Cite Article

Location Analysis for Additional Permanent Radiation Detector in X-Ray Radiography Unit

Choose citation format

BibTeX

@article{IJASEIT15804,
   author = {Rizka Indra Prasetya and Gede Bayu Suparta},
   title = {Location Analysis for Additional Permanent Radiation Detector in X-Ray Radiography Unit},
   journal = {International Journal on Advanced Science, Engineering and Information Technology},
   volume = {12},
   number = {3},
   year = {2022},
   pages = {1080--1084},
   keywords = {Radiography; x-ray machine; dose radiation; radiation protection; x-ray detector.},
   abstract = {We have developed a Digital Fluorescence X-Ray Radiography prototype at the Department of Physics, Gadjah Mada University (UGM). The prototype should comply with radiation protection rules. Using an additional permanent dose detector to measure dose radiation indirectly is necessary. We indirectly controlled the dose analysis through a dose control chart from a permanent detector. We consider the Heel Effect in determining the position of the detector at the edge of the screen while reducing the scattered radiation and minimizing the difference to the reference point. The position of the detector follows a grid 5x5. The dose measurement will show the dose distribution pattern. It shows that the radiation dose at the edge point close to the cathode side has the closest dose value to the center point. The dose value variation at 70 kVp and 80 kVp is less than 5%. The dose value equation for the prototype is Gy = [(0.3579* kVp) -16.27] * mAs. A control chart will control that equation from the permanent detector to ensure that the dose value obtained is always valid. The Warning Limit (WL) dose from the control chart is 68.75 Gy, 63.99 Gy, and the Action Limit (AL) is 69.94 Gy and 62.80 Gy. The dose radiation monitoring may use the dose value equation controlled by a control chart from the permanent detector. Continuous reports on the dose value and the limit dose value are essential to ensure the health of the RSFD prototype.},
   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=15804},
   doi = {10.18517/ijaseit.12.3.15804}
}

EndNote

%A Prasetya, Rizka Indra
%A Suparta, Gede Bayu
%D 2022
%T Location Analysis for Additional Permanent Radiation Detector in X-Ray Radiography Unit
%B 2022
%9 Radiography; x-ray machine; dose radiation; radiation protection; x-ray detector.
%! Location Analysis for Additional Permanent Radiation Detector in X-Ray Radiography Unit
%K Radiography; x-ray machine; dose radiation; radiation protection; x-ray detector.
%X We have developed a Digital Fluorescence X-Ray Radiography prototype at the Department of Physics, Gadjah Mada University (UGM). The prototype should comply with radiation protection rules. Using an additional permanent dose detector to measure dose radiation indirectly is necessary. We indirectly controlled the dose analysis through a dose control chart from a permanent detector. We consider the Heel Effect in determining the position of the detector at the edge of the screen while reducing the scattered radiation and minimizing the difference to the reference point. The position of the detector follows a grid 5x5. The dose measurement will show the dose distribution pattern. It shows that the radiation dose at the edge point close to the cathode side has the closest dose value to the center point. The dose value variation at 70 kVp and 80 kVp is less than 5%. The dose value equation for the prototype is Gy = [(0.3579* kVp) -16.27] * mAs. A control chart will control that equation from the permanent detector to ensure that the dose value obtained is always valid. The Warning Limit (WL) dose from the control chart is 68.75 Gy, 63.99 Gy, and the Action Limit (AL) is 69.94 Gy and 62.80 Gy. The dose radiation monitoring may use the dose value equation controlled by a control chart from the permanent detector. Continuous reports on the dose value and the limit dose value are essential to ensure the health of the RSFD prototype.
%U http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=15804
%R doi:10.18517/ijaseit.12.3.15804
%J International Journal on Advanced Science, Engineering and Information Technology
%V 12
%N 3
%@ 2088-5334

IEEE

Rizka Indra Prasetya and Gede Bayu Suparta,"Location Analysis for Additional Permanent Radiation Detector in X-Ray Radiography Unit," International Journal on Advanced Science, Engineering and Information Technology, vol. 12, no. 3, pp. 1080-1084, 2022. [Online]. Available: http://dx.doi.org/10.18517/ijaseit.12.3.15804.

