KR20230041175A - Method for temperature compensation of radiation spectrum - Google Patents

Abstract

The present invention relates to a method for temperature compensation of a radiation spectrum for nuclide discrimination, which comprises: a first step of receiving and storing background radiation energy spectrum data measured by a radiation detector in an environment without a target to discriminate a radioactive nuclide; a second step of calculating a reference count center value and a reference count rate from the background radiation energy spectrum data to store the same; a third step of receiving target radiation energy spectrum data measured by the radiation detector in an environment with a target to discriminate a radioactive nuclide to store the same; a fourth step of calculating a target count center value and a target count rate from the target radiation energy spectrum data to store the same; a fifth step of comparing the reference count center value to the target count center value; and the sixth step of, when the target count center value exceeds a predetermined error range compared to the reference count center value, comparing the reference count rate to the target count rate while adjusting a gain value for temperature compensation. Therefore, the third step and the sixth step may be repeatedly performed for temperature compensation with respect to the radiation energy spectrum for nuclide discrimination. Therefore, the temperature compensation for nuclide discrimination may be quickly performed.

Description

Temperature compensation method of radiation spectrum for nuclide identification {METHOD FOR TEMPERATURE COMPENSATION OF RADIATION SPECTRUM}

The present invention relates to a method for compensating the temperature of a radiation spectrum, and more particularly, to a method for temperature compensation of a radiation spectrum for discriminating a nuclide in which temperature compensation for discriminating a nuclide can be quickly performed by software.

In general, scintillator-type detection systems such as NaI(Tl) and PVT are equipment that analyzes incident radiation/activity information using a radiation energy spectrum incident on a detector. A scintillator-type detector absorbs incident radiation energy and emits a proportional amount of photons. At this time, the generated photons are measured by the PMT, and the radiation energy spectrum is measured by collecting count information for each radiation energy through a multi-channel analyzer (MCA).

In the radiation energy spectrum, the coefficient distribution is determined according to the gamma ray reaction such as the photoelectric effect, Compton scattering, and electron pair generation, and analysis using the full energy peak is mainly used. The full energy peak is a peak that has absorbed all of the radiation energy and has a Gaussian shape. Full-energy peaks are narrow and indicate specific energies and are used for energy calibration and nuclide determination.

Energy calibration is a process of matching the energy information for each channel using several random radionuclides, and nuclide identification is an analysis to determine the radionuclides included in the measured sample (or radiation), and the energy of the total energy peak and the target The radionuclide energy information is compared to determine the matching radionuclide. In other words, the energy corresponding to each channel is calculated, and the nuclide is determined by comparing the channel (energy) where the total energy peak is generated and the energy of the existing nuclide information.

On the other hand, optical sensors (PMT, SiPM, etc.) that measure the amount of light generated from NaI(Tl), PVT, etc. are sensitive to temperature and affect the radiation energy spectrum. The spectral change according to temperature shows a tendency for the total energy peak to move to a lower channel as the temperature increases, and this change causes inaccurate nuclide identification.

A technology to compensate for this problem is called a temperature compensation technology, and a fixed energy is obtained for a specific channel by grafting the temperature compensation technology. Temperature compensation technology is divided into hardware technology and software technology. Hardware technology includes 1) a method using a thermometer (disclosed in Korean Patent Registration No. 10-1188749, etc.), and 2) a method using an LED (disclosed in US Patent Registration No. 07642516, etc.). The software technology is a correction method through spectrum analysis.

As a software technology, there is a temperature compensation method using natural radionuclides. In environments other than extreme environments such as marine and space environments, radiation from natural radionuclides is collected from the surroundings, and it can be used for temperature compensation. Radiation measured from the surrounding environment uses the total energy peaks measured from Pb-212, Pb-214, K-40, and Tl-208 to check the change in energy value for each channel through regular spectrum analysis and determine the energy difference. way to correct it.

However, this temperature compensation method requires a long calculation time and at least 5 minutes (depending on the detector volume) of measurement data because the peak search and peak positioning algorithms are composed of very complex formulas. In other words, it is suitable for use when a high-speed arithmetic processor such as a PC is used, but it is difficult to apply it to a low-power arithmetic processor embedded in small equipment or portable equipment due to lack of performance.

At least 5 minutes of measurement data is required for natural nuclide analysis, and if the energy is distorted due to temperature compensation, a blank time for correction (as much as the measurement time) is generated to match it, which causes a setback to the actual radiation analysis.

Korean Registered Patent Publication No. 10-1188749 US Patent Registration No. 07642516

An object of the present invention is to provide a temperature compensation method of radiation spectrum for nuclide identification in which temperature compensation for nuclide identification can be quickly performed in software.

The technical problems to be solved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below. You will be able to.

