KR102049518B1 - An imaging device that combines gamma-ray images with visual optical camera images - Google Patents

Abstract

The present invention relates to an imaging device for fusing a gamma-ray image and a visual optical camera image. More specifically, the imaging device for fusing a gamma-ray image and a visual optical camera image visually provides numerical information of a radiation dose and position information remotely separated from a radioactive material to help in promoting safety of workers or ordinary people from the danger of the radioactive material, calculates the reaction position of the radioactive material by calculation program software stored in a computer to crease a gamma-ray image, then fuses the image with a visual optical camera image to check the gamma-ray image and the visual optical camera image on a computer monitor with naked eyes, and implements acquisition, storage, and analysis functions of gamma-ray image data, acquisition and analysis functions of a gamma-ray spectrum, a measurement image transmission function, information acquisition, storage, and analysis functions by time/radiation dose, a screen recording function, a screenshot function, a distance display function between an imaging device and a body to be measured, and an imaging device rotating function in the imaging device by a software program for image reconstruction to fuse two types of images inputted from a gamma camera and an optical camera to accurately represent the position of a real radioactive material in real time.

Description

An imaging device that combines gamma-ray images with visual optical camera images}

The present invention visually provides the remote location information for the radioactive material as well as the numerical information of the radiation dose, can help to promote the safety of workers or the public from the danger of radioactive material, stored in a computer computing program The software calculates the reaction site of the radioactive material into a gamma ray image, and then visualizes this image with a visual optical camera image and visually checks it on a computer monitor.The actual radioactivity is obtained by fusing two images input from a gamma camera and an optical camera. Acquisition, storage and analysis of gamma ray image data, acquisition and analysis of gamma ray spectrum, measurement image transmission function, and acquisition, storage and analysis of information by time and radiation dose through image reconstruction software program to accurately represent the location of materials in real time. group A screen recording function, description of the imaging device to fuse a screenshot function, the imaging device and the distance between the measurement target object display function, an image rotation device features a gamma ray, which can be implemented on the imaging device and the visual image optical camera image.

With the development of radiation application technology, the demand for the use of radiation is continuously increasing, and in connection with this, there is an increasing demand for the safe use of radiation that cannot be immediately detected by the human sense.

In particular, methods for finding unknown or lost radiation sources have been steadily developed in places where radiation is constantly used, but finding these unknown sources still requires a lot of time and effort. For the safety of workers in areas where there is a constant exposure to radiation sources, the development of radiation source position detection technology to detect and monitor the radiation source has been used to monitor and leak radioactive contamination in various fields using radiation. It is very important and necessary situation for the safety of the radiation worker and the general public because it is to determine the occurrence location.

Due to the 2011 Fukushima nuclear accident, there is a growing interest in radioactivity around the world, and the demand for the development of precise radiation detectors for accurately measuring and analyzing the radioactivity of radioactive materials and regions is rapidly increasing.

As in the case of Fukushima nuclear power plant, in case of serious accident, there is a need for a next-generation radiographic surveillance system that can effectively detect the radiation level distribution and real-time image of the sites around major facilities in the nuclear power plant and effectively respond to the radiation threat in the field. have.

In addition, in case of a radioactive leakage accident or decommissioning operation of a nuclear power plant, an operator should directly input the site and measure it with a portable radiometer to determine the degree of contamination of radioactive material and accurate location information of the source.

At this point, workers are exposed to significant time radiation exposure, which inevitably leads to a lot of manpower and high costs due to the narrow work site.

Since radiation monitors and measuring instruments currently used in the workplace provide only numerical information on measured doses, it is difficult to determine the cause of contamination of radioactive materials and to determine the exact location of the source.

Therefore, the computational location of the radioactive material can be calculated by using computer-generated program software to produce gamma-ray images, which can then be visually visualized on a computer monitor by combining them with visual optical camera images. The development of an imaging device that combines gamma-ray images and visual optical camera images that can help the safety of workers and the public from the danger of radioactive materials is provided by providing remote location information about materials. It is true.

KR 10-2016-0071597 (June 9, 2016)

The present invention has been conceived to solve the above problems, and visually provides not only the numerical information of the radiation dose but also the remote location information for the radioactive material, thereby helping to promote the safety of workers or the public from the danger of radioactive material. It is an object of the present invention to provide an image device for fusing a gamma ray image and a visual optical camera image.

It is another object of the present invention to calculate gamma-ray images by calculating the reaction positions of radioactive materials using computational program software stored in a computer, and then fused these images with visual optical camera images to visually check the gamma-ray images and visual images on a computer monitor. The present invention provides an imaging apparatus that fuses an optical camera image.

