WO2013150144A1 - Device for evaluating exposure to electromagnetic radiation - Google Patents

Abstract

The invention relates to a device (1) for evaluating the exposure of a point of interest to electromagnetic radiation emitted by a source, including: a means (11) for targeting an object; a means (12) for measuring the distance between the device and the object, the object being the location of the point of interest or that of the source; means (13, 14) for measuring the relative positions of the device and of the object pointed at; a processing means (19) capable of communicating with the means for measuring the distance between the device and the object and with the means for measuring the relative positions of the device and of the object, wherein the processing means are suitable for calculating, from the measured distance and relative positions, and from at least one radiation-source model, the exposure of said point of interest to the electromagnetic radiation emitted by a source consistent with said model.

Description

 DEVICE FOR EVALUATING EXPOSURE TO RADIATION

 ELECTROMAGNETIC

FIELD OF THE INVENTION

 The field of the invention is that of evaluating the exposure of a site to electromagnetic radiation generated by a source, typically a relay antenna of a base station, or a relay antenna project. STATE OF THE ART

 The significant development of telecommunication networks leads to the installation of numerous antennas generating electromagnetic radiation. Issues relating to the consequences of public exposure to increasing amounts of electromagnetic radiation still exist in the population and various measures of information, consultation and attention have been adopted in different countries. Some of these measures seek to limit the exposure in certain places while maintaining the quality of the service provided.

 Other proposals were made to organize the geographical distribution of relay antennas taking into account the radiation emitted.

 Exposure limits are adopted by certain national legislations, including France, in accordance with the recommendations of the International Commission for the Protection against Non-Ionizing Radiation (ICNIRP).

 To ensure that these exposure limits are met, the rate of electromagnetic radiation in one location must be evaluated or measured directly.

 Already known in this regard are devices for evaluating the exposure of a place to electromagnetic radiation generated by an antenna. This is the case, for example, of document US 2007/093213, which describes a method of estimating an electromagnetic field received at a position of a territory covered by a telecommunication network.

However, this document does not allow to measure at a specific point of interest, for example a dwelling, exposure to radiation electromagnetic emissions from an existing antenna or that could come from a future antenna.

 Indeed, the electromagnetic field is measured globally, by simply taking into account the general topology of the territory and a propagation model of radiation emitted by a wave.

 It does not provide a sufficiently accurate radiation exposure rate for a given location to determine whether or not the rate is in compliance with the law.

 Document EP2098875 also discloses a device for evaluating an electric field generated by a transmitter in a reception zone, this device calculating the average of the gain of the transmitter at the reception zone over a given angular section.

 In a similar manner to the previous document, the solution provided by this document is not sufficiently precise to make it possible to know at a particular point of interest the value of the electric field generated by a neighboring transmitter.

 Similarly, the publication of T. Kurner et al. "Concepts and results for 3D digital terrain-based propagation wave model: an overview", and US 6,341,223 mathematical modeling of electromagnetic wave propagation in urban or rural environments.

 These documents are intended to determine if a receiver located at a significant distance from a transmitter can capture a sufficiently large power signal. The object of the modeling proposed is not to control in a specific place that a rate of exposure to electromagnetic waves is well respected, and therefore the degree of precision of the models proposed in these documents is not sufficient to allow this control.

Document US2005 / 02015268 proposes a direct measurement of the radiation received by a mobile phone from the transmitting stations located nearby.

 Unlike the previous documents, this one allows a measurement of the radiations actually received in a place.

However, the device described in this document does not easily measure the exposure of a place to the radiation generated by an antenna, since it requires that the mobile phone is in said place. In the In the case of an assessment at the home level of an individual, it is necessary to disturb the inhabitant of the home to be able to carry out the measurement.

 In addition, it also does not allow to predict in advance an exposure rate when the antenna is simply in the state of draft.

 It may also happen that users oppose the presence of an existing or planned antenna, near their home or a place they frequent, arguing too much exposure to the radiation generated by this antenna .

 In these cases, a means must be found to objectively measure the exposure of a point of interest to electromagnetic radiation from an antenna, including in cases where it is not possible to measure directly at the point of interest. This problem arises, for example, when the user objects to a third party accessing his home to carry out a measure of exposure to radiation.