The present invention for achieving the above object is a first step of receiving and storing background radiation energy spectrum data measured by a radiation detector in an environment without an object for determining radioactive nuclides; a second step of calculating and storing a reference count center value and a reference count rate from the background radiation energy spectrum data; a third step of receiving and storing the radiation energy spectrum data of the object measured by the radiation detector in an environment where the object for determining radioactive nuclides is present; a fourth step of calculating and storing an object count center value and an object count rate from the object radiation energy spectrum data; a fifth step of comparing the reference count center value and the object count center value; and a sixth step of comparing the reference count rate and the object count rate and adjusting a gain value for temperature compensation when the object count center value exceeds a preset error range with respect to the reference count center value. It is characterized in that the radiation energy spectrum for discriminating the nuclide is temperature-compensated while repeating the step to the sixth step.

Specifically, in the sixth step, when the object count center value exceeds the error range of 5% compared to the reference count center value, the reference count rate and the object count rate may be compared.

In the sixth step, if the object count rate is 10% or less compared to the reference count rate, the gain value may be adjusted.

In the sixth step, the gain value may be calculated by multiplying a value obtained by dividing the reference count center value by the object count center value by a preset gain value in the first step.

According to the present invention, since the temperature compensation for the radiation energy spectrum is performed in software in about 15 seconds, the blank time for correction (as much as the measurement time) is greatly reduced as in the prior art, so that the nuclide can be quickly identified, and with low power Since it is possible to drive an operation processor, it can be applied to small equipment or portable equipment.

1 is a block diagram schematically showing a system implementing the temperature compensation method of radiation spectrum for nuclide determination according to the present invention.
2 is a flowchart showing a temperature compensation method of radiation spectrum for nuclide determination according to the present invention.
3 is a graph of background radiation energy spectrum data.
4 is a graph showing a process of accumulating and storing object radiation energy spectrum data and calculating values.
5 is a graph showing object radiation energy spectrum data within an error range.
6 is a graph showing the object radiation energy spectrum data existing within an error range and exceeding a target time.
7 is a graph showing a case where an object count rate is greater than a reference count rate.
8 is a graph in which a gain value is adjusted when an object count rate is equal to or similar to a reference count rate.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like elements in the drawings are indicated by like symbols wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

As shown in FIGS. 1 and 2, the temperature compensation method of the radiation spectrum for discriminating radionuclides of the present invention uses background radiation energy spectrum data measured by the radiation detector 100 in an environment without an object for discriminating radioactive nuclides. It starts from the step of receiving and storing the transmission (S10).

An environment in which there is no object for determining radionuclides refers to an environment in which only natural radiation is emitted. That is, radiation of a size below a certain level does not significantly affect the human body. As is well known, fine radiation that does not affect the human body is emitted in the natural world, which is called natural radiation, and a state in which only natural radiation is emitted is called a background state.

The radiation detector 100 may be a scintillator type detector such as NaI(Tl). As is well known, when radiation is incident, the radiation detector 100 converts it into an electrical signal, amplifies the size, and removes noise to convert it into an analyzable signal. The converted signal is expressed in a pulse form, and the pulse is counted and stored according to the magnitude of the voltage value. Each process of counting the pulses of each voltage value and cumulatively managed for a certain period of time in the allocated buffer is called energy, and through this process, radiation energy spectrum data represented by count values (counting values) according to energy values can be obtained. .

The radiation detector 100 measures radiation in an environment in which there is no object for determining radioactive nuclides, that is, in a background state, obtains background radiation energy spectrum data (referred to as "background spectrum data"), and then outputs the result.

The background spectrum data is transmitted to the nuclide determination unit 200 electrically connected to the radiation detector 100 . The nuclide determination unit 200 performs functions such as input, calculation, control, storage, and output, and accumulates and stores background spectrum data transmitted from the radiation detector 100.

For example, the nuclide determination means 200 may be a multi-wave analyzer (MCA). As is well-known, the multi-wave analyzer is a device that classifies, collects, stores, and outputs background spectrum data, which is a pulse signal output from the radiation detector 100, by pulse height in a continuous execution method of a single channel analyzer. It consists of a device and a display device, and divides and designates data storage by range of pulse size to be analyzed. When a certain pulse is output, it digitizes the pulse size and adds it to the designated data storage corresponding to the number.

The nuclide discrimination means 200 may be a configuration in which the algorithm for performing the temperature compensation of the present invention is loaded in such a multiple wave height analyzer (MCA). Alternatively, the nuclide determination means 200 may be a computer means equipped with an algorithm for performing temperature compensation of the present invention and an existing multi-wave analyzer (MCA) electrically connected to the computer means.

