Convert Voltage Readings to Radiation Dose Rate (Sievert)

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In summary, to convert voltage readings from a PIN photodiode to radiation dose equivalent (sievert), one would need to calibrate against known sources of different strengths, then develop a calibration curve relating voltage to Sieverts. Beyond the detector would be the geometric correction for distance and size of detector which limits the number of radiation particles interacting with the detector.
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php
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how do i convert voltage readings, say from a PIN photodiode, to radiation dose rate equivalent (aka. sievert)?

any equation?

any help will be appreciated!
 
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  • #2
Well, with any detector, one would usually calibrate against known sources of different strengths, then with the known source strength and voltage develop a calibration curve relating voltage to Sieverts (radiation equivalent dose) or perhaps in this case and more appropriately grays (radiation absorbed dose).

Siverts and greys have units of energy (joules) per unit mass, and the energy deposited depends on the type of radiation which affects the interaction per unit length of path that the radiation takes through detector. Beyond the detector would be the geometric correction for distance and size of detector which limits the number of radiation particles interacting with the detector.

I presume this is for beta and/or gamma radiation?
 
  • #3
It depends on what you want to do. As Astro pointed out already, there are several things to consider, and everything depends on the accuracy you want to reach.

The most difficult point will probably be to convert the dose received by the diode (the energy deposited per unit of mass), into a dose, received by a human exposed to the same flux. This would be ok if the PIN diode had an equivalent composition to the human body, but it isn't - it's made out of higher-Z material. As such, it will over-estimate soft gammas and under-estimate hard gammas.

There are ways to solve this, like having several diodes, certain behind a thin lead shield, and others not, so that you can have a rough estimate of the gamma-spectrum. Other problem: you will seriously under-estimate the neutron-induced dose.

Now, if you just want a rough device of the kind "beep when I have to get out of here", then all these considerations are hair-splitting. But if you want to have a good quantitative dosimeter, then you will have a lot of calibration work.
 
  • #4
It depends on what you want to do.

actually I'm working on a radiation monitoring application that reads information from the gamma detector, processes it and display the monitored area radiation levels in an understandable format (probably in sievert)! so i'll need conversions like those!
 
Last edited:

1. How do you convert voltage readings to radiation dose rate (Sievert)?

To convert voltage readings to radiation dose rate, you first need to measure the voltage using a radiation detector. Then, you can use a conversion factor specific to the type of detector you are using to convert the voltage to radiation dose rate in Sieverts (Sv). This conversion factor can usually be found in the detector's user manual or by consulting a radiation expert.

2. Why is it important to convert voltage readings to radiation dose rate (Sievert)?

Converting voltage readings to radiation dose rate is important because it allows us to accurately measure the amount of radiation exposure in a given area. The dose rate in Sieverts takes into account the type of radiation, its energy, and the specific biological effects it may have on humans. This information is crucial for determining potential health risks and implementing appropriate safety measures.

3. Can voltage readings be directly used to measure radiation dose rate?

No, voltage readings cannot be directly used to measure radiation dose rate. While voltage is a measurement of the electric potential difference, radiation dose rate is a measurement of the amount of radiation absorbed by a human body. These are two different concepts and cannot be directly equated without a conversion factor.

4. Are there different conversion factors for different types of radiation detectors?

Yes, there are different conversion factors for different types of radiation detectors. This is because different detectors are designed to measure different types of radiation, such as alpha, beta, or gamma radiation. Each type of radiation has a different energy and biological effect, so the conversion factor must be specific to the type of detector being used.

5. Is converting voltage readings to radiation dose rate a complicated process?

The process of converting voltage readings to radiation dose rate can be complex, depending on the type of detector and the specific situation. It is important to have a solid understanding of the principles of radiation and measurement techniques to accurately convert the readings. Seeking guidance from a radiation expert can also be helpful in ensuring accurate conversion.

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