at about 45 m due to the blockage by some concrete walls. The radiation count received by the sensor must be at least 30 seconds, and the counting is stable up to 400 seconds. By determining the radiation dose received in real-time, radiation workers may receive an early notification related to the dose received in their working environment with a better log documentation system.
%U http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=11875
%R doi:10.18517/ijaseit.11.4.11875
%J International Journal on Advanced Science, Engineering and Information Technology
%V 11
%N 4
%@ 2088-5334

IEEE

Ramacos Fardela,Gede Bayu Suparta,Ahmad Ashari and Kuwat Triyana,"Experimental Characterization of Dosimeter Based on a Wireless Sensor Network for A Radiation Protection Program," International Journal on Advanced Science, Engineering and Information Technology, vol. 11, no. 4, pp. 1468-1473, 2021. [Online]. Available: http://dx.doi.org/10.18517/ijaseit.11.4.11875.

RefMan/ProCite (RIS)

TY  - JOUR
AU  - Fardela, Ramacos
AU  - Suparta, Gede Bayu
AU  - Ashari, Ahmad
AU  - Triyana, Kuwat
PY  - 2021
TI  - Experimental Characterization of Dosimeter Based on a Wireless Sensor Network for A Radiation Protection Program
JF  - International Journal on Advanced Science, Engineering and Information Technology; Vol. 11 (2021) No. 4
Y2  - 2021
SP  - 1468
EP  - 1473
SN  - 2088-5334
PB  - INSIGHT - Indonesian Society for Knowledge and Human Development
KW  - Dosimeter; radiation protection; real-time measurement; wireless sensor network; gamma radiation.
N2  - In this paper, we show our instrumental design and experimental results on the use of personal dosimeters for determining the radiation dose received by a radiation worker in real-time. We used the wireless sensor networks (WSN) technology to monitor five personal dosimeters. This instrument includes cost-effective sensors, developed as an alternative efficient method for a radiation protection program. A coordinator node, along with a graphic user interface (GUI) was developed for this purpose. The main component of a sensor node consists of commercial radiation made from photodiode type X-100 7, an Arduino microcontroller as a microprocessor, and a low power consumption Xbee module for wireless communication. Testing has been carried out to see the characteristics of the wireless sensor in an open space and a laboratory building. Based on the analysis of packet error rate (PER) values, the communication between the sensor node and coordinator node can be run properly in open space at a maximum distance of 140 m, whereas in the laboratory building at about 45 m due to the blockage by some concrete walls. The radiation count received by the sensor must be at least 30 seconds, and the counting is stable up to 400 seconds. By determining the radiation dose received in real-time, radiation workers may receive an early notification related to the dose received in their working environment with a better log documentation system.
UR  - http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=11875
DO  - 10.18517/ijaseit.11.4.11875

RefWorks

RT Journal Article
ID 11875
A1 Fardela, Ramacos
A1 Suparta, Gede Bayu
A1 Ashari, Ahmad
A1 Triyana, Kuwat
T1 Experimental Characterization of Dosimeter Based on a Wireless Sensor Network for A Radiation Protection Program
JF International Journal on Advanced Science, Engineering and Information Technology
VO 11
IS 4
YR 2021
SP 1468
OP 1473
SN 2088-5334
PB INSIGHT - Indonesian Society for Knowledge and Human Development
K1 Dosimeter; radiation protection; real-time measurement; wireless sensor network; gamma radiation.
AB In this paper, we show our instrumental design and experimental results on the use of personal dosimeters for determining the radiation dose received by a radiation worker in real-time. We used the wireless sensor networks (WSN) technology to monitor five personal dosimeters. This instrument includes cost-effective sensors, developed as an alternative efficient method for a radiation protection program. A coordinator node, along with a graphic user interface (GUI) was developed for this purpose. The main component of a sensor node consists of commercial radiation made from photodiode type X-100 7, an Arduino microcontroller as a microprocessor, and a low power consumption Xbee module for wireless communication. Testing has been carried out to see the characteristics of the wireless sensor in an open space and a laboratory building. Based on the analysis of packet error rate (PER) values, the communication between the sensor node and coordinator node can be run properly in open space at a maximum distance of 140 m, whereas in the laboratory building at about 45 m due to the blockage by some concrete walls. The radiation count received by the sensor must be at least 30 seconds, and the counting is stable up to 400 seconds. By determining the radiation dose received in real-time, radiation workers may receive an early notification related to the dose received in their working environment with a better log documentation system.
LK http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=11875
DO  - 10.18517/ijaseit.11.4.11875