The nuclide determination unit 200 calculates and stores a reference count center value and a reference count rate from the background spectrum data transmitted by the radiation detector 100 (S20). The nuclide discrimination means 200 calculates and stores the reference count center value and the reference count rate by calculating the accumulated background spectrum data for a predetermined period of time.

CountCenter means a channel that is balanced according to the count distribution in the same principle as the center of gravity (the position where balance is achieved according to the weight distribution) used as an important factor in load design, etc., and the count center value is the accumulated radiation energy It can be obtained through spectrum data, and its formula can be expressed as Equation 1 below.

는 채널(Ch)과 스펙트럼 i번째 채널 카운트값(Cnt_i)을 곱한 합이고,

는 스펙트럼 i번째 채널 카운트값(Cnt_i)의 합이다. 계수율은 카운트값들의 합을 시간으로 나누면 구할 수 있다.here,

Is the sum of the product of the channel (Ch) and the spectrum i-th channel count value (Cnt _i ),

Is the sum of the i-th channel count values (Cnt _i ) of the spectrum. The count rate can be obtained by dividing the sum of count values by time.

3 is a graph of background spectrum data (count value per channel) accumulated for 300 seconds, and the count center value (C.C) of the accumulated measured background spectrum data calculated by Equation 1 and the count rate formula is 113.57 channels (ch) , and the count rate is 583.0cps.

The values calculated in this way become reference values for performing temperature compensation, and are values obtained in a state in which a gain of 1.386 is preset in the nuclide determination unit 200. The cumulative measurement time of 300 seconds means the target time and is the minimum time to implement temperature compensation in software.

The initially set gain value (Gain) becomes a reference value for adjusting the gain for temperature compensation in the subsequent process, and the nuclide discrimination means 200 is the background spectrum data accumulated for 300 seconds for the target time in the state where the gain value (Gain) is set. Calculate the reference count center value (C.C) and the reference count rate (Count rate) through

When the reference count center value and the reference count rate are calculated from the background spectrum data, the nuclide discrimination means 200 deletes and initializes the accumulated background spectrum data (S30).

When the accumulated and stored background spectrum data is deleted and initialized, the nuclide determination means 200 determines the object radiation energy spectrum data measured by the radiation detector 100 in the environment where the object for determining radioactive nuclides is present (hereinafter referred to as “object spectrum data”). ) is transmitted and stored. At this time, the gain value (Gain) does not fluctuate at 1.386.

The nuclide discrimination means 200 cumulatively measures and stores the object spectrum data for a set period, and applies Equation 1 and the count rate formula from the object spectrum data accumulated at every cycle to accumulate and calculate the object count center value and object count rate Do (S40).

As illustrated in FIG. 4, when the object spectrum data is set to be measured at 1-second intervals for 15 seconds (minimum calculation time), the nuclide determination unit 200 accumulates and measures the object spectrum data at 1-second intervals and stores the object spectrum data. The count center value (C.C) and object count rate (Count rate) are cumulatively calculated and stored, but this process is repeated for 15 seconds. The minimum calculation time of 15 seconds is the minimum calculation time to calculate the meaningful object count center value and object count rate that can calculate the gain value for temperature compensation.

If the object spectrum data is not cumulatively measured for 15 seconds, so that each accumulated value for the object count center value and the object count rate cannot be calculated (S50), the nuclide determination unit 200 feeds back to step S40 to obtain the object spectrum data again Cumulative measurement is performed for 15 seconds (minimum calculation time) at intervals of 1 second. At this time, the nuclide determination means 200 may calculate the accumulated value by accumulating newly measured data with the currently accumulated data, resetting the currently accumulated data by deleting the stored data, and measuring the object spectrum data again to calculate the accumulated value. can be calculated

When the object count center value and the object count rate are calculated through the above process, the nuclide determination unit 200 compares the reference count center value and the object count center value (S60).

The nuclide determination means 200 compares the object count center value with the reference count center value based on the error range of 5%, and if the object count center value exists within ±5% of the error range compared to the reference count center value, the nuclide determination means ( 200) deletes and initializes the accumulated measured and stored object spectrum data and each calculated value, and then cumulatively measures the object spectrum data from the radiation detector 100 to cumulatively calculate the object count center value and object count rate.

As illustrated in FIG. 5, the calculated object count center value is 110.6 channels (ch) and exists within ±5% of the reference count center value 113.57 channels (ch), and the nuclide determination means 200 initializes the current accumulated data After that, the object spectral data from the radiation detector 100 may be accumulated and measured to cumulatively calculate the object count center value and the object count rate.

At this time, the nuclide determination means 200 may perform a process of recalculating the object count center value and the object count rate by determining whether the cumulative measurement time of the object spectrum data exceeds the target time (S70).

