KR20010068118A - Electromagnetic field exposure distribution measurement device using multi-electromagnetic sensors - Google Patents

Abstract

PURPOSE: A device for measuring an electronic wave exposure distribution using a plurality of electronic wave sensors is provided to measure the strengths of electronic waves among a plurality of spots by adjusting the distances among respective sensor spots. CONSTITUTION: In a device(20) for measuring an electronic wave exposure distribution, a key input part(22) receives a signal for controlling a sensor, a signal for starting a motor driving, a signal for controlling a display and a signal for setting a reference electronic wave, for an electronic wave detection. At least electronic wave sensors(24,26,28,30,32) detect a strength of an electronic wave from source for generating a particular electronic wave by a key control signal from the key input part. A signal processing part filters and A/D converts the detected signal. A motor driving part(38) drives a motor by the key control signal. A part for driving a display drives a display part(40) which outputs the information about the detected strength and distribution of the electronic wave and a distance measured from the source. A part for storing data calculates the distance about a reference electronic wave strength pre-determined by the key input part and the detected electronic wave strength, and stores an electronic wave operation algorithm for making a distribution map for the detected electronic wave using a plurality of electronic wave sensors. A control part(44) predicts an exposure distribution range and makes an exposure map based on the strength of the electronic wave detected from the electronic wave sensor with the part for storing data.

Description

Electromagnetic field exposure distribution measurement device using multi-electromagnetic sensors

The present invention relates to an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors, and more specifically, to estimate the size of an electromagnetic wave source and to measure a direction in which an antenna-type folder in which other sensors are built is located from a point where one sensor is located. The electromagnetic wave exposure distribution meter using the multiple electromagnetic sensor which measures the electromagnetic wave intensity at each point and measures the electromagnetic wave exposure distribution according to the distance from the source by using the multiple electromagnetic sensor which automatically stops when the international standard safety electromagnetic wave is reached. It is about.

As is well known, the electromagnetic wave exposure distribution is measured at a distance separated from the front because the intensity of electromagnetic waves is radiated very differently according to the slope of the system under measurement even with the same source of electromagnetic waves. Applying uniformly to is meaningless at all.

This is because it is closely related to the direction of electric current induced inside the electromagnetic wave source and also shows a considerable difference depending on the internal structure.

Hereinafter, a conventional electromagnetic wave exposure distribution meter will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram schematically showing a configuration of an electromagnetic wave exposure distribution measuring device according to a conventional embodiment.

Referring to this, the conventional electromagnetic wave exposure distribution measuring device 2 has been measured by using one measuring sensor in one measuring device to measure the intensity of electromagnetic waves, and has a function of displaying the value on the liquid crystal display.

More specifically, the conventional electromagnetic wave exposure distribution measuring device 2 is composed of a rectangular frame, and a key input unit 4 for generating a key signal for measuring the electromagnetic wave exposure distribution is formed at a predetermined lower surface of the frame.

In addition, an electromagnetic wave sensor 6 for detecting the intensity of electromagnetic waves from various electromagnetic wave generation sources is formed in a predetermined upper surface of the frame, and applied from the electromagnetic wave sensor 6 in a state in which an electromagnetic algorithm is stored. The control unit 8 is configured to control the display by signal processing the electromagnetic wave and measuring its intensity.

Therefore, the intensity of the electromagnetic wave measured from the electromagnetic wave sensor 6 is displayed on the display unit 10.

However, the above-described conventional electromagnetic wave exposure distribution measuring device 2 can accurately measure the electromagnetic wave intensity of the electromagnetic wave source from the point where the current sensor is located, but the electromagnetic wave exposure distribution from the electromagnetic wave source is not known, in particular to some extent from the source. It is not possible to predict the distance from the range of electromagnetic wave safety zone.

However, the above-mentioned conventional electromagnetic wave measuring method is not completely impossible to prepare an electromagnetic wave distribution map, but it is somewhat inconvenient in that each measurement should be measured at different distances in order to know the distribution. Therefore, repeated measurement at different points is difficult. Many measurement errors are likely to occur.

In practice, conventional measuring instruments are suitable for obtaining such information because, in the assessment of electromagnetic environment or mapping exposure distributions, information such as the distribution of electromagnetic waves and the safety distance from the source may be more important than the accuracy of the data at the measurement location. Not.