RefMan/ProCite (RIS)

TY  - JOUR
AU  - Prasetya, Rizka Indra
AU  - Suparta, Gede Bayu
PY  - 2022
TI  - Location Analysis for Additional Permanent Radiation Detector in X-Ray Radiography Unit
JF  - International Journal on Advanced Science, Engineering and Information Technology; Vol. 12 (2022) No. 3
Y2  - 2022
SP  - 1080
EP  - 1084
SN  - 2088-5334
PB  - INSIGHT - Indonesian Society for Knowledge and Human Development
KW  - Radiography; x-ray machine; dose radiation; radiation protection; x-ray detector.
N2  - We have developed a Digital Fluorescence X-Ray Radiography prototype at the Department of Physics, Gadjah Mada University (UGM). The prototype should comply with radiation protection rules. Using an additional permanent dose detector to measure dose radiation indirectly is necessary. We indirectly controlled the dose analysis through a dose control chart from a permanent detector. We consider the Heel Effect in determining the position of the detector at the edge of the screen while reducing the scattered radiation and minimizing the difference to the reference point. The position of the detector follows a grid 5x5. The dose measurement will show the dose distribution pattern. It shows that the radiation dose at the edge point close to the cathode side has the closest dose value to the center point. The dose value variation at 70 kVp and 80 kVp is less than 5%. The dose value equation for the prototype is Gy = [(0.3579* kVp) -16.27] * mAs. A control chart will control that equation from the permanent detector to ensure that the dose value obtained is always valid. The Warning Limit (WL) dose from the control chart is 68.75 Gy, 63.99 Gy, and the Action Limit (AL) is 69.94 Gy and 62.80 Gy. The dose radiation monitoring may use the dose value equation controlled by a control chart from the permanent detector. Continuous reports on the dose value and the limit dose value are essential to ensure the health of the RSFD prototype.
UR  - http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=15804
DO  - 10.18517/ijaseit.12.3.15804

RefWorks

RT Journal Article
ID 15804
A1 Prasetya, Rizka Indra
A1 Suparta, Gede Bayu
T1 Location Analysis for Additional Permanent Radiation Detector in X-Ray Radiography Unit
JF International Journal on Advanced Science, Engineering and Information Technology
VO 12
IS 3
YR 2022
SP 1080
OP 1084
SN 2088-5334
PB INSIGHT - Indonesian Society for Knowledge and Human Development
K1 Radiography; x-ray machine; dose radiation; radiation protection; x-ray detector.
AB We have developed a Digital Fluorescence X-Ray Radiography prototype at the Department of Physics, Gadjah Mada University (UGM). The prototype should comply with radiation protection rules. Using an additional permanent dose detector to measure dose radiation indirectly is necessary. We indirectly controlled the dose analysis through a dose control chart from a permanent detector. We consider the Heel Effect in determining the position of the detector at the edge of the screen while reducing the scattered radiation and minimizing the difference to the reference point. The position of the detector follows a grid 5x5. The dose measurement will show the dose distribution pattern. It shows that the radiation dose at the edge point close to the cathode side has the closest dose value to the center point. The dose value variation at 70 kVp and 80 kVp is less than 5%. The dose value equation for the prototype is Gy = [(0.3579* kVp) -16.27] * mAs. A control chart will control that equation from the permanent detector to ensure that the dose value obtained is always valid. The Warning Limit (WL) dose from the control chart is 68.75 Gy, 63.99 Gy, and the Action Limit (AL) is 69.94 Gy and 62.80 Gy. The dose radiation monitoring may use the dose value equation controlled by a control chart from the permanent detector. Continuous reports on the dose value and the limit dose value are essential to ensure the health of the RSFD prototype.
LK http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=15804
DO  - 10.18517/ijaseit.12.3.15804