That is, if the cumulative measurement time is less than the target time, the nuclide determination unit 200 may cumulatively measure the object spectrum data from the radiation detector 100 by feeding back to step S40 to calculate the object count center value and the object count rate.

If the cumulative measurement time is equal to or longer than the target time, the nuclide determination means 200 returns to step S30 to delete and initialize the cumulatively measured and stored object spectrum data and each calculated value, and then accumulate the object spectrum data from the radiation detector 100 again. By measuring, the object count center value and the object count rate can be cumulatively calculated.

As illustrated in FIG. 6, when the cumulative measurement time reaches the target time of 300 seconds, the nuclide determination unit 200 feeds back to step S30 to initialize the data, and then accumulates and measures object spectrum data from the radiation detector 100 again. Calculate the object count center value and object count rate.

If the object count center value exceeds the error range of 5% compared to the reference count center value, the nuclide determination means 200 compares the reference count rate and the object count rate (S80). The object count rate is a cumulative value when the measurement period is set as described above.

The nuclide determination means 200 compares the reference count rate and the object count rate based on 10%, and if the object count rate exceeds 10% of the reference count rate, radionuclide discrimination is performed, and if the object count rate is less than 10% of the standard count rate , the gain value for temperature compensation is adjusted based on the temperature effect (S90).

As illustrated in FIG. 7, when the object count rate is 843.0cps and exceeds 10% of the reference count rate of 583.0cps, the nuclide determination means 200 proceeds to determine the radionuclide, and as illustrated in FIG. 8, the object count rate If 581.5cps is 10% or less compared to the reference count rate of 583.0cps, the nuclide determination unit 200 calculates a gain value (setGain) for temperature compensation and adjusts the gain.

The adjusted gain value (setGain) is calculated by multiplying the value obtained by dividing the reference count center value by the object count center value by the preset gain value (Gain), and can be expressed by Equation 2 below.

Here, setGain is an adjusted gain value, Gain is a preset gain value, refC.C is a reference count center value, and C..C is an object count center value.

Referring to FIG. 8, the gain value (setGain) is preferably calculated when the object count rate is equal to or similar to the reference count rate, the object count center value is 99.6ch, the preset gain value (Gain value) is 1.386, and the reference If the count center value is 113.57ch, the nuclide determination means 200 calculates 1.386×(113.57/99.6) to calculate a gain value (setGain) of 1.5804.

When the gain value (setGain) is calculated, the nuclide determination unit 200 adjusts and sets the previously set gain value (Gain) to the newly calculated gain value (setGain), and then feeds back to step S30 to delete all data and initialize it. After that, steps S40 to S90 are repeatedly performed, and repetition is performed until the object count rate exceeds 10% of the reference count rate.

As described above, according to the present invention, the temperature compensation for the radiation energy spectrum is performed with a software technology rather than a temperature compensation with a hardware technology using a thermometer or an LED, but the temperature compensation is made in about 15 seconds. As such, the blank time for calibration (as much as the measurement time) is greatly reduced, and the nuclide can be quickly identified, and the operation processor can be driven with low power, so it can be applied to small or portable equipment.

The present invention has been examined with a focus on preferred embodiments, and those skilled in the art can implement embodiments of a different form from the detailed description of the present invention within the essential technical scope of the present invention. You will be able to. Here, the essential technical scope of the present invention is shown in the claims, and all differences within the equivalent range should be construed as being included in the present invention.

100: radiation detector
200: nuclide determination means

Claims (4)

A first step of receiving and storing background radiation energy spectrum data measured by a radiation detector in an environment without an object for determining radioactive nuclides;
a second step of calculating and storing a reference count center value and a reference count rate from the background radiation energy spectrum data;
a third step of receiving and storing the radiation energy spectrum data of the object measured by the radiation detector in an environment where the object for determining radioactive nuclides is present;
a fourth step of calculating and storing an object count center value and an object count rate from the object radiation energy spectrum data;
a fifth step of comparing the reference count center value and the object count center value; and
A sixth step of comparing the reference count rate and the object count rate and adjusting a gain value for temperature compensation when the object count center value exceeds a preset error range with respect to the reference count center value,
The temperature compensation method of the radiation spectrum for determining the nuclide, wherein the third step to the sixth step are repeatedly performed and the radiation energy spectrum for the determination of the nuclide is temperature compensated.
According to claim 1,
In the sixth step, if the object count center value exceeds an error range of 5% compared to the reference count center value, the reference count rate and the object count rate are compared.
According to claim 1,
In the sixth step, if the object count rate is 10% or less compared to the reference count rate, the gain value is adjusted.
According to claim 1,
In the sixth step, the gain value is calculated by multiplying the value obtained by dividing the reference count center value by the object count center value by the preset gain value in the first step.

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