PRESENTATION OF THE INVENTION

 The invention proposes to overcome at least one of the aforementioned shortcomings.

In particular, the invention aims to provide a device for evaluating the exposure of a particular point of interest to electromagnetic radiation emitted by an existing or potential source.

 In this respect, the invention proposes a device for evaluating the exposure of a point of interest to electromagnetic radiation emitted by a source, the device comprising:

 sighting means of a pointed object,

 means for measuring a distance between the device and the pointed object, the pointed object being the location of the point of interest or that of the source, means for measuring the relative positions of the device and the device; pointed object,

processing means capable of communicating with the means for measuring the distance between the device and the pointed object, and with the means for measuring the relative positions of the device and the pointed object, in which the processing means are adapted to calculate, from the measured distance and relative positions, and from at least one predetermined pattern radiation source, exposing said point of interest to electromagnetic radiation emitted by a source conforming to said model.

The invention is advantageously complemented by the following features, taken alone or in any of their technically possible combination: the sighting means are a sighting telescope or a camera,

 the means for measuring the relative positions of the device and the pointed object comprise means for measuring the attitude and the azimuth of the device,

 the means for measuring the attitude are chosen from the following group: inclinometer with accelerometer, inclinometer with balance, level, rangefinder, the means for measuring the azimuth are chosen from the following group: compass, magnetoresistance sensor, rangefinder,

 the device further comprises a rotating support and variable inclination, adapted to change its azimuth and its attitude,

 the device further comprises a satellite positioning system, the means for measuring the distance between the device and the pointed object are a range finder,

 the device is portable and weighs less than 40 kg, preferably less than 20 kg,

 the device further comprises data export means.

The invention further relates to a method for measuring the exposure of a point of interest to electromagnetic radiation generated by a source, the method comprising the steps of:

 positioning a device according to the invention at a location among the location of the source, the location of the point of interest, or a location for the source and the point of interest,

 point the device at an object positioned at the point of interest or source location,

 measure the distance and the relative positions between the device and the pointed object, and

From measurements and a predetermined electromagnetic radiation source model, calculate the point exposure rate of interest to electromagnetic radiation generated by a source that conforms to the source model.

Advantageously, but optionally, the method according to the invention may further comprise at least one of the following characteristics:

 the device is positioned at the location of the source or point of interest, and is pointed at an object positioned respectively at the location of the point of interest or the source,

 the device is positioned at a location for the location of the source and the point of interest, and during which the pointing steps of the device to an object are reiterated and the distance between the device and the device is measured. object, before the step of calculating the exposure ratio, the pointed object being successively one and the other of the location of the source and the point of interest,

 the measurement of the relative positions of the device and of the pointed object comprises:

 o the measurement of the attitude of the device when it is pointed towards the pointed object, and

 o the measurement of the azimuth of the device when it is pointed towards the pointed object.

 the step of calculating the exposure rate of the point of interest comprises:

 o calculating the gain of the source model in the direction of the point of interest, and

 o the calculation of the radiofrequency electric field generated by the source at the point of interest, as a function of the gain of the source model, the distance between the location of the source and the point of interest, and the frequency of the source,

 the source model includes the following parameters: an antenna model, an electromagnetic radiation emission frequency band, an antenna power as a function of frequency, an antenna azimuth, and an attitude of the antenna. antenna.

the step of calculating the exposure ratio further comprises a step of selecting a predetermined source model from among a plurality of models stored in a memory of the device processing means. PRESENTATION OF FIGURES

 Other features, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and nonlimiting, and which should be read with reference to the appended drawings in which:

 FIGS. 1a, 1b and 1c illustrate a device according to the invention placed in different contexts of use,

 Figure 2a shows schematically an example of a device according to the invention.

 FIG. 2b illustrates a schematic diagram of the device according to the invention; FIG. 3a schematically represents measurements made by the device,

 FIG. 3b illustrates constraints on the accuracy of the attitude measurements made by the device,

 FIG. 3c illustrates constraints on the accuracy of the azimuth measurements made by the device,

 FIG. 4 illustrates an exemplary implementation of the method for measuring the exposure of a point of interest to a radiation source according to the invention. DETAILED DESCRIPTION OF AT LEAST ONE EXAMPLE OF IMPLEMENTATION

FIGS. 1a 1b and 1c show diagrammatically an example of a device according to the invention in three different contexts of use.

