RU2796396C1 - Device for long-term continuous measurement of power density of non-ionizing electromagnetic radiation and total energy density - Google Patents

Abstract

FIELD: measurement devices.

SUBSTANCE: used to measure power density of non-ionizing electromagnetic radiation and the total energy density. The essence of the invention lies in the fact that a device for long-term continuous measurement of the power density of non-ionizing electromagnetic radiation and the total energy density in a predetermined frequency band contains a planar antenna and a detection unit, while the detection unit is built into the receiving surface of the planar antenna, and its interaction with the antenna is carried out through high-frequency fields and currents, while the detection unit together with the antenna form a single electrodynamic receiving structure.

EFFECT: ensuring the possibility of a minimum mismatch between the antenna and the detector in the upper frequency range while maintaining the possibility of measuring the power density of non-ionizing electromagnetic radiation and the total energy density in the hyper-broadband range.

13 cl, 1 dwg

Description

SUBSTANCE: invention relates to measuring technique, in particular, to measurements of power density of non-ionizing electromagnetic radiation and total energy density.

In the prior art, an electromagnetic radiation dosimeter is disclosed in US 3,783,448 A (publ. 01/01/1974). A device for measuring total electromagnetic radiation and exposure to non-ionizing electromagnetic radiation includes: a polarization-insensitive antenna; crystal diode; and an integrator having an anode, a cathode, and an electrolytic gap between the anode and the cathode. The output of a crystal diode applied to the anode and cathode causes electrolyte ions to migrate through the electrolytic gap to the anode, proportional to the charge passing from the diode, to sum up the amount of radiation to which the antenna is exposed at all times. In this case, the antenna is directly connected to the crystal diode detector, and the crystal diode detector is directly connected to the integrator.

The disadvantages of this dosimeter are the inability to accumulate data for a long measurement period, a small measurement range, and the lack of an autonomous power supply.

A system for measuring electromagnetic pollution is known from the prior art, as disclosed in DE 29810794 U1 (published on 11/26/1998). The dosimeter consists of a small, pocket-sized plastic case containing a printed circuit board, antenna, precision voltage divider, instrumentation amplifier, rectifier bridge, and filter. The electromagnetic field induces an alternating voltage in the antenna, which is fed directly to the rectifier bridge. The symmetrically rectified voltage passes through a filter that eliminates residual AC voltage and to an instrumentation amplifier, where the voltage is amplified.

The disadvantages of this dosimeter is also the inability to accumulate data for a long measurement period and a small measurement range.

From the prior art, a device for environmental monitoring of the harmful effects of microwave radiation from a cell phone on the human body, disclosed in document RU 65241 U1 (publ. 27.07.2007) is known. The device contains a receiving antenna connected in series, a microwave radiation detector, a unit for measuring the level of microwave radiation, a controller made in the form of a microprocessor with the ability to set a sanitary standard, and a unit for indicating the excess of the sanitary standard. In addition, the device contains a unit for measuring the duration of microwave radiation, connected between the output of the detector of microwave radiation and the corresponding input of the controller, while the latter is configured to determine the accumulated dose of harmful effects of microwave radiation on the human body from the output signals of the units for measuring the level and duration of microwave radiation. and comparing it with the sanitary standard.

The disadvantages of this dosimeter is also the inability to accumulate data for a long measurement period and a small measurement range.

The closest in technical essence to the claimed dosimeter is the device disclosed in the article "MICROWAVE ELECTROMAGNETIC DOSIMETRY OF PERSONAL ECOLOGICAL SPACE", authors Dmitriev A. S., Itskov V. V., Ryzhov A. I. and Uvarov A. V., published in the journal "PHYSICAL FOUNDATIONS OF INSTRUMENT MAKING" 2020. V. 9. No. 1 (35). This device was chosen as a prototype of the claimed solution.

The specified device contains an antenna, a detector, a microcontroller, an ADC, built-in memory, a real-time clock, a USB interface, FLASH memory, a USB connector, a controlled voltage regulator, a power supply driver, and a battery. At the same time, the antenna is made of a printed monopole in an integral layout with a radio emission detector.

