JP5751646B2 - Radioactivity measuring device - Google Patents

Description

  The present invention relates to a radioactivity measurement apparatus.

  2. Description of the Related Art Conventionally, there are known radiation measuring instruments that display a plurality of trend graphs showing temporal changes in radiation dose on the time axis and appropriately expand and contract the time region. (For example, refer to Patent Document 1).

JP 11-248840 A

By the way, according to the radiation measuring instrument according to the above-described prior art, only a plurality of trend graphs are displayed in a single scale so as to maintain temporal continuity, and a plurality of trend graphs are compared in detail. The problem is that it is difficult to do.
The present invention has been made in view of the above circumstances, and an object thereof is to provide a radioactivity measurement apparatus capable of easily comparing a plurality of spectra.

In order to solve the above problems and achieve the object, the present invention employs the following aspects.
(1) A radioactivity measurement apparatus according to an aspect of the present invention includes a radiation detector that detects radiation emitted from a sample (for example, the radiation detector 15 in the embodiment), and at least once by the radiation detector. A storage unit for storing a plurality of energy spectra including the energy spectrum of the radiation by detection of a plurality of energy spectra selected from among the plurality of energy spectra stored in the storage unit ( For example, the output device 12) in the embodiment, and processing means (for example, the processing device 13 in the embodiment) for controlling the display of a plurality of energy spectra of the radiation on the display device, the processing means in the above display device, the plurality of independent energy and count energy spectrum in each scan In conjunction between said plurality of energy spectra in a state of displaying side by side in Lumpur, the same energy position by cursor direction, enlargement and reduction of the same display area, and the whole peak area of the target species, the total absorption peak area The base area is colored and displayed for the lower background area and the total absorption peak area away from the background area .

(2) In the radioactivity measurement apparatus according to (1), the processing unit performs a process of analyzing a plurality of energy spectra of the radiation, and displays the result of the process on the display device.

(3) the radioactivity measuring apparatus according to (1) or (2), said processing means in the display device, in a state of displaying side by side on a scale of independent energy and count to each of the plurality of energy spectra The order of arrangement of the plurality of energy spectra may be changed.

(4) The radioactivity measuring apparatus according to any one of (1) (3), said processing means in the display device, the scale of the independent energy and count to each of the plurality of energy spectra In the state of displaying side by side, the plurality of energy spectra may be linked to change to the same scale type.

(5) the radioactivity measurement apparatus according to any one of (1) (4), said processing means in the display device, the scale of the independent energy and count to each of the plurality of energy spectra You may switch between the state of displaying side by side and the state of displaying the plurality of energy spectra in a single scale.

(6) The radioactivity measuring apparatus according to any one of (1) (5), in the processing means said display device, independent to each of at least three or more of said plurality of energy spectral energy And they may be displayed side by side on the scale of the count .

According to the radioactivity measuring apparatus according to the aspect described in (1) above, it is possible to easily compare a plurality of energy spectra, and to easily discriminate and detect even complex energy spectra. .
In the case of (2) to (6) above, convenience when comparing a plurality of energy spectra can be improved.

It is a block diagram of the radioactivity measuring apparatus which concerns on embodiment of this invention. It is a figure which shows an example of the separate display screen of the radioactivity measuring apparatus which concerns on embodiment of this invention. It is a figure which shows an example of the whole display screen of the radioactivity measuring apparatus which concerns on embodiment of this invention. It is a figure which shows an example of the comparison display of the analysis result in the separate display screen of the radioactivity measuring apparatus which concerns on embodiment of this invention.

Hereinafter, a radioactivity measurement apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings.
As shown in FIG. 1, the radioactivity measurement apparatus 10 according to the present embodiment includes an input device 11, an output device 12, a processing device 13, a pulse height analyzer 14, and a radiation detector 15.
The input device 11 includes, for example, various switches and a keyboard that output signals according to the input operation of the operator, and transmits various command signals according to the input operation of the operator to the processing device 13.
The output device 12 includes a speaker and a display device, and outputs various types of information received from the processing device 13.

The wave height analyzer 14 is, for example, a multi-channel analyzer, and calculates the wave height distribution of the output signal pulse output from the radiation detector 15, that is, the count value for each of a plurality of channels set according to the wave height value. For example, when an output signal pulse having a peak value corresponding to the energy of radiation emitted from the sample is output from the radiation detector 15, the pulse height analyzer 14 uses the energy distribution as the pulse height distribution of the output signal pulse of the radiation detector 15. Create a spectrum.
The radiation detector 15 is a semiconductor detector such as germanium, and detects radiation (for example, γ-rays, X-rays, etc.) emitted from the sample.