 The device is used to estimate the exposure of a point of interest 3 to electromagnetic radiation emitted by a source 2, such as an antenna, existing or potential.

 The device 1 can be positioned at the location of the source 2, at the location of the point of interest 3, or at a separate location 4, but which is in view of the location of the source 2 and that of the point of interest 3.

The device 1 is pointed at an object O which is at the location of the point of interest 3 or the source of radiation 2, hence the need, when the device is positioned at the location 4, that it for Point 3 and Source 2. Referring to Figure 1a, there is shown without limitation a source 2 placed at the top of a building B, a device 1 placed at the location of this source, and points of interest 3 located in buildings B surrounding.

 In this example of implementation of the device 1, it directly targets one of the points of interest 3 and can by means defined below determine exactly the amount of electromagnetic radiation from the source 2 to which these points are submitted.

 This situation may arise when an operator plans to build a new antenna near homes, and must choose between several locations that will expose the least neighboring inhabitants to electromagnetic radiation.

 It can also occur in the event of conflict between an operator and a local resident living near an antenna, the resident arguing too much exposure to radiation emitted by the antenna. In this case, it is necessary to achieve an objective and precise measurement of the radiation that it receives without having access to its home.

With reference to FIG. 1b, the device 1 is positioned at a point of interest 3, and is pointed towards the location of a source 2, or a location chosen for the future installation of a source. 2.

 This arrangement is the opposite of that of Figure 1a. It can be considered when one seeks for example a reduced exposure at the level of a particular place. The device can measure different possible locations of sources near and in direct view of the point of interest to determine the location of the source that minimizes exposure at that point.

With reference to FIG. 1c, the device 1 is positioned at a location 4 situated in view of the point of interest 3 and the source 2 - or if the source does not exist, in the case of an installation project , its potential location.

This arrangement makes it possible to estimate the exposure of the point of interest 3 to the radiation emitted by the source 2, even when access to one and the other is impossible. It also makes it possible, in the case of an antenna installation project in which several sites are conceivable, to simulate the exposure resulting from the antenna on each of the two sites, and this on a plurality of points of interest. The components of the device are described with reference to Figure 2a.

 This device 1 comprises sighting means 11 of an object pointed at O by the device.

 The sighting means 11 may be of any known type, and preferably an optical sighting telescope or a camera.

 The optical sight can optionally be provided with a laser system to reveal a point of light on the object pointed O and confirm that the device is pointed to the right object.

 If necessary, a digital camera can also be used to acquire images of the pointed object O.

The device 1 is also provided with means 12, 13, 14 for measuring the distance and the relative positions between the device 1 and the pointed object O, the various measured parameters being identified in FIG. 3a. By relative positions is meant the angular difference in height ΔΗ between the device and the pointed object O, and the azimuth ΔΑ of the object O relative to the North. In Figure 3a, the Z axis represents the zenith, and the E and N axes respectively represent the East and North.

The means 12 for measuring the distance between the device and the pointed object O are also chosen from existing means, preferably a laser rangefinder rangefinder by flight time measurement, to allow use of the device outdoors, without addition of a reflective target on the pointed object, to which the operator does not necessarily have access when performing the measurements.

The means 13, 14 for measuring the relative positions between the device 1 and the pointed object O preferably comprise means 13 for measuring the attitude, and means 14 for measuring the azimuth of the device 1.

The means 13 for measuring the attitude are chosen from solutions such as accelerometer inclinometer, balance inclinometer or level, but this function can also be performed by the rangefinder 12 chosen to measure the distance between the device 1 and the pointed object O.

 The means 14 for measuring the azimuth are chosen from solutions such as compass or magnetoresistance sensor, but this function can also be performed by the rangefinder 12.

 In any case, the means 12, 13, 14 for measuring the distance and the relative positions between the device 1 and the pointed object O are preferably electronic devices able to be connected to a processing unit 19 represented in FIG. Figure 2b and described in more detail below.

