Comparison of dosimeters

Last updated April 10, 2024

The following table compares features of dosimeters.

Ionizing radiation dosimeters
Device	Mfg. country	Size, mm	Weight, g	Power supply	Display	Sound	Vibration	Detector type	Range, μSv/h	Range, μR/h	Measurement time, seconds	Measuring of beta and gamma radiation and range of energy	PC link	Extra features
SA-05A^[1]	Switzerland	119x65x26.5	135	Built-in lithium polymer battery	LCD	No	No	Geiger–Müller tube LND 713	0.01–6000	No	1–60	0.05–1.3 MeV	USB	Clock, calendar and data logger
ANRI 01-02 Sosna^[2]	Russia	133x82x45	350	Nine-volt battery	LCD	Yes	No	Two to four Geiger–Müller tubes	0.1–100	10–10⁴	20±5	Combined, 0.5–3.0 MeV	No
DKG-RM1203M^[3]	Belarus	125x42x24	90	Two LR44	LCD	Yes	No	Geiger–Müller tube	0.01–2000	1–2*10⁵	?	No	Infrared	Clock with alarm
MKS-05 «Terra-P»	Ukraine	120×52×26	150	Two AAA	LCD	Yes	No	Geiger–Müller tube	0.1–1000	10–10⁵	5–70	Combined, 0.5–3.0 MeV	No	Clock with alarm, cover as option
MKS-05 «Terra» (New edition)	Ukraine	120×52×26	150	Two AAA	LCD with backlight	Yes	Yes	Geiger–Müller tube	0.1–10⁴	10–10⁶	1–70	Combined, 0.5–3.0 MeV	Bluetooth	Clock with alarm, cover
DKR-04	?	74х48х16	50	AAA	LCD	Yes	No	Semiconductor	0.1–10⁶	10–10⁸	4–256	No	No
GQ GMC-500+^[4]	United States	135x78x25		Lithium-ion battery (18650)	LCD with backlight	Yes	No	Two Geiger–Müller tubes	0–42500	0–4.25*10⁶	1–60	Combined, 0.1–3 MeV	USB	WiFi, logging to a server, gyroscope
Radex RD1503, RD1503+	Russia	105х60х26	90	One or two AAA	LCD with backlight	Yes	Only RD1503+	Geiger–Müller tube	0.05–10	5–1000	up to 40	Combined, 0.1–1,25 MeV	No
Radex RD1706	Russia	105х60х26	90	One or two AAA	LCD with backlight	Yes	Yes	Two Geiger–Müller tubes	0.05–1000	5–10⁵	1–26	Combined, 0.1–1.25 MeV	No	Background mode
Radex RD1212	Russia	97x68x24	80	One or two AAA	LCD with backlight	Yes	Yes	One Geiger–Müller tube	0.05–999	5–10⁵	1–10	Combined, 0.4–3.5 MeV	USB	Background mode, integrated flashlight, time and date functions, multilingual
Radex RD1008	Russia	140х64х26	175	AA	LCD with backlight	Yes	Yes	Two Geiger–Müller tubes	0.1–1000	2–120	2–21	Separated, 0.05–3.5 MeV	No	Background mode, separated indication of beta and gamma radiation
RadTarge II D300^[5]	China	69x46x17	60	Built-in lithium ion battery	LCD with backlight	Yes	Yes	YSO scintillator + SiPM	0.5–5000	50–5*10⁵	< 8	No, 0.03–1.5 MeV	USB	Dose equivalent rate + accumulated dose meter, pager-like clip, time and date functions, data logging and export (via Mac/PC software)
RadTarge II D700^[6]	China	69x46x17	60	Built-in lithium-ion battery	LCD with backlight	Yes	Yes	YSO scintillator + SiPM	0.01–1000	1–10⁵	< 2	No, 0.02–3 MeV	USB	Dose equivalent rate + accumulated dose meter, pager-like clip, time and date functions, data logging and export (via Mac/PC software)
RadTarge II D900^[7]	China	69x46x17	60	Built-in lithium-ion battery	LCD with backlight	Yes	Yes	YSO scintillator + SiPM	0.1–10⁵	10–10⁷	< 6	No, 0.02–3 MeV	USB	Dose equivalent rate + accumulated dose meter, pager-like clip, time and date functions, data logging and export (via Mac/PC software)
RKSB-104	Belarus	154х77х39	350	Nine-volt battery	LCD	No	No	Two Geiger–Müller tubes	0.1–100	10–2*10⁴	18–400	Combined, 0.5–3.0 MeV	No
DKG-RM1610	Belarus	58х58х18	70	Built-in accumulator	LCD	Yes	Yes	One Geiger–Müller tube	0.01–1.2*10⁶	1–1.2*10⁸	?	No	USB	Shock protection
EcotestCARD	Ukraine		80	CR2450	LCD	Yes	No	Semiconductor	0.1–10⁶	10–10⁸	?	?	Infrared