In addition, in the conventional technology, since there is only one electromagnetic wave measuring sensor, the distribution must be estimated through repeated measurement at a distance away from the source of the electromagnetic wave, and the position of the repeated measurement is also estimated by the user's guess. The electromagnetic wave strength is different and there is a problem in accuracy.

In addition, when the electromagnetic wave source is placed inside or behind an invisible wall, it is impossible to determine whether there is an electromagnetic wave source at a distance from the current measurement point. Conventional electromagnetic three-axis measurement sensor has a disadvantage in that it is not possible to predict the direction of the electromagnetic wave strength because the intensity measured from the axis is calculated by the square root to display only the numerical value through the display unit 10.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described state of the art. By applying a plurality of electromagnetic wave sensors to a predetermined side portion, a plurality of electromagnetic wave sensors can be used to measure the electromagnetic wave strength between multiple points by adjusting the distance between each sensor point. Its purpose is to provide an electromagnetic wave exposure distribution meter used.

In addition, the present invention can obtain the information on the distance between the electromagnetic wave source and the sensor and the intensity of the electromagnetic wave for each sensor by using a single measurement by using a plurality of electromagnetic sensors, through which a map of the electromagnetic wave exposure distribution can be prepared Another object of the present invention is to provide an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors capable of measuring the electromagnetic wave distribution at a point where measurement is impossible by analyzing the functional relationship.

1 is a schematic diagram schematically showing the configuration of an electromagnetic wave exposure distribution measuring instrument according to a conventional embodiment,

2 is a schematic diagram schematically showing a configuration of an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors according to an embodiment of the present invention;

3 is a schematic diagram schematically showing another configuration of an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors according to an embodiment of the present invention;

4 is a block diagram illustrating a circuit configuration of an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors according to an embodiment of the present invention;

5 is a diagram illustrating a measurement algorithm of an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors according to an exemplary embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

20: Electromagnetic exposure distribution meter, 21: Frame,

22: key input, 24, 26, 28, 30, 32: electromagnetic sensor,

25: antenna, 36: motor,

38: motor drive part, 40: display part,

42: interface unit, 44: control unit.

According to a preferred embodiment of the present invention, a key input unit for inputting various sensor operation signals, motor driving start signal, display operation signal, reference electromagnetic wave setting signal for electromagnetic wave detection; At least one electromagnetic sensor for measuring electromagnetic wave strength from a specific electromagnetic wave generation source by a key operation signal of the key input unit; A signal processor for filtering and A / D converting the signal detected from the electromagnetic sensor; A motor driving unit which drives the motor by the key operation signal of the key input unit; A display driver for driving a display unit for outputting electromagnetic wave intensity and distribution detected from the electromagnetic wave sensor and distance information from the electromagnetic wave source; Data storing therein an electromagnetic calculation algorithm that calculates a distance with respect to the reference electromagnetic intensity preset by the key input unit and the intensity of the electromagnetic wave, and creates a distribution map of the electromagnetic intensity detected through the plurality of electromagnetic wave sensors. A storage unit; Electromagnetic exposure using a plurality of electromagnetic sensors, characterized in that the control unit for predicting the exposure distribution range from the electromagnetic wave generation source and creating an exposure map based on the intensity of the electromagnetic wave detected from the electromagnetic sensor in the state of interworking with the data storage unit. Provide a distribution meter.

Preferably, the electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensor characterized in that it further comprises an interface unit for transmitting the intensity of the electromagnetic wave calculated by the control unit and the safety distance and the electromagnetic wave distribution information to the external terminal. do.

More preferably, the electromagnetic wave intensity calculated by the control unit and the safety distance from the source of the electromagnetic wave source, characterized in that it further comprises a voice output unit and a driving circuit for outputting the electromagnetic wave distribution information, the electromagnetic wave exposure distribution measuring device Provides an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensor, characterized in that the electromagnetic wave sensor has a structure capable of advancing / exiting an antenna formed at one end thereof by a motor formed therein.

On the other hand, there is provided an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensor, characterized in that the at least one electromagnetic wave sensor detachable structure on a predetermined side of the electromagnetic wave exposure distribution measuring instrument, any one electromagnetic wave sensor is formed at one end The antenna provides an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic sensor, characterized in that automatically advances until the intensity of the electromagnetic wave equal to or greater than the preset electromagnetic wave is detected.