With reference to FIGS. 3b and 3c, the choice of these means 12, 13, 14 is also constrained by their context of use.

 To obtain a reliable measurement of a pointed object, particularly when the pointed object is the point of interest 3, the aim of the device must be sufficiently accurate both in attitude and in azimuth.

 However, the distances D to be measured outdoors between the source and the point of interest can reach at least 1000m. At this distance, it must be necessary to distinguish two buildings to ensure that the measurement is indeed made at the point of interest.

 With reference to FIG. 3b, it is considered that the accuracy in azimuth is sufficient if the device 1 makes it possible at least to distinguish two buildings B spaced 20 meters apart, at a distance D of 1000 m. The precision necessary to be able to distinguish these two buildings is given by the angle formed by these buildings and

 20

the device, gives by the relation sin a = ^ jj- α is worth in this case about 1.15 °.

 An accurate azimuth measurement system is therefore considered sufficient.

 This accuracy can of course be adapted according to the constraints of use of each and will be determined by the skilled person.

With reference to FIG. 3c, it is considered that the accuracy in attitude (angular difference in height) is sufficient if the device makes it possible to distinguish two points of interest 3 and 3 'spaced 5 m in height at a distance D of 1000 m. The necessary precision is given by the relation sin a =. a worth in the r ^r 1000

present case about 0.28 °. It is therefore considered that a quarter-degree attitude measurement system is sufficiently accurate for the present use.

 Returning to FIG. 2a, all the elements mentioned above are integral with a support 15, which can take the form of a retractable tripod which facilitates the handling and transport of the device. Preferably, the device 1 is portable and weighs less than 40 kg, advantageously less than 20 kg, so as to be transportable by a person from one measurement point to another.

 On the tripod 15 can be arranged a support 16 rotating, and optionally variable inclination, for adjusting the trim and azimuth of the device. For simplified use it is also possible to provide a handle 18. Other means, including independent adjustment means 161 of the plate and the azimuth 162 of the device may alternatively be installed.

 The device may include a satellite positioning system

17 (GPS) to read the position of the device during the measurement, which allows to attest to the presence of the device at the location of the source 2 or the point of interest 3, or if necessary to calculate the location of the source 2 and / or the point of interest 3, if the device is in a place 4 distinct from these locations.

 Finally, the device further comprises a processing unit 19, which is connected to the other elements according to the configuration illustrated in FIG. 2b.

 The processing unit is connected to the devices 12, 13, 14 measuring distance and relative positions between the device 1 and the pointed object O, as well as possibly to the sighting device 1 1 and the positioning system 17 for example via Bluetooth, a communication bus such as an RS232 bus, or any other compatible connection means.

 Where appropriate the means for adjusting the attitude 161 and the azimuth 162, if they are electronic, can also be connected respectively to the measuring means 13 and 14 of the attitude and the azimuth.

The processing unit 19 preferably comprises a memory, in which are stored one or more predetermined source models. Each source model is defined by parameters such as the model of the antenna, each model being associated with a radiation pattern. Types antennas may be television broadcast antennas, FM antennas, civilian or military antennas for which the radiation patterns are accessible, or telecommunication antennas.

 Each source model can also be parameterized according to an electromagnetic radiation emission frequency band, an antenna power as a function of the frequency, an azimuth and a selected antenna attitude.

 The processing unit 19 also comprises a processor, adapted to calculate the level of exposure of the point of interest 3 to the radiation generated by the source 2, from the information transmitted by the measuring means 12, 13, 14, and a source model selected in the memory.

 Finally, the processing unit 19 preferably comprises a human-machine interface, making it possible to display results and to receive instructions from an operator.

 This processing unit 19 may for example, but not limited to, be integrated into a mobile phone type "smartphone", a personal assistant (known by the acronym of "PDA"), a tablet digital, or a laptop.

 The processing unit 19 may finally be provided with means for exporting the data, for example ports allowing the connection of removable storage means such as a memory card or a USB key, or communication means, which they can use. are wired or wireless.