Another object of the present invention is to acquire, store, and analyze gamma ray image data through a software program for image reconstruction so that the actual position of radioactive material is accurately expressed in real time by fusing two images input from a gamma camera and an optical camera. Acquisition and analysis of spectrum, transmission of measured image, acquisition and storage and analysis of information by time and radiation dose, screen recording, screenshot function, distance display between imaging device and measuring object, rotation of imaging device An object of the present invention is to provide an image apparatus that can be implemented with a gamma ray image and a visual optical camera image.

According to a preferred embodiment of the present invention, an image apparatus for fusing a gamma ray image and a visual optical camera image is manufactured in the form of an encoded pattern mask to react to a scintillator, and the encoded pattern is a MURA pattern. The pattern is arranged in a 2 × 2 matrix form made of tungsten, the pixel size of the pattern has a size of 1 to 1.5 mm, the radioisotope far away from the invisible radiation An encoding aperture collimator for aiming incident the gamma ray emitted from the element to react with the scintillator and rotating the unit by 90 ° in connection with a rotating motor; It is an array type of GAGG scintillator, and the material of the scintillator may be an organic scintillator of GAGG semiconductor crystal or plastic scintillator, and the inner surface of the scintillator is transferred so that the gamma-ray information converted from the GAGG scintillator to the silicon semiconductor optical sensor is transmitted. A scintillator which is painted in white with good reflection and reacts with the gamma ray passing through the encoding aperture collimator to generate a fine light signal; It is an array-type semiconductor optical sensor and can be implemented as SiPM (Silicon Photomultiplier) or PMT (Photomultiplier Tube), and the total output signal is 12 horizontally and 12 vertically by applying 9 optical sensors in 4 × 4 array. A semiconductor optical sensor for outputting two signals and converting gamma-ray information converted from the scintillator to light into minute electric signals according to the amount of light; An analog circuit unit for reducing the signal into four signals by applying a method of differential summing through a channel reduction circuit designed as a diode chain because it is difficult to simultaneously process all 144 signals output from the semiconductor optical sensor into minute analog signals; Four analog signals amplified and processed through the preamplifier of the analog circuit unit are converted into digital signals through a four-channel ADC (Analog to Digital Convertor) board, and the signal and noise are converted using an FPGA (Field Programmable Gate Array) board. A digital circuit unit for classifying and constructing a basic video signal to transfer data to a computer at high speed; The operating power of the optical camera is 5 VDC, using a high-definition MJPEG 60 fps resolution 1280 (H) × 720 (V) camera, and processing the reaction location of the radioactive material as an image by calculating with a computer program software. An optical camera for photographing a visual image to be fused with the gamma ray image and adjusting the image to be realized even in low light; A computer program for calculating a reaction position of the radioactive material and editing the gamma ray image, wherein the computer allows the user to visually check the visual image fused with the gamma ray image through a monitor; An operating power of the range finder is 3 VDC, the measuring distance of which can be measured up to 50 m from the imaging device, and is attached to the imaging device to accurately measure the distance between the imaging device and the measurement object; Manufactured in the form of battery and power board, it is attached to the image device. It receives 12 VDC and outputs +5, -5, +3.3 VDC and +10 ~ 80 VDC and supplies power to all modules in the image device. A power unit; A fan attached to the imaging apparatus and configured to discharge heat generated from the imaging apparatus to the outside of the imaging apparatus; Characterized in that it comprises a.

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In the present invention, the four signals reduced in the analog circuit portion is characterized in that it is configured to pass through the preamplifier for signal amplification and waveform processing.

In the present invention, the chip used in the four-channel ADC (Analog to Digital Convertor) board of the digital circuit is capable of sampling at a resolution of 14 bits and 66.6 MHz, FPGA (Field Programmable Gate Array) board is a high-speed data It uses a USB 3.0 interface to transfer the data to a computer.

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As described above, the imaging apparatus of the present invention fusing a gamma ray image and a visual optical camera image has the following effects.

First, the present invention visually provides the remote location information for the radioactive material as well as the numerical information of the radiation dose can help to promote the safety of workers or the public from the risk of radioactive material.

Second, the present invention calculates the reaction position of the radioactive material into a gamma-ray image by calculating the calculation program software stored in the computer, and then the image can be visually confirmed on a computer monitor by fusing the image with a visual optical camera image.

Third, the present invention acquires, stores and analyzes gamma ray image data through gamma ray spectrum through image reconstruction software program that fuses two images input from a gamma camera and an optical camera to accurately represent the position of a radioactive material in real time. Image acquisition and analysis function, measurement image transmission function, hourly / radiation dose information acquisition and storage and analysis function, screen recording function, screenshot function, distance display between image device and measuring object, image device rotation function Can be.