Related Research Articles

A radiation dosimeter is a device that measures dose uptake of external ionizing radiation. It is worn by the person being monitored when used as a personal dosimeter, and is a record of the radiation dose received. Modern electronic personal dosimeters can give a continuous readout of cumulative dose and current dose rate, and can warn the wearer with an audible alarm when a specified dose rate or a cumulative dose is exceeded. Other dosimeters, such as thermoluminescent or film types, require processing after use to reveal the cumulative dose received, and cannot give a current indication of dose while being worn.

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The sievert is a unit in the International System of Units (SI) intended to represent the stochastic health risk of ionizing radiation, which is defined as the probability of causing radiation-induced cancer and genetic damage. The sievert is important in dosimetry and radiation protection. It is named after Rolf Maximilian Sievert, a Swedish medical physicist renowned for work on radiation dose measurement and research into the biological effects of radiation.

The gray is the unit of ionizing radiation dose in the International System of Units (SI), defined as the absorption of one joule of radiation energy per kilogram of matter.

The Therac-25 is a computer-controlled radiation therapy machine produced by Atomic Energy of Canada Limited (AECL) in 1982 after the Therac-6 and Therac-20 units.

Radiation dosimetry in the fields of health physics and radiation protection is the measurement, calculation and assessment of the ionizing radiation dose absorbed by an object, usually the human body. This applies both internally, due to ingested or inhaled radioactive substances, or externally due to irradiation by sources of radiation.

Radiation protection, also known as radiological protection, is defined by the International Atomic Energy Agency (IAEA) as "The protection of people from harmful effects of exposure to ionizing radiation, and the means for achieving this". Exposure can be from a source of radiation external to the human body or due to internal irradiation caused by the ingestion of radioactive contamination.

<span class="mw-page-title-main">Health physics</span>

Health physics, also referred to as the science of radiation protection, is the profession devoted to protecting people and their environment from potential radiation hazards, while making it possible to enjoy the beneficial uses of radiation. Health physicists normally require a four-year bachelor’s degree and qualifying experience that demonstrates a professional knowledge of the theory and application of radiation protection principles and closely related sciences. Health physicists principally work at facilities where radionuclides or other sources of ionizing radiation are used or produced; these include research, industry, education, medical facilities, nuclear power, military, environmental protection, enforcement of government regulations, and decontamination and decommissioning—the combination of education and experience for health physicists depends on the specific field in which the health physicist is engaged.

Absorbed dose is a dose quantity which is the measure of the energy deposited in matter by ionizing radiation per unit mass. Absorbed dose is used in the calculation of dose uptake in living tissue in both radiation protection, and radiology. It is also used to directly compare the effect of radiation on inanimate matter such as in radiation hardening.

Radiation hardening is the process of making electronic components and circuits resistant to damage or malfunction caused by high levels of ionizing radiation, especially for environments in outer space, around nuclear reactors and particle accelerators, or during nuclear accidents or nuclear warfare.

<span class="mw-page-title-main">Film badge dosimeter</span> Device using photographic film to measure radiation exposure

A film badge dosimeter or film badge is a personal dosimeter used for monitoring cumulative radiation dose due to ionizing radiation.

A quartz fiber dosimeter, sometimes called a self indicating pocket dosimeter (SIPD) or self reading pocket dosimeter (SRPD) or quartz fibre electrometer (QFE), is a type of radiation dosimeter, a pen-like device that measures the cumulative dose of ionizing radiation received by the device, usually over one work period. It is clipped to a person's clothing, normally a breast pocket for whole body exposure, to measure the user's exposure to radiation.

The computed tomography dose index (CTDI) is a commonly used radiation exposure index in X-ray computed tomography (CT), first defined in 1981. The unit of CTDI is the gray (Gy) and it can be used in conjunction with patient size to estimate the absorbed dose. The CTDI and absorbed dose may differ by more than a factor of two for small patients such as children.

The roentgen or röntgen is a legacy unit of measurement for the exposure of X-rays and gamma rays, and is defined as the electric charge freed by such radiation in a specified volume of air divided by the mass of that air . In 1928, it was adopted as the first international measurement quantity for ionizing radiation to be defined for radiation protection, as it was then the most easily replicated method of measuring air ionization by using ion chambers. It is named after the German physicist Wilhelm Röntgen, who discovered X-rays and was awarded the first Nobel Prize in Physics for the discovery.