In addition, the outer circumferential surface of the antenna is characterized in that the scale for measuring the distance is displayed, the electromagnetic calculation algorithm is characterized by calculating by applying different calculation equations according to the size and shape and type of the electromagnetic wave source. An electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors is provided.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail with reference to drawings.

2 is a schematic diagram schematically showing a configuration of an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic sensor according to an embodiment of the present invention.

Referring to this, the electromagnetic wave exposure distribution measuring device 20 using a plurality of electromagnetic wave sensors according to the present invention is first formed in a rectangular frame 21, the outer surface of the frame 21 is formed on the predetermined part of the measuring device Through a plurality of electromagnetic sensors, a key input unit 22 is formed for generating distance and intensity from an electromagnetic wave source, creating an electromagnetic wave distribution map, and displaying various types of information.

In addition, the first electromagnetic wave sensor 24 for measuring the intensity of the electromagnetic wave is formed in the front predetermined portion of the electromagnetic wave exposure distribution measuring instrument 20, the entrance / exit from the interior of the electromagnetic wave exposure distribution measuring instrument 20 An antenna 25 configured to be capable of attachment is attached, and a second electromagnetic wave sensor 26 is configured at the end of the antenna 25. At this time, the antenna 25 is a graduation mark that can measure the length on the outer peripheral surface.

Meanwhile, the third electromagnetic wave sensor 28 and the fourth and fifth electromagnetic wave sensors 30 and 32 are respectively installed at predetermined side surfaces of the electromagnetic wave exposure distribution measuring instrument 20. It is formed at the end of the first support (36) detachably attached to the side of the electromagnetic wave exposure distribution measuring instrument 20, the fourth and fifth electromagnetic wave sensors 30, 32 are also similar to the side of the electromagnetic wave exposure distribution measuring instrument 20 It is formed at the upper and lower ends of the second support (34) configured to be detachable with respect to.

In addition, the electromagnetic exposure distribution measuring device 20 is provided with a step motor 36 for advancing / injecting the antenna 25 according to an applied pulse, and a motor driver 38 for driving the step motor 36. ) Is configured.

In addition, a display unit 40 for displaying the intensity of the electromagnetic wave and its distribution information is formed on a predetermined front surface of the electromagnetic wave exposure distribution measuring instrument 20, and below the electromagnetic wave intensity and its distribution data detected from the sensor. Interface unit 42 such as a communication port for transmitting the data to a terminal such as a PC is formed.

On the other hand, inside the electromagnetic wave exposure distribution measuring unit 20 by calculating and processing the safety distance and the electromagnetic wave distribution through the intensity of the electromagnetic wave detected through the sensor (24, 26, 28, 30, 32) the display unit ( The controller 44 is configured to generate a control signal for outputting through the bar 40. The controller 44 receives various key signals from the key input unit 22 to drive and set the electromagnetic wave strength of the antenna 25. Comparison with (international reference value), control of the display unit 40, and data input / output control through the interface unit 42 are performed.

Therefore, since the electromagnetic wave exposure distribution measuring device 20 can obtain the information on the distance and intensity with respect to the electromagnetic wave source by measuring a single number of times, the electromagnetic wave exposure distribution measuring instrument can create an electromagnetic wave exposure distribution map as a function of the measured distance and intensity. .

More specifically, in the electromagnetic wave sensors 24, 26, 28, 30, and 32 formed in the electromagnetic wave exposure distribution measuring instrument 20, the first electromagnetic wave sensor 24 is embedded in the electromagnetic wave exposure distribution measuring instrument 20. And the second electromagnetic sensor 26 is embedded in the antenna 25 folder, and the third, fourth and fifth electromagnetic wave sensors 28, 30, and 32 are side surfaces of the electromagnetic wave exposure distribution measuring instrument 20. The user's convenience is increased by attaching / detaching to the sensor. When attaching, the distance between the two sensors (24, 26) can be pulled out like an antenna with a certain distance in the longitudinal direction from the first electromagnetic sensor (24). To adjust.

Therefore, the electromagnetic wave intensity at at least one or more points can be measured simultaneously, and the size of the electromagnetic wave source and the electromagnetic distribution from the source are automatically displayed through the display unit 40 using the distance information between the measurement points.