However, the antenna in the specified dosimeter has a weak agreement with the radiation detector in the upper frequency range of measurements.

The objective of the present device for long-term continuous measurement of the power density of non-ionizing electromagnetic radiation and the total energy density is to eliminate the shortcomings of the prototype.

The technical result consists in ensuring a minimum mismatch between the antenna and the detector in the upper frequency range, while maintaining the possibility of measuring the power density of non-ionizing electromagnetic radiation and the total energy density in the hyper-broadband range.

A device for long-term continuous measurement of the power density of non-ionizing electromagnetic radiation and the total energy density in a predetermined frequency band, containing a planar antenna and a detection unit, characterized in that the detection unit is built into the receiving surface of the planar antenna, its interaction with the antenna is carried out through high-frequency fields and currents , while the detection unit together with the antenna form a single electrodynamic receiving structure.

Combining a planar antenna and a detection unit into a single electrodynamic receiving structure by embedding the detection unit into the receiving surface of the antenna makes it possible to minimize the mismatch between the antenna and the detection unit in the upper frequency measurement range.

Figure 1 shows a block diagram of the dosimeter.

Figure 1 indicates: 1 - dosimeter, 2 - antenna, 3 - detection unit, 4 - data processing and display unit, 5 - ADC, 6 - built-in memory, 7 - real time clock, 8 - USB interface, 9 - FLASH memory, 10 - USB connector, 11 - controlled voltage regulator, 12 - power driver, 13 - autonomous power supply, 14 - reader.

The personal dosimeter 1 comprises a body, an omnidirectional antenna 2 capable of operating in hyper-broadband mode, a detection unit 3, a data processing and display unit 4, an autonomous power source 13, and a power driver 12. The data processing and display unit can be made on the basis of microcontroller, to which a data storage device in the form of additional FLASH memory 9 and a micro-USB connector 10 for interfacing with a reader 14 are connected to store the processed data.

The microcontroller contains an analog-to-digital converter (ADC) 5, built-in memory 6, real time clock 7 and USB interface 8 with connector 10, which acts as a communication unit with external current sources, computing and communication devices. The case is additionally equipped with an LED indicator of the charge level of the autonomous power supply 13.

In one embodiment, the antenna is in the form of a UWB dipole printed antenna. In another embodiment, the antenna may be in the form of an ultra-wideband monopole printed antenna.

Also, the antenna can be made in the form of an ultra-wideband F-shaped printed antenna.

The detection unit is configured to amplify, detect and filter the said high-frequency current into an output unipolar signal, which is a monotonic function of the power of the received electromagnetic radiation.

In one embodiment, the detection unit is made in the form of a logarithmic amplifier and a low-pass filter connected in series.

In another embodiment, the detection unit is made in the form of a quadratic detector, an amplifier and a low-pass filter connected in series.

The data processing and display unit is configured to issue, upon request, the accumulated data for any time interval, both in the form of the current received power and in the form of the total energy accumulated in the mentioned range, as well as performing program settings of the device in accordance with the selected application conditions.

A light or sound indicator can also be placed in the housing to instantly inform the user about the level of radiation.

Device implementation example.

The basis of the dosimeter is a hyper-wideband receiver with an operating frequency band from 800 to 8000 MHz (the ratio of the upper to the lower operating frequency is 10:1), a dynamic range of 55 dB, and a sensitivity of about 3 nW. The frequency range of the receiver covers almost the entire used and promising (related to 5G up to 6 GHz) frequency range of modern mobile communication systems, except for the currently little-used frequency range below 800 MHz.

The receiver consists of a printed antenna, the receiving surface of which has a built-in detection unit. The resulting electrodynamic receiving structure makes it possible to measure the strength of the electromagnetic field in all directions and in the hyper-wideband mode and has a minimum mismatch between the antenna and the detector in the upper frequency range.

The hyper-wideband receiver measures the power of the electromagnetic microwave signal arriving at the antenna at a frequency of 1 time per second and stores it in memory. These data can be directly displayed on the screen of a computer connected to the dosimeter (laptop, tablet, smartphone), and then it is possible to observe the dynamics of changes in the received signal power in real time. After 1 min of readings are accumulated, the total energy is recorded in a permanent non-volatile memory, and such data can be recorded for a long time. The maximum recording time is over 6 months. These data or any of their fragments can also be displayed as graphs on the monitor.