With reference to FIG. 4, an example of a method for calculating a level of exposure of a point of interest to electromagnetic radiation emitted by a source implemented by the device 1 is now described.

 During a step 100, a device 1 is positioned at the location of an existing or potential source 2, or a point of interest 3, or a location 4 for the previous locations.

 This step may include adjusting the attitude of the device using the means 161, so that the support of the measuring means is horizontal, and the azimuth using the means 162, for example to identify the north .

This step may also include recording the position of the device 1 using the satellite positioning system 17. During a step 110, the device 1 is pointed towards an object O, this object being the location of the point of interest 3 or the location of the source 2, aiming at the object O, if appropriate with the sighting device 11.

 More precisely, if the device 1 is positioned at the location of the source 2 or the point of interest 3, it is pointed respectively towards the point of interest 3 or the source 2.

 Alternatively, if the device 1 is positioned at the location 4, it is pointed towards one or the other of the source or the point of interest.

 This step may also include the acquisition of photographs of the pointed object. By pointing, it is meant that the device is oriented towards the object, if necessary by changing its attitude and its azimuth.

 During a step 120, the distance D is measured as well as the relative positions between the device 1 and the pointed object O.

 The measurement of the angular difference in height ΔΗ is preferably performed by measuring the attitude of the device once it is pointed towards the object O, and by determining the difference between this measurement and the attitude of the device. set in step 100.

 The measurement of the angular difference in azimuth ΔΑ is performed by measuring the azimuth of the device once it is pointed towards the object O.

 These measurements can be performed automatically or by an operator.

If the device 1 is at a location 4 distinct from that of the source and the point of interest, the steps 1 and 10 of pointing and measuring the distance and the respective positions between the device and the object are repeated. pointed out, by selecting as pointed object that of the source or the point of interest which was not previously the pointed object.

 Thus, the distance and the relative positions between the device 1 and each of the location of the source and the point of interest are known, and it is possible to deduce from these by known trigonometry calculations the distances and relative positions between the source and the point of interest.

During a step 130, the measurements obtained are transmitted to the processing unit 19, and a source model 2 is configured, by selecting certain values for the parameters mentioned above. This configuration includes antenna model selection, antenna power for each frequency band, azimuth, and trim. If necessary, during this step 120, the processing unit 19 also implements the trigonometric calculation steps mentioned above to deduce, from the measurements taken by the device, the distances and relative positions between the point d interest and source.

 The processing unit can then implement the calculation of the exposure level of the point of interest 3 to the source 2.

 To do this, during a step 131, it determines the gain G (f) of the antenna model in the direction of the point of interest, this gain being given by the relation G (f) = Gf (AH) + Gf (A), where Gf is the gain of the antenna at the frequency f in a given angular direction.

 For a multi-band antenna, several gains can be evaluated, such as for example and not limited to G (900M Hz), G (1800M Hz) and G (2100M Hz).

From the gain thus determined, the electric field is calculated during a step 132 using the free space propagation formula, which gives a good approximation of the exposure when there is a direct view between the antenna and the point of interest, which is always the case since the object O is pointed by the device 1.

An electric field E (f) is calculated for each frequency band by the formula £ (/ ^") = ^ £ I2EÎÛ ill _{i or} p (f) _are \ _a power transmitted by the antenna at the frequency f and D distance between antenna 2 and point of interest 3.

Finally, the total field produced by the antenna is calculated by quadratically summing the electric fields at the different frequencies ^' _totai = One can optionally calculate the percentage of the limit prescribed by the ICNIRP that represents the total field, during a step 133. For example, for a tri-band antenna this percentage is given by:% _ICNIRP = J (¾) ² + (¾) ² + (¾) ² ; where E ₉₀₀ =

Electric field at 900 MHz, E _18QQ = Electric field at 1800 MHz, and £ 2100 ⁼ Electric field at 2100 MHz. Finally, during a step 140, the measurement values, the photographs taken and the results of the calculations can be displayed to the attention of the operator and may optionally be exported. Thus the device according to the invention makes it possible to directly determine whether a source complies with the legislation in terms of electromagnetic radiation for a specific location.