The second electromagnetic sensor 26 attached to the tip of the antenna 25 may drive the motor by the key operation of the key input unit 22 to control the entry / exit of the antenna 25 in a direction desired by the user.

Preferably, the electromagnetic wave exposure distribution measuring device 20 according to the present invention can map the electromagnetic wave exposure distribution from the electromagnetic wave source, and the antenna 25 of the second electromagnetic wave sensor 26 starts to operate in a linear direction. When the reference value (international electromagnetic wave reference value) set by the user is reached, the automatic stop is displayed as a function of electromagnetic wave intensity according to the progressed distance, and the function relationship is analyzed to predict the electromagnetic wave intensity at a long distance which cannot be measured. Wherever the antenna 25 can enter, it is possible to predict the intensity and distribution of electromagnetic waves even in a closed narrow space, and the distance between each of the plurality of electromagnetic sensors 24, 26, 28, 30, 32 and each sensor. Enable simultaneous measurements at.

3 is a schematic diagram schematically showing another configuration of the electromagnetic wave exposure distribution measuring device using the multiple electromagnetic sensor according to an embodiment of the present invention.

Referring to this, first, a description of components overlapping with the electromagnetic wave exposure distribution measuring instrument 20 will be omitted. The electromagnetic wave exposure distribution measuring instrument 20 'according to the present example has a plurality of electromagnetic wave sensors formed therein, and the sixth, seventh and eighth elements are detachably attached to the side surface of the electromagnetic wave exposure distribution measuring instrument 20'. Electromagnetic sensors 46, 48, and 50 are formed.

The sixth electromagnetic wave sensor 46 is formed at the end of the support 54 which is detachable to the side of the electromagnetic wave exposure distribution measuring instrument 20 ', and the seventh and eighth electromagnetic wave sensors 48 and 50 are also similar to the electromagnetic wave. It is formed on the upper and lower ends of the support 52 that can be attached to and detached from the side of the exposure distribution measuring instrument 20 '.

Therefore, the electromagnetic wave exposure distribution measuring device 20 'according to the present invention can more smoothly map the exposure distribution of the electromagnetic wave with respect to the same electromagnetic wave generating source.

4 is a block diagram illustrating a circuit configuration of an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic sensor according to an embodiment of the present invention.

Referring to this, reference numeral 22 denotes setting of the reference value of the electromagnetic wave intensity (international reference value), initiation of the detection operation of the plurality of sensors 24a to 24n, driving of the motor 36 and the display unit 40. A key input unit that performs key operations for operating screen output and the like is shown.

Incidentally, reference numerals 24a to 24n denote first to N sensors for measuring the electromagnetic wave intensities, their distances, and the like, which have already been described by other reference numerals in the above embodiments, respectively. 60 denotes a signal processor for filtering and A / D converting a signal applied from the first to Nth sensors 24a to 24n.

On the other hand, 64 calculates the distance to the electromagnetic wave source based on the electromagnetic wave data detected from the first to Nth sensors 24a to 24n, and makes it possible to prepare an electromagnetic wave exposure distribution map based on the functional relationship between the respective sensors. Represents a data storage unit for storing the electromagnetic calculation algorithm and the international electromagnetic wave intensity reference value.

38 represents a motor driving unit for driving the motor 36 generating the outgoing / incoming power of the antenna 25, wherein the motor 36 has a rotation speed determined according to an applied pulse, and the forward / reverse rotation is performed. Possible step motors.

In addition, 62 denotes a display driving unit for driving the display unit 40, and the configuration of the character memory, which is a character display memory in pixel units, in the display unit 40 is well known technique and thus will be omitted.

In addition, 42 denotes an interface unit for transmitting the electromagnetic wave intensity and distance measured from the electromagnetic wave exposure distribution measuring instruments 20 and 20 ', and data on the distribution to an external terminal (for example, a PC).

On the other hand, 44 represents a control unit for controlling the signal flow of the electromagnetic wave exposure distribution measuring instruments 20, 20 'bar, the control unit 44 is based on the key input signal applied from the key input unit 22 to the first to The electromagnetic wave intensity signals detected from the N-th sensors 24a to 24n are respectively applied, and an electromagnetic wave calculation algorithm for the intensity is read from the data storage unit 64 to calculate the distance from the electromagnetic wave source and its distribution. The screen is output by controlling the driver 62.