1 is a block diagram showing the configuration of an image device for fusing a gamma ray image and a visual optical camera image according to an embodiment of the present invention.
2 is a view showing the shape of an image device for fusing a gamma ray image and a visual optical camera image according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating an encoding aperture collimator having a 2 × 2 matrix form in a configuration of an imaging apparatus in which a gamma ray image and a visual optical camera image are fused according to an embodiment of the present invention. FIG.
4 is a diagram illustrating a scintillator and a silicon semiconductor optical sensor in the configuration of an imaging apparatus that fuses a gamma ray image and a visual optical camera image according to an embodiment of the present invention.
FIG. 5 is a view showing a 144: 4 channel reduction circuit and a preamplification circuit in the configuration of an imaging apparatus that fuses a gamma ray image and a visual optical camera image according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating a four-channel ADC and an FPGA circuit in a configuration of an imaging apparatus in which a gamma ray image and a visual optical camera image are fused according to an embodiment of the present invention. FIG.
FIG. 7 is a diagram illustrating a gamma ray measurement (central red dot) screen and a spectrum analysis screen below on an imaging apparatus fusing a gamma ray image and a visual optical camera image according to an embodiment of the present invention.

Looking at the preferred embodiment of the present invention together with the accompanying drawings as follows, when it is determined that the detailed description of the known art or configuration related to the present invention may unnecessarily obscure the subject matter of the present invention The description will be omitted, and the following terms are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or the operator, and the definition is a fusion of a gamma ray image and a visual optical camera image of the present invention. It should be made based on the contents throughout the present specification for describing the imaging device.

Hereinafter, an image apparatus for fusing a gamma ray image and a visual optical camera image according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the configuration of an image device for fusing a gamma ray image and a visual optical camera image according to an embodiment of the present invention, Figure 2 is a gamma ray image and a visual optical camera image according to an embodiment of the present invention 3 is a view illustrating a shape of an image device to be fused, and FIG. 3 is a view illustrating a coding aperture collimator having a 2 × 2 matrix form among components of an image device that fuses a gamma ray image and a visual optical camera image according to an embodiment of the present invention. 4 is a view showing a scintillator and a silicon semiconductor optical sensor in the configuration of an image device that fuses a gamma ray image and a visual optical camera image according to an embodiment of the present invention, and FIG. 5 is a gamma ray according to an embodiment of the present invention. 144: 4 channel reduction circuit and preamplification circuit of the configuration of the image device fusion image and visual optical camera image, Figure 6 is a view showing the invention Of the configuration of a video device that combines the gamma-ray image and a visual optical camera image according to one embodiment of a diagram showing a four channel ADC and FPGA circuit.

As shown in FIGS. 1 to 6, the imaging apparatus 200 that fuses a gamma ray image and a visual optical camera image according to the present invention may transmit energy from a gamma ray having high energy among invisible radiation to a distant place in the air. By using a phenomenon that can be aimed at the gamma ray emitted from the radioactive isotope far away to react to the scintillator 20, and is connected to the rotary motor 110 to rotate by 90 ° to the aiming coder aimer 10 ; A scintillator 20 which reacts with the gamma ray passing through the encoding aperture collimator 10 to generate a fine light signal; A semiconductor optical sensor 30 for converting gamma ray information converted from the scintillator 20 into light into a fine electric signal according to the amount of light; Since the 144 signals output from the semiconductor optical sensor 930 are difficult to process all as fine analog signals at the same time, the signal is reduced to four signals by applying a differential summation method through a channel reduction circuit 42 designed as a diode chain. An analog circuit unit 40; Four analog signals amplified and processed through the preamplifier 41 of the analog circuit unit 40 are converted into digital signals through a four-channel analog to digital converter (ADC) board 51, and a field programmable gate array (FPGA). A digital circuit unit 50 for distinguishing a signal from noise using a board 52 and composing a basic video signal to transfer data to a computer at high speed; The optical camera 70 calculates by using arithmetic program software stored in the computer 60 to capture a visual image of the reaction position of the radioactive material and the gamma-ray image processed as an image, and to realize the image even in low light Wow; Programmable software is stored for calculating the reaction position of the radioactive material and editing the gamma ray image, and the computer 60 allows the user to visually check the visual image fused with the gamma ray image through the monitor 61. Wow; A distance meter 80 attached to the imaging device 200 to accurately measure the distance between the imaging device 200 and the measurement object; A power supply unit 90 for supplying power to all modules in the imaging apparatus 200; A fan 100 attached to the imaging device 200 and configured to discharge heat generated from the imaging device 200 to the outside of the imaging device 200; It is provided.