The processing device 13 includes a storage unit 21 and a calculation unit 22.
The storage unit 21 stores, for example, various types of preset data, calculation result data of the calculation unit 22, data output from the wave height analyzer 14, and the like. The various types of data set in advance are, for example, nuclear data of a plurality of nuclides (for example, energy of emitted radiation) and peak efficiency data at the energy of all absorption peaks of the radiation detector 15.

  The calculation unit 22 uses the nuclear data of a plurality of nuclides stored in the storage unit 21 and the peak efficiency data at the energy of all absorption peaks of the radiation detector 15 to detect the radiation detected by the radiation detector 15. Automatically analyze the energy spectrum of. The calculation unit 22 searches for the total absorption peak and total absorption from the energy spectrum of the radiation collected cumulatively at a plurality of timings with a predetermined monitoring interval during the period in which the radiation detector 15 detects the radiation. The identification of the nuclide corresponding to the peak and the radioactivity of the nuclide are automatically performed.

The processing device 13 can simultaneously display a plurality of (for example, three or more) energy spectra of the radiation detected by the radiation detector 15 on the display device of the output device 12. As shown in FIG. 2, the processing device 13 has an individual display state in which a plurality of energy spectra are arranged and displayed on an independent scale, and a plurality of energy spectra are superimposed on a single scale as shown in FIG. To change the status of the entire display.
For example, as illustrated in FIGS. 2 and 3, the processing device 13 includes a button 32 a for instructing individual display and a button 32 b for instructing overall display on the spectrum comparison screen 31. The tab 32 is displayed.

In the individual display state, the processing device 13 has a plurality of individual display areas (for example, four individual display areas 33a to 33d) arranged in the vertical direction of the screen in the spectrum display area 33 as shown in FIG. Set. In each of the plurality of individual display areas, the processing device 13 arranges the energy spectra so that the energy scales (Channels) coincide with each other in the horizontal direction of the screen and the counting scales (Counts) are arranged in the vertical direction of the screen. To display.
The processing device 13 can arbitrarily select each energy spectrum to be displayed in each individual display area from the storage unit 21, sets any one of the selected plurality of energy spectra as a reference energy spectrum, and others It can be displayed separately from the energy spectrum. For example, the processing device 13 sets the background color of the reference energy spectrum so as to be different from the background color of the other energy spectrum, and also selects a specific individual display area (for example, in the vertical direction of the screen) from the plurality of individual display areas. The individual display area 33a in the uppermost stage is set as a display area dedicated to the reference energy spectrum. Furthermore, the processing device 13 displays the name of the energy spectrum data set as the reference energy spectrum on the reference spectrum display tab 34.

As shown in FIG. 3, the processing device 13 in the entire display state has a single energy scale (Channel) in the horizontal direction of the screen and a single count scale in the vertical direction of the screen in the spectrum display region 35. A plurality of (for example, four) energy spectra are displayed with respect to (Counts).
The processing device 13 can arbitrarily select a plurality of energy spectra to be displayed in the spectrum display area 35 from the storage unit 21, and sets the display colors of the selected energy spectra to be different. The processing device 13 sets any one of the selected plurality of energy spectra as the reference energy spectrum, distinguishes it from other energy spectra, and sets the name of the energy spectrum data set as the reference energy spectrum. The reference spectrum is displayed on the display tab 34.

The processing device 13 displays the result obtained by analyzing and analyzing each energy spectrum for each comparison when displaying a plurality of energy spectra for comparison in the individual display state and the entire display state. Alternatively, analysis and analysis may be performed in advance, and results stored in the storage unit 21 may be displayed.
In addition, the processing device 13 compares a plurality of energy spectra having different contents of analysis and analysis, such as differences in nuclear data used for analysis and analysis, search sensitivity of all absorption peaks, and background spectra acquired in advance. May be displayed.