In addition, the control unit 44 receives a key signal for driving the motor from the key input unit 22 to drive the motor by controlling the motor driving unit 38 to enter / in / out the antenna 25 and store the data. If the electromagnetic wave intensity reference value (international reference value) read out from the unit 64 is the same as the intensity of the detected electromagnetic wave, a control signal is generated to the motor driver 38 to stop the entry / exit of the antenna 25. At the same time, the controller 44 automatically outputs a distribution map of electromagnetic waves generated from a specific electromagnetic wave generation source through the display unit 40 through an electromagnetic calculation algorithm previously stored in the data storage unit 64.

5 is a diagram illustrating a measurement algorithm of an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors according to an exemplary embodiment of the present invention.

The present invention is not possible to estimate the size of the conventional electromagnetic wave source and to make a distribution map by measuring the distribution of the electromagnetic wave source more accurately and conveniently using a plurality of sensors, in particular the distance from the electromagnetic wave source to the safety reference value The actual antenna 25 tracks to a reference value and automatically extends when the reference value is reached and stops automatically.

In addition, while the motor 36 rotates, the distance between the measuring points and the electromagnetic wave intensity are measured to provide information on the distance and the electromagnetic wave intensity simultaneously, and by analyzing the size and shape of the electromagnetic wave source, It is to estimate whether it originates from an electromagnetic wave generating source, and to provide measurement data which can prepare an electromagnetic wave exposure distribution map from an electromagnetic wave generating source.

That is, the control unit 44 has a 32-bit digital signal processor (DSP) that allows the sub-precision operation to increase the measurement accuracy. Performs the function of calculating an expression.

Hereinafter, an electromagnetic wave calculation algorithm for calculating electromagnetic wave information based on the intensity of electromagnetic waves stored in the data storage unit 64 and applied from a plurality of sensors will be described.

The electromagnetic wave sources may be distributed differently according to the slope, which is due to the different size and shape of the source. The magnitude prediction of electromagnetic wave source is divided into electric field and magnetic field. In the case of electric field, it is related to the charge distribution in the source. In the case of magnetic field, it can be correlated with the radius of the circular coil. Predict the size and distribution of sources as a function of electromagnetic wave strength.

More specifically, the magnitude of the source in the magnetic field is assumed to be a circular coil having a radius a in FIG. 5 in the Z direction from the center of the coil. For example, the magnitude of the source may be estimated by applying the currently measured electromagnetic wave intensity and Equation 1. Compare the electromagnetic wave strengths present. Equation 2 is measured at the point closest to the electromagnetic wave source (z = 0) and compared with the currently measured electromagnetic wave strength.

[Equation 1]

[Equation 2]

If the current measured electromagnetic wave intensity Bz and the distance z between the electromagnetic wave source and the measurement point are defined and the current I flowing through the coil is defined as R, the radius a of the electromagnetic wave source can be obtained from Equations 1 and 2. If we draw a curve similar to the actual calculated value and measured data from Equations 1 and 2, it is assumed that the electromagnetic wave source is a circular coil, and when this assumption is made, the prediction of the electromagnetic wave strength at a distance away from z is impossible. The radius a of the circular coil may be calculated by substituting the equations (1) and (2).

In addition, information on the shape and size of the electromagnetic wave generation source is also possible by the calculated coil radius a. If the intensity of the electromagnetic wave at the center of the electromagnetic wave source (z = 0) cannot be estimated from Equation 2, the electromagnetic wave source can be regarded as the magnetic field dipole moment, and the magnetic field dipole moment is derived as shown in Equation 3 below.

[Equation 3]

Since the magnetic field dipole moment increases exponentially with the size of the electromagnetic wave source, the radius of the circular coil becomes much larger. Whether to assume magnetic field dipole moment or circular coil can be easily understood by analyzing the function relationship of measured electromagnetic wave strength and distance. If Equations 1 and 2 are satisfied, it can be regarded as an electromagnetic wave generating source close to a circular coil and an electromagnetic wave generating source having a magnetic field dipole. When the electromagnetic wave generating source is the magnetic field dipole moment, Equation 4 below is expressed as the distance and the intensity of the electromagnetic wave.

[Equation 4]

It is possible to measure the electromagnetic wave intensity in the directions of x, y and z axes according to the size of the electromagnetic wave source from the above equation, and to predict the distance of x, y, z and display the size of the electromagnetic wave source with the measured electromagnetic wave intensity. do. In general, the magnetic field dipole moment decreases inversely proportional to the cube of distance by the equation (4) from the electromagnetic wave source.