The connection of the personal dosimeter with a computer, tablet or smartphone is carried out via a USB interface. Through it, the battery is charged from an external computing device or from a 220 V network.

Each copy of the personal dosimeter has a unique number. The ability to set and read the individual number of each personal dosimeter has been implemented, which allows processing data from several dosimeters on one reader device (PC, tablet, phone), as well as remotely storing personal statistics for many devices, for example, in the cloud. The device provides synchronization of the calendar and the current time with the reader when connected via the USB interface to bind the received radiation dose to the absolute time.

The device works as follows.

The first time power is applied or the next wake-up, the settings controller is launched, where the I / O ports are configured. After that, a check is made for the presence of external power, if positive, a high-speed internal clock source is started to initialize the USB. In the absence of external power, a slower, but at the same time more economical internal multi-speed generator starts up and the device switches to an autonomous mode of operation. If this is the first power-up, the device starts the external clock quartz and the real time clock. During autonomous operation, the ADC is started at this point in time, which is indicated by the green LED on the side panel of the device. Then the device is in standby mode.

If an interrupt is triggered to indicate the end of receiving data on the ADC, which is indicated by turning off the green LED on the side panel of the device, this data is processed and summed with the previous values. Next, the internal counter is checked. New information about the pointer to the address of the latest data in the FLASH memory is written to the registers of the microcontroller, where this data is stored safely while the device is in sleep mode.

If the timer interrupt is triggered, the ADC is started, which is indicated by the green LED on the side panel of the device, and a check for the presence of external power. If there is no external power supply, the device goes into standalone mode and goes into standby mode. When external power is available, the device immediately enters the standby state.

In the event that data is received via the USB interface from the reader, the personal dosimeter processes them and, depending on the request, generates a response data message. During a communication session, through special software on the reader, it is possible to set an individual number of a personal dosimeter, synchronize absolute time, read an arbitrary fragment of the device’s memory, read and write an index, delete pages in FLASH memory. After the session, the personal dosimeter goes into standby mode.

Claims (13)

1. A device for long-term continuous measurement of the power density of non-ionizing electromagnetic radiation and the total energy density in a predetermined frequency band, containing a planar antenna and a detection unit, characterized in that the detection unit is built into the receiving surface of the planar antenna, and its interaction with the antenna is carried out through high-frequency fields and currents, while the detection unit together with the antenna form a single electrodynamic receiving structure. 2. The device according to claim 1, characterized in that the antenna is made in the form of an ultra-wideband dipole printed antenna. 3. The device according to claim 1, characterized in that the antenna is made in the form of an ultra-wideband monopole printed antenna. 4. The device according to claim 1, characterized in that the antenna is made in the form of an ultra-wideband F-shaped printed antenna. 5. The device according to claim 1, characterized in that the detection unit is configured to amplify, detect and filter the said high-frequency current into an output unipolar signal, which is a monotonic function of the power of the received electromagnetic radiation. 6. The device according to claim 1, characterized in that the detection unit is made in the form of a logarithmic amplifier and a low-pass filter connected in series. 7. The device according to claim 1, characterized in that the detection unit is made in the form of a series-connected quadratic detector, amplifier and low-pass filter. 8. The device according to claim 1, characterized in that it additionally contains a data processing and display unit. 9. The device according to claim 8, characterized in that the data processing and display unit is configured to issue, upon request, the accumulated data for any time interval both in the form of the current received power and in the form of the total energy accumulated in the mentioned range, and also performing software settings of the device in accordance with the selected application conditions. 10. The device according to claim 8, characterized in that it additionally contains a light or sound indicator for instantly informing the user about the level of radiation. 11. The device according to claim 1, characterized in that it further comprises a data storage device. 12. The device according to claim 1, characterized in that it additionally contains a communication unit with external current sources, computing and communication devices. 13. The device according to claim 1, characterized in that it additionally contains an autonomous power source.

Images