In the individual display state, the processing device 13 is linked between a plurality of energy spectra, indicates the same energy position by the cursor bar C, enlarges and reduces the same display area, displays the same energy area in color, and performs the same analysis process. A comparison display of the processing results is performed.
For example, as shown in FIG. 4, the processing device 13 sets the type of the counting scale (Counts) between the linear scale and the logarithmic scale in conjunction with the plurality of energy spectra on the spectrum comparison display screen 41. A button 42 for instructing switching is displayed. Further, the processing device 13 is linked with a plurality of energy spectra, and a button 43 for instructing the enlargement / reduction of the counting display area or the energy display area, and the display form (dot display, line display) of the energy spectrum. , And a bar display) button 44 for instructing switching. Furthermore, the processing device 13 is linked between a plurality of energy spectra, and only the predetermined energy range before and after the total absorption peak corresponding to the nuclide identified by the analysis processing or the total absorption peak corresponding to the preset target nuclide. A check box 45 for instructing to enlarge and display is displayed.

As a result, when the appropriate nuclide N1 is selected on the screen 46 for comparing and displaying the processing results of the analysis processing for a plurality of energy spectra, the processing device 13 is linked to the nuclide N1 in conjunction with the plurality of energy spectra. Only the predetermined energy range before and after the corresponding total absorption peak is enlarged and displayed.
Further, the processing device 13 sets the peak shape and the total absorption peak region 51 by the function fitting and the background set for the total absorption peak with respect to the total absorption peak searched by the analysis processing for each of the plurality of energy spectra. Each of the region 52 and the base region 53 is colored and displayed in conjunction with a plurality of energy spectra. In this case, as shown in FIG. 4, between the plurality of energy spectra, each of the peak shape by function fitting, the background region 52 set for all absorption peaks, and the base region 53 has the same analysis and Even if the analysis processing is performed, the results are not necessarily the same, and different results may be obtained.

  Note that the processing device 13 can change the arrangement order of a plurality of energy spectra in the individual display state. For example, the display position of the reference energy spectrum can be changed from the individual display region 33a at the uppermost stage in the vertical direction of the screen. The individual display areas 33b to 33d may be changed.

  As described above, according to the radioactivity measurement apparatus 10 according to the present embodiment, it is possible to easily compare a plurality of energy spectra, and to easily discriminate and detect even complex energy spectra. it can. Furthermore, convenience when comparing a plurality of energy spectra can be improved.

  The above-described embodiments are presented as examples, and are not intended to limit the scope of the invention. The above-described novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. The above-described embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  For example, in the above-described embodiment, the radiation detector 15 is a semiconductor detector such as germanium, but is not limited thereto, and may be another detector such as a scintillation detector.

DESCRIPTION OF SYMBOLS 10 ... Radioactivity measuring device 11 ... Input device 12 ... Output device (display device) 13 ... Processing device (processing means) 14 ... Wave height analyzer 15 ... Radiation detector 21 ... Memory | storage part 22 ... Calculation part

Claims (6)

A radiation detector for detecting radiation emitted from the sample;
A storage unit for storing a plurality of energy spectra including an energy spectrum of the radiation by at least one detection by the radiation detector;
A display device that displays a plurality of energy spectra selected from the plurality of energy spectra stored in the storage unit ;
Processing means for controlling display of a plurality of energy spectra of the radiation on the display device;
With
The processing means in said display device,
In a state where the plurality of energy spectra are displayed side by side at independent energy and count scales, the plurality of energy spectra are linked to each other to indicate the same energy position by a cursor, enlargement and reduction of the same display area, and target Coloring display of the base region for the total absorption peak region of the nuclide, the background region below the total absorption peak region, and the total absorption peak region away from the background region ,
A radioactivity measuring apparatus characterized by that. The processing means executes a process of analyzing a plurality of energy spectra of the radiation, and displays a result of the process on the display device.
The radioactivity measuring apparatus according to claim 1. The processing means in said display device,
Changing the arrangement order of the plurality of energy spectra in a state in which the plurality of energy spectra are displayed side by side at independent energy and count scales;
The radioactivity measurement apparatus according to claim 1 or claim 2, wherein The processing means in said display device,
In a state where the plurality of energy spectra are displayed side by side with independent energy and count scales, the energy spectra are linked to each other and changed to the same scale type.
The radioactivity measurement apparatus according to any one of claims 1 to 3, wherein The processing means in said display device,
Switching between a state in which the plurality of energy spectra are displayed side by side at independent energy and count scales, and a state in which the plurality of energy spectra are displayed in a single scale.
The radioactivity measuring apparatus according to any one of claims 1 to 4, wherein The processing means in said display device,
Displaying at least three or more of the plurality of energy spectra side by side on independent energy and count scales, respectively.
The radioactivity measurement apparatus according to any one of claims 1 to 5, wherein

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