Referring to the functions of the technical means constituting the imaging device fusion of the gamma ray image and visual optical camera image of the present invention as follows.

The encoding aperture collimator 10 uses a phenomenon in which gamma rays having high energy among invisible radiations can transfer energy to a far place in the air, thereby illuminating gamma rays emitted from radioisotopes far apart. Aiming to react to the reaction, it is connected to the rotary motor 110 to rotate by 90 °.

In addition, the encoding diameter collimator 10 is a mechanical focusing device that blocks high energy gamma rays, such as gamma rays, from entering in an undesired direction, and tungsten is mainly used.

Here, the coded aperture aimer 10 is manufactured in the form of a coded pattern mask to react with the scintillator 20, the coded pattern is applied as a MURA pattern, and the pattern is arranged in a 2 × 2 matrix form. And the pixel size of the pattern is 1 to 1.5 mm in size.

The scintillator 20 reacts with the gamma rays passing through the encoding aperture collimator 10 to generate a fine light signal.

Here, the scintillator 20 is an array-type GAGG scintillator, and the material of the scintillator may be a GAGG scintillator and a similar organic scintillator, and gamma-ray information converted from the GAGG scintillator to light is transferred to the silicon semiconductor optical sensor 30. If possible, the inner surface of the scintillator 20 is painted in white with good reflection.

The semiconductor optical sensor 30 converts gamma ray information converted into light from the scintillator 20 into minute electric signals according to the amount of light.

Here, the semiconductor optical sensor 30 is an array-type semiconductor optical sensor, by applying nine optical sensors in a 4 × 4 array to output a total of 144 signals in a total of 12 horizontal and 12 vertical signals. .

In addition, the semiconductor optical sensor 30 may be implemented as a silicon photomultiplier (SiPM) or a photomultiplier tube (PMT). The SiPM may be coupled to a small scintillator having a cross-sectional area of several mm 2 and thus may be combined with the scintillator 20. It will maximize the light-receiving performance of collecting the light emitted from.

Since the analog circuit unit 40 is difficult to simultaneously process all of the 144 signals output from the semiconductor optical sensor 930 as fine analog signals, a method of differentially summing signals through the channel reduction circuit 42 designed as a diode chain is applied. To reduce it to four signals.

Here, the four signals reduced by the analog circuit unit 40 are configured to pass through the preamplifier 41 for signal amplification and waveform processing.

The digital circuit unit 50 converts the four analog signals amplified and processed through the preamplifier 41 of the analog circuit unit 40 into digital signals through a four-channel analog to digital convertor (ADC) board 51. In this case, the field programmable gate array (FPGA) board 52 is used to distinguish signals from noise and to construct a basic video signal to transfer data to a computer at high speed.

Here, the chip used in the four-channel analog to digital converter (ADC) board 51 of the digital circuit unit 50 is capable of sampling at a resolution of 14 bit and 66.6 MHz, and has a field programmable gate array (FPGA) board 52. Is using the USB 3.0 interface 53 to transfer data to the computer at high speed.

The optical camera 70 captures a visual image to be fused with a gamma ray image processed as an image of the reaction position of the radioactive material by calculating with a calculation program software stored in the computer 60, so that the image can be implemented even in low light To adjust.

Here, the operating power of the optical camera 70 is 5 VDC, using a high-resolution MJPEG 60 fps resolution 1280 (H) × 720 (V) camera.

In addition, the software program acquires and stores gamma-ray image data, analyzes, acquires and analyzes gamma-ray spectrum, transmits measured images, and acquires, stores, and analyzes information by hourly and radiation dose, screen recording function, and screenshot function. The distance display function between the image device and the measurement object and the image device rotation function may be implemented in the image device 200.

The computer 60 stores a programmed software that calculates a reaction position of the radioactive material and edits the gamma ray image, and the user visually checks the visual image fused with the gamma ray image through the monitor 61. To ensure that

The distance measuring device 80 is attached to the imaging device 200 to accurately measure the distance between the imaging device 200 and the measurement object.

Here, the operating power of the range finder 80 is 3 VDC, the measuring distance can be measured up to 50 m from the imaging device 200.

The power supply unit 90 supplies power to all modules in the imaging apparatus 200.

Here, the power supply unit 90 is manufactured in the form of a substrate of a battery and a power board and attached to the imaging device 200, and receives 12 VDC and outputs +5, -5, +3.3 VDC and +10 to 80 VDC. It is.