The Radiation Laboratory, commonly called the Rad Lab, was a microwave and radar research laboratory located at the Massachusetts Institute of Technology (MIT) in Cambridge, Massachusetts. It was first created in October 1940 and operated until 31 December 1945 when its functions were dispersed to industry, other departments within MIT, and in 1951, the newly formed MIT Lincoln Laboratory.

StemRad is an Israeli-American start-up company that develops and manufactures personal protective equipment (PPE) against ionizing radiation. Its first product was the 360 Gamma, a device that protects the user's pelvic bone marrow from gamma radiation. StemRad has also developed the StemRad MD, a protective suit designed to provide whole-body radiation protection to physicians, and the AstroRad vest for radiation protection in space, which is currently being tested on the International Space Station and is one of the primary payloads onboard NASA's Artemis 1 lunar mission.

Gel dosimeters, also called Fricke gel dosimeters, are manufactured from radiation sensitive chemicals that, upon irradiation with ionising radiation, undergo a fundamental change in their properties as a function of the absorbed radiation dose.

<span class="mw-page-title-main">Electronic personal dosimeter</span>

The electronic personal dosimeter (EPD) is a modern electronic dosimeter for estimating uptake of ionising radiation dose of the individual wearing it for radiation protection purposes. The electronic personal dosimeter has the advantages over older types that it has a number of sophisticated functions, such as continuous monitoring which allows alarm warnings at preset levels and live readout of dose accumulated. It can be reset to zero after use, and most models allow near field electronic communications for automatic reading and resetting.

US Nuclear Corporation is a US radiation detection holding company headquartered in Canoga Park, CA specializing in the development and manufacturing of radiation detection instrumentation. It supplies instrumentation to nuclear power plants, national laboratories, government agencies, homeland security, military and weapon makers, universities and schools, research companies, hospitals, as well as energy companies.

Radiochromic film is a type of self-developing film typically used in the testing and characterisation of radiographic equipment such as CT scanners and radiotherapy linacs. The film contains a dye which changes colour when exposed to ionising radiation, allowing the level of exposure and beam profile to be characterised. Unlike x-ray film no developing process is required and results can be obtained almost instantly, while it is insensitive to visible light.

References

↑ Allimann.com
↑ Дозиметр-радиометр АНРИ-01-02 "Сосна"
↑ Polimaster DKG-RM1203M or find a current model at Polimaster Ltd.
↑ "GQ Geiger Counter Selection Guide". GQ Electronics LLC. Retrieved 2022-10-06.
↑ "Electronic Personal Dosimeter | RadTarge II D300 | X-Z LAB". X-Z LAB. Retrieved 2016-11-14.
↑ "Electronic Personal Dosimeter | RadTarge II D700 | X-Z LAB". X-Z LAB. Retrieved 2016-11-14.
↑ "Electronic Personal Dosimeter | RadTarge II D900 | X-Z LAB". X-Z LAB. Retrieved 2016-11-14.

Literature

"Intercomparison of personal dose equivalent measurements by active personal dosimeters" (PDF). International Atomic Energy Agency. Chicago. 2007.
Bordy JM, Daures J, Clairand I, Denozière M, Donadille L, d'Errico F, Gouriou J, Itié C, Struelens L (2008). "Evaluation of the calibration procedure of active personal dosemeters for interventional radiology". Radiation Protection Dosimetry. 131 (1): 87–92. doi:10.1093/rpd/ncn225. PMID 18757898.
"Comparison of Personal Dosimeters". Radiation Emergency Medical Management (REMM). United States Department of Health and Human Services . Retrieved October 10, 2022.

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[Allimann.com-1] Allimann.com

[2] Дозиметр-радиометр АНРИ-01-02 "Сосна"

[3] Polimaster DKG-RM1203M or find a current model at Polimaster Ltd.

[4] "GQ Geiger Counter Selection Guide". GQ Electronics LLC. Retrieved 2022-10-06.

[5] "Electronic Personal Dosimeter | RadTarge II D300 | X-Z LAB". X-Z LAB. Retrieved 2016-11-14.

[6] "Electronic Personal Dosimeter | RadTarge II D700 | X-Z LAB". X-Z LAB. Retrieved 2016-11-14.

[7] "Electronic Personal Dosimeter | RadTarge II D900 | X-Z LAB". X-Z LAB. Retrieved 2016-11-14.

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