RU116296U1 - MOBILE RADIO DEVICE WITH PRESENCE AND LOCATION OF RADIATION SOURCE DETECTOR - Google Patents

Abstract

1. A mobile radio device containing a housing containing a processor and a navigator connected to it, a data transmission module and sound signaling means, a program unit, a video matrix, a display, a power supply and sound signaling means, and it is equipped with a measuring matrix of two groups of radiation sensors located on one side of the body, made of the same number of sensors and their relative position in the group, while the program block is executed with the software of the procedures "Radiometer" to determine the spectrum and intensity of the study and "Visualization" to determine the location of the radiation source with subsequent visualization of its location on the display. ! 2. The mobile radio device according to claim 1, characterized in that the measuring matrix is made of two groups of four radiation sensors, placed symmetrically relative to the geometric middle of the side of the housing, and the sensors in each group are located at the points that are the vertices of a square formed by straight line segments connecting each of them with two adjacent sensors, and the software "Visualization" is made with the ability to determine the distances and azimuth angles between the radiation source and the plane of the sensor array. ! 3. The mobile radio device according to any one of claims 1 and 2, characterized in that it is equipped with a removable flash memory and an input device in the form of a touch screen. ! 4. A mobile radio device according to any one of claims 1 and 2, characterized in that it is equipped with a navigation device for determining position in space using GPS and / or GLONASS systems�

Description

The invention relates to DO-RA Vision mobile radio devices (mobile, cell phone, smartphone) equipped with auxiliary equipment, in particular to portable radio communication devices having a built-in module for measuring and processing measurement results in the form of a source presence and location detector radiation, i.e. Means of recording point (concentrated) radiation sources, in particular radioactive sources on the ground or on moving objects.

In connection with the disasters in Chernobyl and Fukushima-1, the world has significantly increased attention to the effects of radiation on the human body in the zone of radiation contamination, in border areas of infection, and in remote places where radioactive decay products may appear, carried by wind, rain, groundwater, river, seas and oceans. There are various designs of means for detecting and identifying radiation sources having an independent housing in which the equipment is located, and means of visual indication. However, providing all people with means of detecting radiation sources in the form of special mobile devices that require constant wear and each have their own individual means of power, alarm and indication, is neither convenient nor rational. In addition, the lack of information about the location of the radiation source makes it difficult to orient and search for the optimal path for moving people on the ground.

Known mobile phones in combination with built-in accessories.

Known cell phone, which uses a separately executed command device in the form of a case for a mobile phone, designed to convert the electrical signal from the electronic unit after the security sensor has been triggered, into a mechanical effect by means of an electromechanical unit on the key of the cell phone to signal an alarm, which is calling a subscriber using the “quick call” function of a cell phone, if it is possible to use GSM communication with the “blocking” function all incoming ”(RU No. 102282).

A well-known mobile (cellular) telephone with additional functions, comprising a transceiver (transceiver) for transmitting and receiving sound (means of sound signaling) and information signals, a signal processing circuit, which, when connected, is connected to a transceiver and a microprocessor to process signals transmitted and received by the transceiver, a storage device (memory unit), a keypad (keyboard), a display (monitor), a battery (power supply), a housing, it is additionally equipped with a built-in an additional special tool - an electron-optical module for measuring distances, areas, volumes and processing of measurement results, which during operation is connected to a signal processing circuit, keypad, display, battery, transceiver and microprocessor, made with the possibility of terminating the operation of the electron-optical module and save the results of his work when an incoming phone call. (RU No. 70434).

A mobile radio device is known that contains a housing in which a transceiver device and a processor are connected electrically connected to each other, to which a monitor, keyboard, memory unit, power supply and sound signaling devices are connected, the device is equipped with a semiconductor radiation detector, an amplifier and an interface unit connected in series, an output which is connected to a processor configured to generate sound and visual signals of the dosimeter and radiometer using the above-mentioned means audible alarm and monitor. The radiation detector is configured to measure alpha, beta, gamma and neutron radiation, as well as solar radiation. The processor is made with software for signaling the permissible, limit and unacceptable dose of radiation, determining the background radiation level, generating graphs of the state of human organs and systems depending on the accumulated radiation dose, and making recommendations for prevention, depending on the accumulated radiation dose, and also displaying on the monitor the corresponding informational visual messages in graphical, tabular, textual form; in addition, the processor is executed with ammnoy provision for signaling the permissible, limiting and unacceptable dose in the hourly, daily, weekly, monthly, annual interval. The keyboard contains additional keys for controlling the operation in the dosimeter-radiometer mode. The device is equipped with a navigation device for determining location in space using GPS and GLONASS systems. A radiation detector, an amplifier and an interface unit are placed in its housing; equivalently, a radiation detector, an amplifier and an interface unit can be placed in a removable-casing (RU No. 109625, prototype).