The electric field is similar to the method of the magnetic field, and compares the value calculated by the equations (6) and (7) with the trend line in the distance relationship between the current intensity of the electromagnetic wave and the plurality of sensors. In particular, in the electric field, the size of the source can be predicted if the equipotential line is known from the electromagnetic wave source. The potential difference and the electric field strength are obtained from Equation 5 below.

[Equation 5]

In Equation 6, when the source of the electric field is a volume charge, a line charge, or a surface charge, the potential difference is inversely proportional to the distance as in Equation 6, and the electric field is inversely proportional to the square root of the distance. However, in the case of an electric field dipole, it can be regarded as a spherical electromagnetic wave source, which can be calculated by Equation 7, wherein the potential difference is inversely proportional to the square root of the distance and the electric field is inversely proportional to the cube root of the distance.

[Equation 6]

[Equation 7]

Therefore, when the electric field is measured as a function of distance and intensity from the source, it can be assumed that the equation (6) is satisfied, the line, plane, and volume charge distribution. The size and shape of the source can be predicted accordingly.

Distance information is important in order to obtain a function curve of electromagnetic wave intensity and distance, and the distance information acquisition method includes an antenna 25 having a second electromagnetic wave sensor 26 embedded therein according to a pulse signal applied through the controller 44. The advancing distance is calculated by the number of revolutions of the motor 36 when entering / exiting.

In order for the antenna 25 to extend in a linear direction, a motor driving circuit is required, and the distance currently extended by the rotation speed of the motor 36 can be accurately estimated. The second electromagnetic wave sensor 26 placed at the top of the antenna 25 proceeds in a linear direction with the antenna axis to automatically calculate the distance on the z axis and measure the electromagnetic wave strength at each distance. The relationship between the distance and the electromagnetic wave intensity is output through the display unit 40, and the distance information between the two measurement points is based on the first electromagnetic wave sensor 24 embedded therein. It can be predicted by converting the rotational speed of the motor moving by the motor in the direction.

The predetermined intensity of the electromagnetic wave is compared with the present measured value detected through the electromagnetic sensors 24a to 24n, and the motor 36 is stopped when the measured value is greater than or equal to the preset value.

While the motor 36 is operating, the controller 44 reads and computes an electromagnetic calculation algorithm (for example, Equations 1 to 7) stored in the data storage unit 64 in real time, and through this, Analyze the function of distance, size of source, and exposure distribution of electromagnetic wave sources.

In this case, the size of the electromagnetic wave source is very large and the radius of the electromagnetic wave source is very large when the inclination of the source is very large. This is not an effect, but an effect generated by external power lines or wiring inside a house.

Hereinafter, an electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic sensor according to another embodiment of the present invention will be described in detail with reference to the accompanying drawings.

6 is a schematic diagram showing a schematic configuration of an electromagnetic wave exposure distribution measuring apparatus using a plurality of electromagnetic wave sensors according to another embodiment of the present invention, Figure 7 is an electromagnetic wave exposure distribution measuring apparatus using a plurality of electromagnetic wave sensors in accordance with another embodiment of the present invention Fig. 1 is a block diagram showing the circuit configuration of the circuit.

Referring to this, the electromagnetic wave exposure distribution measuring instrument according to the present invention is provided with a voice output means which can secure the electromagnetic wave information by the voice when it is difficult to visually check the electromagnetic wave information through the visually impaired people or the display unit 40. to provide.

In more detail, the electromagnetic wave exposure distribution measuring device 20 ″ includes a voice output unit 70 for outputting voice data at a predetermined lower end thereof, and the existing headphone or earphone jack ( 72) so that the electromagnetic wave information can be output as voice.

At the same time, a voice output driver 72 for driving the voice output unit 70 is configured inside the electromagnetic wave exposure distribution measuring instrument 20 ″, and the electromagnetic wave information is displayed according to the mode selection of the key input unit 22. FIG. It may be output through the unit 40 or the voice output unit 70.

On the other hand, the electromagnetic wave exposure distribution measuring device using a plurality of electromagnetic wave sensors according to an embodiment of the present invention is not limited to the above-described embodiment, various modifications can be made within the scope not departing from the technical gist.