Claims

1. Device (1) for evaluating the exposure of a point of interest (3) to electromagnetic radiation emitted by a source (2), characterized in that it comprises:

 sighting means (11) of a pointed object (O);

 means for measuring (12) a distance between the device (1) and the pointed object (O), the pointed object (O) being the location of the point of interest (3) or that of the source (2)

 measuring means (13, 14) for the relative positions of the device (1) and of the pointed object (O),

 processing means (19) able to communicate with the measuring means (12) of the distance between the device (1) and the pointed object (O), and with the measuring means (13, 14) of relative positions the device (1) and the pointed object (O),

wherein the processing means (19) is adapted to calculate, from the measured distance and measured positions, and from at least one predetermined radiation source model, the exposure of said point of interest (3) to electromagnetic radiation emitted by a source (2) according to said model.

2. Device (1) according to the preceding claim, wherein the sighting means (1 1) are a telescope or a camera.

3. Device (1) according to claim 1, wherein the measuring means (13, 14) of the relative positions of the device and the pointed object comprise measuring means (13) of the plate and (14) of the azimuth of the device.

4. Device (1) according to the preceding claim, wherein the measuring means (13) of the plate are selected from the following group: accelerometer inclinometer, balance inclinometer, level, rangefinder.

5. Device (1) according to claim 3, wherein the means (14) for measuring the azimuth are selected from the following group: compass, magnetoresistance sensor, range finder.

6. Device (1) according to one of the preceding claims, comprising a support (16) rotating and variable inclination, adapted to change the azimuth and attitude of the device.

7. Device (1) according to claim 1, further comprising a satellite positioning system (GPS).

8. Device (1) according to claim 1 wherein the means (12) for measuring the distance between the device and the pointed object are a rangefinder.

9. Device (1) according to claim 1, characterized in that it is portable and weighs less than 40 kg, preferably less than 20 kg.

10. Device (1) according to claim 1, further comprising means for exporting data.

A method for measuring the exposure of a point of interest (3) to electromagnetic radiation generated by a source (2), the method comprising the steps of:

 positioning a device (1) according to one of the preceding claims at a location among the location of the source (2), the location of the point of interest (3), or a location (4) in view of the source and the point of interest,

 pointing the device (1) to an object (O) positioned at the location of the point of interest (3) or the source (2),

 measuring the distance and the relative positions between the device (1) and the pointed object (O), and

from the measurements and a predetermined electromagnetic radiation source model, calculating the exposure rate of the point of interest to the electromagnetic radiation generated by a source (2) according to the source model.

12. Measuring method according to the preceding claim, wherein the device (1) is positioned at the location of the source (2) or the point of interest (3), and is pointed at an object (O) positioned respectively at the location of the point of interest (3) or the source (2).

The measuring method according to claim 11, wherein the device (1) is positioned at a location (4) for the location of the source (2) and the point of interest (3), and during which is repeated the pointing steps of the device (1) to an object (O), and measuring the distance between the device (1) and the object (O), before the step of calculating the exposure rate , the pointed object (O) being successively one and the other of the location of the source (2) and the point of interest (3).

14. Measuring method according to one of claims 11 to 13, wherein the measurement of the relative positions of the device (1) and the pointed object (O) comprises: measuring the attitude of the device (1) when it is pointed at the pointed object (O), and

 measuring the azimuth of the device (1) when it is pointed towards the pointed object (O).

15. Measuring method according to one of claims 1 1 to 14, wherein the step of calculating the exposure rate of the point of interest (3) comprises:

 calculating the gain of the source model in the direction of the point of interest (3), and

 calculating the radiofrequency electric field generated by the source (2) at the point of interest (3), according to the gain of the source model, the distance between the location of the source (2) and the point d interest (3), and the frequency of the source (2).

16. Measuring method according to one of claims 11 to 15, wherein the source model comprises the following parameters: an antenna model, an electromagnetic radiation emission frequency band, an antenna power in function of the frequency, an azimuth of the antenna, and a plate of the antenna.

17. Measuring method according to one of claims 1 1 to 16, wherein the step of calculating the exposure ratio further comprises a step of selecting a predetermined source model from a plurality of models stored in a memory of the processing means (19) of the device (1).