A disadvantage of the known mobile radio device is the narrowness of the functionality that does not provide a location of the radiation source.

The essence of the utility model consists in the fact that a mobile radio device comprises a housing in which a processor and a navigator connected to it, a data transmission module and sound alarm means, a program unit, a video matrix, a display, a power supply unit and sound alarm means are located, while it is equipped with a connected with a processor with a measuring matrix of two groups of radiation sensors placed on one side of the case, made identical in the number of sensors and their relative position in the group, while the program block is executed n with the program software procedures "Radiometer" for determining the spectrum and the radiation intensity, and "visualization" to determine the location of the radiation source with subsequent visualization of its location in the display.

Preferably, the measuring matrix is made up of two groups of four radiation sensors placed symmetrically with respect to the geometric middle of the side of the housing, the sensors in each group being located at the vertices of the square formed by line segments connecting each of them to two adjacent sensors, and the software "Visualization" is made with the possibility of determining the distances and azimuthal angles between the radiation source and the plane of the sensor matrix.

As a rule, the radio device is equipped with a removable flash memory and an input device in the form of a touch screen, as well as a navigation device for determining the location in space using GPS and / or GLONASS systems, and the measuring matrix is placed on the outside of the case, or in its silicone case.

The technical task of the utility model is to create an effective mobile radio device that provides the visualization function of the radiation source, and expand the arsenal of mobile radio devices.

The technical result that provides the solution of the problem lies in expanding the functionality to ensure the location (coordinates) of the detection radiation source, while measuring, storing and processing the parameters of the radiation source and visualizing the radiation source on the display of a mobile radio device, as well as generating relevant information in an accessible form Suitable for long-term storage, use and distribution.

The essence of the utility model consists in the fact that a mobile radio device comprises a housing in which a processor and a navigator connected to it, a data transmission module and sound alarm means, a program unit, a video matrix, a display, a power supply unit and sound alarm means are located, and it is provided with the processor with a measuring matrix of two groups of radiation sensors located on one side of the case, made identical in the number of sensors and their relative position in the group, while the program block is executed with software procedures "Radiometer" to determine the spectrum and intensity of the study, and "Visualization" to determine the location of the radiation source, followed by visualization of its location on the display.

Preferably, the measuring matrix is made up of two groups of four radiation sensors placed symmetrically with respect to the geometric middle of the side of the housing, the sensors in each group being located at the vertices of the square formed by line segments connecting each of them to two adjacent sensors, and the software "Visualization" is made with the possibility of determining the distances and azimuthal angles between the radiation source and the plane of the sensor matrix.

In special cases, the implementation of a mobile radio device with removable flash memory and an input device in the form of a touch screen, as well as a navigation device for determining the location in space using GPS and / or GLONASS systems. In this case, the measuring matrix is placed on the outside of the housing, or in its silicone case.

The drawing of figure 1 shows a schematic block diagram of a mobile radio device with a detector of the presence and location of the radiation source (device "DO-RA Vision"), figure 2 is a diagram of the construction of virtual pyramids according to the results of measurements by radiation sensors.

In the drawing of FIG. 1, processor 1, user flash memory 2, display (screen) 3, input device, preferably a touchscreen — touchscreen 4 (touchscreen) —touch screen), video (photo) matrix 5 (designated for photo and video camera), a detector of the presence and location of a radiation source in the form of a measuring matrix of eight radiation sensors 6 (with a narrow radiation pattern), Wi-Fi / GPRS data transmission module 7 (a radio communication module, where the GPRS protocol for wireless data transmission works via cellular communication), battery (power supply) 8, e.g. up battery, the navigator (transceiver) 9 GPS or GLONASS or GPS / GLONASS, block 10 programs (software), the routine 11 "radiometer", the routine 12 "Visualization". Block 10 programs with routines 11 "Radiometer" and 12 "Visualization" can be loaded into a user flash memory 2. In the drawing of figure 2, the source 14 of the radiation is conventionally indicated.