As described above, the electromagnetic wave exposure distribution measuring device using the multiple electromagnetic wave sensors according to the present invention can predict at what distance the various electromagnetic wave sources are exposed, and the intensity of the electromagnetic wave measured at the current position is applied to the surrounding electronic products. Is it a problem or whether it is a problem with the distribution line in the outdoor or residential. In addition, when the transmission line is viewed as a source of electromagnetic waves, by measuring the electromagnetic wave at the current measuring position, it is possible to predict how much the electromagnetic waves are distributed in the transmission line.

In addition, the measuring device according to the present invention can be applied to any electronic product or any product that causes electromagnetic wave generation, and in particular, by predicting the electromagnetic wave exposure range for each product and displaying the predicted value on the corresponding product, the user can minimize the electromagnetic environment. It is expected to contribute to the reduction of power consumption and harmful electromagnetic wave exposure by shortening the time of unnecessarily connecting the plug by making the exposure distribution map for each electronic product and publishing it to the public. In addition, electromagnetic waves can be provided as educational measuring equipment that can help students understand the physical physics of electromagnetic waves by directly inducing complex mathematical formulas and reducing them as a function of distance from electromagnetic wave sources.

In addition, the measuring device according to the present invention is capable of measuring the distribution of electromagnetic waves in an enclosed space, and can measure the electromagnetic wave intensity distribution in an incubator and other narrow spaces in an electromagnetic exposure device for cellular experiments. There is an advantage.

Claims (8)

A key input unit for inputting various sensor operation signals, motor drive start signals, display operation signals, and reference electromagnetic wave setting signals for electromagnetic wave detection; At least one electromagnetic sensor for measuring electromagnetic wave strength from a specific electromagnetic wave generation source by a key operation signal of the key input unit; A signal processor for filtering and A / D converting the signal detected from the electromagnetic sensor; A motor driving unit which drives the motor by the key operation signal of the key input unit; A display driver for driving a display unit for outputting electromagnetic wave intensity and distribution detected from the electromagnetic wave sensor and distance information from the electromagnetic wave source; Data storing therein an electromagnetic calculation algorithm that calculates a distance with respect to the reference electromagnetic intensity preset by the key input unit and the intensity of the electromagnetic wave, and creates a distribution map of the electromagnetic intensity detected through the plurality of electromagnetic wave sensors. A storage unit; Electromagnetic exposure using a plurality of electromagnetic sensors, characterized in that the control unit for predicting the exposure distribution range from the electromagnetic wave generation source and creating an exposure map based on the intensity of the electromagnetic wave detected from the electromagnetic sensor in the state of interworking with the data storage unit. Distribution meter. The electromagnetic wave exposure distribution using a plurality of electromagnetic wave sensors according to claim 1, further comprising an interface unit for transmitting the electromagnetic wave intensity calculated by the controller, the safety distance from the electromagnetic wave source, and the electromagnetic wave distribution information to an external terminal. Measuring instrument. [Claim 2] The plurality of electromagnetic wave sensors of claim 1, further comprising a voice output unit and a driving circuit for outputting the electromagnetic wave intensity calculated by the controller, the safety distance from the electromagnetic wave source, and the electromagnetic wave distribution information. Electromagnetic exposure distribution measuring instrument. The electromagnetic wave exposure distribution measuring apparatus of claim 1, wherein the electromagnetic wave exposure distribution measuring device has a structure in which any one electromagnetic wave sensor can enter / exit an antenna formed at one end thereof by a motor formed therein. Exposure distribution meter. The electromagnetic wave exposure distribution measuring device of claim 1, wherein at least one electromagnetic wave sensor is detachably attached to a predetermined side surface of the electromagnetic wave exposure distribution measuring instrument. The multiple electromagnetic wave sensor according to claim 1 or 4, wherein an antenna formed at one end of the electromagnetic wave sensor automatically advances until an intensity of an electromagnetic wave equal to or greater than a predetermined electromagnetic wave is detected. Electromagnetic exposure distribution measuring instrument. The electromagnetic wave exposure distribution measuring device according to claim 1 or 4, wherein a scale for measuring a distance is displayed on an outer circumferential surface of the antenna. The electromagnetic wave exposure distribution measuring device according to claim 1, wherein the electromagnetic arithmetic algorithm operates by applying different arithmetic expressions according to the size, shape, and type of the electromagnetic wave generating source.