The fan 100 is attached to the imaging apparatus 200 and discharges heat generated from the imaging apparatus 200 to the outside of the imaging apparatus 200.

FIG. 7 is a diagram illustrating a gamma ray measurement (central red dot) screen and a spectrum analysis screen below of an imaging apparatus that fuses a gamma ray image and a visual optical camera image according to an embodiment of the present invention. In the image apparatus that fuses the optical camera image, the central red dot on the upper screen is for measuring gamma rays, and the visible spectrum of the lower screen is for analyzing gamma ray information.

As described above, the imaging apparatus that combines gamma ray image and visual optical camera image can be applied to protect the safety from colorless, tasteless, and odorless radiation by workers in nuclear power plants or ordinary people living nearby. Do.

It will be appreciated by those skilled in the art that the present invention is not limited to the above embodiments, and that various modifications and changes can be made without departing from the spirit of the present invention.

10: encoding aperture aiming 20: scintillation body
30: semiconductor optical sensor 40: analog circuit
41: preamplifier 42: channel reduction circuit
50: digital circuit 51: ADC board
52: FPGA board 53: USB 3.0 interface
60: computer 61: monitor
70: optical camera 80: distance measuring instrument
90: power supply unit 100: fan (FAN)
110: rotating motor 200: video device

Claims (9)

An imaging apparatus for fusing a gamma ray image and a visual optical camera image,
Produced in the form of a coded pattern mask to react to the scintillator, the coded pattern is applied as a MURA pattern, the pattern is arranged in a 2 × 2 matrix form made of tungsten, the pixel size of the pattern Has a size of 1 to 1.5 mm, aims incident light to react to scintillant gamma rays emitted from a remote radioisotope among invisible radiation, and rotates by 90 ° in connection with a rotating motor. Aiming unit;
The array type GAGG scintillator, and the material of the scintillator may be a GAGG scintillator and a similar organic scintillator, and the inner surface of the scintillator is white to reflect well so that gamma-ray information converted from the GAGG scintillator to the light is transferred to the silicon semiconductor optical sensor. A scintillator which is painted and reacts with gamma rays passing through the coded aperture collimator to generate a fine light signal;
It is an array-type semiconductor optical sensor and can be implemented as SiPM (Silicon Photomultiplier) or PMT (Photomultiplier Tube), and the total output signal is 12 horizontally and 12 vertically by applying 9 optical sensors in 4 × 4 array. A semiconductor optical sensor for outputting two signals and converting gamma-ray information converted from the scintillator to light into minute electric signals according to the amount of light;
An analog circuit unit for reducing the signal into four signals by applying a method of differential summing through a channel reduction circuit designed as a diode chain because it is difficult to simultaneously process all 144 signals output from the semiconductor optical sensor into minute analog signals;
Four analog signals amplified and processed through the preamplifier of the analog circuit unit are converted into digital signals through a four-channel ADC (Analog to Digital Convertor) board, and the signal and noise are converted using an FPGA (Field Programmable Gate Array) board. A digital circuit unit for classifying and constructing a basic video signal to transfer data to a computer at high speed;
The operating power of the optical camera is 5 VDC, using a high-definition MJPEG 60 fps resolution 1280 (H) × 720 (V) camera, and processing the reaction location of the radioactive material as an image by calculating with a computer program software. An optical camera for photographing a visual image to be fused with the gamma ray image and adjusting the image to be realized even in low light;
A computer program for calculating a reaction position of the radioactive material and editing the gamma ray image, wherein the computer allows the user to visually check the visual image fused with the gamma ray image through a monitor;
An operating power of the range finder is 3 VDC, the measuring distance of which can be measured up to 50 m from the imaging device, and is attached to the imaging device to accurately measure the distance between the imaging device and the measurement object;
Manufactured in the form of battery and power board, it is attached to the image device. It receives 12 VDC and outputs +5, -5, +3.3 VDC and +10 ~ 80 VDC and supplies power to all modules in the image device. A power unit;
A fan attached to the imaging apparatus and configured to discharge heat generated from the imaging apparatus to the outside of the imaging apparatus; Imaging apparatus that comprises a gamma-ray image and a visual optical camera image comprising a. delete delete delete The method of claim 1,
And the four signals reduced by the analog circuit unit are configured to pass through a preamplifier for signal amplification and waveform processing. The method of claim 1,
The chip used in the four-channel analog to digital converter (ADC) board of the digital circuit part can sample at a resolution of 14 bit and 66.6 MHz, and the field programmable gate array (FPGA) board is used to transfer data to a computer at high speed. Imaging device for fusing a gamma ray image and a visual optical camera image, characterized by using a USB 3.0 interface. delete delete delete

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