In this case, the navigator 9 of the GPS / GLONAS systems 9, the data transmission module 7 (the technology of packet data transmission over the radio channel) and the sound signaling devices (not shown) connected to the processor 1 equipped with the program (software) block 10 are connected to the processor 1, to which are connected video matrix 5, display 3, input device in the form of a touch screen (keyboard) - touchscreen 4, power supply unit 8 and sound alarms (not shown). The radio device is equipped with a measuring matrix connected to the processor 1 from two groups of radiation sensors 6 arranged on the same side of the housing 13 (symmetrically with respect to the imaginary geometric midpoint of the housing 13), made identical in the number of sensors 6 and their relative position in the group. Block 10 of the processor programs is made with a memory card index of the spectra of isotopes and with software 11 of the Radiometer procedure for determining the spectrum and intensity of the study from the readings of sensors 6, and with software 12 of the Visualization procedure for determining the location of the radiation source by measuring azimuth angles between the radiation source and the plane of the sensor array 6, with subsequent visualization of its location on the display 3.

The measuring matrix is made up of two groups of four radiation sensors 6 (with a solid-state working medium), the sensors 6 in each group being located at the vertices of the square formed by line segments connecting each of them with two adjacent sensors 6, i.e. groups of sensors 6 are located on one side of the smartphone case 13 directly on the case, or in its silicone case at the corners (vertices) of two equal squares. The measuring matrix looks, if you look at these sensors 6 from the back of the mobile display 3 of the smartphone, like a domino “double 4-4” with sensors 6 along the contour of the smartphone’s body 13.

The radio device is equipped with a connected removable flash memory 2, as well as a navigation device (navigator) 9 connected to the processor 1 for determining a location in space using GPS and / or GLONASS systems (two separate GPS and GLONASS navigators can be implemented equivalently). As a mobile radio device, a smartphone is preferably used.

Mobile radio operates as follows.

After detecting the presence of radiation in the surrounding space, the radio device, based on the readings of the radiation sensors 6, evaluates and identifies the radiation spectrum of the radiation source using the software built-in, for example, in the memory unit 10 of the card index of the radiation spectra of the main isotopes. For this, the claimed radio device - the device "DO-RA Vision" using all eight sensors 6 measures the energy of the radiation of a point source having a maximum amplitude. Having identified the isotope with the closest spectrum in the card index memory, processor 1 includes sensors 6 and block 10 for measuring the intensity of radioactive radiation using routine 11 of the Radiometer.

According to the results of measuring the radiation intensity of a radioactive source with a maximum amplitude of all eight sensors 6, the processor 1 recounts the intensity (value of the radiation energy E) received by each sensor 6 into the corresponding segment d - the distance to the point source of radioactive radiation.

All measured distance segments are arranged on an appropriate scale in the form of two pyramids, in the corners (vertices of the square) of the base of which there are radiation sensors 6, and the common vertex of these two virtual pyramids is the intersection of the ends of the distance segments d to a point source. As a result of this construction, the coordinates of the point of location of a point (concentrated) source of radioactive radiation are revealed, which is simultaneously, as it were, the common vertex of these two pyramids, built on the basis of the measured distance-segments d from the sensors 6 to the radiation source. This virtual picture from the measured distance segments d to the point source is superimposed using subroutine 12 Visualization on the video matrix 5 of the smartphone to visualize the point source of radioactive radiation through the sight of the camera or movie camera of the video matrix 5.

Thus, all visualization of a point source of radioactive radiation occurs on the screen (display) 3 of the smartphone. It is formed by the following chain: point source of radioactive radiation; determining the energy of a point source by each of the sensors 6, calculating the distances d from the radiation source to each sensor 6, by the processor 1; building pyramids based on calculated distance segments to the radiation source; identification of the point of intersection of the edges of the pyramids at an imaginary point corresponding to the location of the radiation source; plotting the edges of the pyramids on the screen (display) of the smartphone; visual localization of the radiation source on the screen (display) of 3 smartphones; determination of GPS or GLONASS source coordinates by the location of the smartphone itself. For this, the global positioning system receives a signal from satellites and superimposes it on the internal map of the navigator 9.

In the case of fixing several sources of radiation by sensors 6, on the screen (display) 3 of the smartphone, the image of these will appear sequentially from the source with maximum amplitude to the source with a smaller amplitude. The step between the amplitudes of measurements of the energy of radioactive radiation from several sources is set in hardware, and is constructed in a similar manner as described above. The frequency of occurrence of the image on the screen (display) 3 of the smartphone from several point sources of radiation will be determined by the speed of the processor 1 of a particular model of the smartphone having a matrix of sensors 6 of radiation.

As a result of this technical solution, the source (s) of radioactive radiation is visualized using hardware controls built on the basis of a modern smartphone, or another mobile radio device having its own operating system, visualization tools, and a positioning (navigation) system based on accurate measurements of the radioactive intensity radiation and indirect calculations of the distances from the sensors 6 to the radiation source using the 13 cm located on the outside of the housing the background of the sensitive matrix of the sensors 6 of radiation, and the final determination of the location of the radiation source in space based on the measurement of azimuthal angles between the directions from the sensors 6 to the radiation source and the plane of the matrix of sensors 6 of radioactive radiation located on the outside of the housing 13 of the radio device.

The spatial pyramid is built on the basis of the measured distance segments to the radiation source, with the addition of azimuthal angles determining the spatial position of the edges of the pyramid, with further visualization of the measurements, as well as the calculations of the distances to the radioactive source by the smartphone processor from each of the radiation sensors 6 separately. The software constructs two virtual tetrahedral pyramids on display 3, at the tops of which there is a source of radioactive radiation, and at the base of the pyramids are radiation sensors 6 in the form of an equilateral square, in the corners of which and at its center of symmetry there is one radioactive radiation sensor 6. By turning or tilting the housing 13 with a matrix of sensors 6, a visual approximate coincidence on the display of 3 vertices of virtual tetrahedral pyramids is achieved. Then, a visualized image is built by superimposing this virtual data on a real image of the area with the help of video matrix 5 in the camera or video camera mode. In this case, the coordinates of the source of radioactive radiation are determined based on the GPG / GLONASS system, and these coordinates of the source of radioactive radiation are fixed at the location of the device and these data are transmitted to the video matrix 5 of the camera to fix the source (sources) of radioactive radiation and its (their) coordinates on based on the GPG / GLONAS system in a photograph sent to flash memory 2 to record the fact of identifying the source of radioactive radiation and its spatial coordinates. For this, the GPS / GLONASS navigator 9 using global satellite navigation systems receives location data using either exclusively GLONASS signals, or exclusively GPS, as well as using the combined GPS / GLONASS constellation, which makes it possible to increase the reliability of determining coordinates in difficult conditions (for example, in dense urban development).

Based on measurements and calculations in GPS / GLONAS mode, a point of a radioactive radiation source is fixed in space and in time, and it can be photographed and recorded.

At the same time, the coordinates of the point of radioactive radiation, its radiation intensity at a given point in space, as well as the time of fixation and determination of the radioactive source of radiation are recorded. This event can be photographed in the form of: a point in space built on the basis of image formation, measured radiation energy, GPS / GLONASS calculation of the smartphone’s coordinates in space, and the time it took to record this event using the smartphone’s internal clock. All this information can be recorded in the smartphone’s own memory, or in the flash memory of 2 smartphones in the form of a digital code.

Thus, the device implements visualization of the source of radioactive radiation, determination of its coordinates with simultaneous visual and sound signaling about the maximum and unacceptable dose of radiation in the hourly, daily, weekly, monthly, annual interval, determination of the background radiation level, formation of graphs of the state of organs and systems person depending on the accumulated dose of radiation, the formation of recommendations for prevention, depending on the accumulated dose of radiation tions, and display the appropriate information 3 visual messages.

As a result, the mobile radio device is given new properties and functionality to ensure the location (coordinates) of the detection radiation source, while measuring, storing and processing the parameters of the radiation source and visualizing the radiation source on the display of the mobile radio device, as well as generating relevant information in an accessible form suitable for long-term storage, use and distribution.

Claims (5)

1. A mobile radio device comprising a housing in which a processor and a navigator connected to it, a data transmission module and sound alarms, a program block, a video matrix, a display, a power supply and sound alarms are located, and it is equipped with a measurement matrix of two groups of radiation sensors placed on one side of the case, made the same in the number of sensors and their relative position in the group, while the program block is made with software procedures "P adiometer "to determine the spectrum and intensity of the study and" Visualization "to determine the location of the radiation source and then visualize its location on the display. 2. The mobile radio device according to claim 1, characterized in that the measuring matrix is made of two groups of four radiation sensors placed symmetrically with respect to the geometric middle of the side of the housing, the sensors in each group being located at the vertices of the square formed by straight line segments connecting each of them with two adjacent sensors, and the Visualization software is made with the possibility of determining the distances and azimuth angles between the radiation source and the matrix plane sensors. 3. A mobile radio device according to any one of claims 1 and 2, characterized in that it is equipped with a removable flash memory and an input device in the form of a touch screen. 4. A mobile radio device according to any one of claims 1 and 2, characterized in that it is equipped with a navigation device for determining a location in space using GPS and / or GLONASS systems. 5. A mobile radio device according to any one of claims 1 and 2, characterized in that the measuring matrix is placed on the outside of the housing or in its silicone case.