METHOD AND SYSTEM FOR REMOTE MONITORING DEFORMATIONS OF A STRUCTURE

TECHNICAL FIELD" The present invention relates to a method and to a system for remote monitoring deformations of a structure.

In particular, the present invention is advantageously, but not exclusively intended for use in the field of monitoring the state of health of structures under stress such a building, a bridge or structural parts of a means of transport or a generic machinery, or parts of a living organism, for example, a muscle or a limb, to which the following description expressly refers without prejudice to the generality thereof. BACKGROUND ART

Deformation sensors based on radio- frequency resonant cavities whose resonant frequency depends on the size of the resonant cavity are well known. Such sensors are inserted in the stressed structural material to be monitored. When the material is subjected to a stress such as to alter the size of resonant cavity, the resonance frequency changes. Therefore, by processing the resonant frequency changes it is possible to trace the deformation of the structure. The sensor is typically equipped with a radio- frequency communication device, for example a

RFID tag ("RFID tag") (Radio Frequency IDentification) , to receive a variable-frequency radio signal from a remote interrogator device, to transfer such a radio signal to the resonant cavity for exciting it and to transmit back the cavity reaction to the interrogator device. In this way it is possible to remotely interrogating the sensor without physical connection, that is "wirelessly" .

The resonant-cavity sensors provide fairly reliable measurements, but have the disadvantage of being rather bulky, and therefore of being particularly invasive and difficult to be installed.

An alternative is provided by the piezoelectric sensors based on MEMS technology, which sensors convert the mechanical variation of the structures to which they are attached in electric signal changes. These sensors have the advantage of having reduced dimensions, compared to those based on resonant cavities, however at the expense of lower reliability. This type of sensors too is provided with a radio- frequency communication device to transmit the information coming from the sensor to the interrogator device .

Other types of sensors are based on optical fiber Bragg gratings. Such sensors provide very accurate deformation measurements but are extremely expensive and bulky as well .

DISCLOSURE OF INVENTION

The purpose of present invention is to achieve a system for remote monitoring deformations of a structure under stress, which overcomes the drawbacks described above and, at the same time, is easy to use and cost-effective to implement.

According to the present invention a method and a system for remote monitoring deformations of a structure are provided as set forth in the appended claims.

Further, according to the present invention a method and a system for remote monitoring displacements of points of a structure are provided as set forth in the appended claims. BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described with reference to the attached drawings, illustrating a non-limiting embodiment thereof, in which: figure 1 illustrates a system for remote monitoring deformations of a structure according to the present invention; and figures 2 and 3 illustrate the system of figure 1 according to further embodiments of the present invention. BEST MODE FOR CARRYING OUT THE INVENTION

In Figure 1, number 1 generically indicates as a whole, the system for remote monitoring deformations of a structure 2.

The depicted system 1 comprises two R.FID tags 3 of known type, namely of the type comprising each a microchip 4 to store information related to the RFID tag 3, including its own identification code, and a miniaturized antenna 5 connected to the microchip 4 to receive and transmit radio signals at a prescribed operating frequency F; an interrogation unit 6 of known type designed to interrogate via radio signals at the operating frequency F the RFID tags 3; an electromagnetic- field measurement unit 7 to obtain measurements of a resultant electromagnetic field produced by the RFID tags 3 in response to said interrogation; and a processing unit 8 to control the interrogation unit 6 and the measurement unit 7 in order to acquire and store, through its own internal memory 9, electromagnetic field measurements and to determine deformations of the structure 2 based on the stored electromagnetic field measurements.

Each RFID tag 3 is of active type, that is, electrically powered by its own battery (not shown) , or of passive type, that is, electrically powered through the transformation of part of the radio frequency electromagnetic field received by the interrogation unit 6 during the interrogation. According to the present invention, the two RFID tags 3 are designed to be coupled to the structure 2 in two points 10a e 10b of the structure itself, and to be positioned at a reference distance D from one

another in order to monitor the deformations of a portion 11 of the structure 2 located between such points 10a and 10b. The RFID tags 3 may be coupled to the structure 2 through bonding, or by fastening with screws, or through appropriate interlocking shapes.

The processing unit 8 is configured to implement the method for remote monitoring deformations of a structure described hereinafter.

The method envisages to interrogate, through the interrogation unit 6, the RFID tags 3 so that a resultant electromagnetic field is produced at a certain distance DINF from a reference point 12 of the structure 2, such a resultant electromagnetic field ensuing from a combination of electromagnetic fields produced individually by each RFID tag 3 in response to the interrogation. Particularly, the interrogation unit 6 sends one or more radio signals that excite both RFID tags 3 in such a way that they simultaneously produce respective electromagnetic fields, which have the same frequency and phase and thus interfere with each other coherently. Therefore, the two RFID tags 3 behave, from the electromagnetic point of view, as a phased antenna array of the broadside type. The interrogation envisages to send a radio signal at the operating frequency F modulated, according to procedures known from the RFID standards, with the identification codes of the two

RFID tags 3 , which simultaneously reply to the radio signal producing respective electromagnetic fields at the operating frequency F.

Alternatively, the interrogation envisages to send, at different time slots, two radio signals at the operating frequency F, each modulated with the identification code of a respective of the RFID tags 3 and with information relating to a response delay associated to such RFID tag 3 so that the two RFID tags 3 can reply simultaneously producing respective electromagnetic fields at the operating frequency F.

Therefore, under the assumption of far- field conditions, that is at a distance DINF such that the two RFID tags 3 are comparable to punctiform sources of electromagnetic field, the resultant electromagnetic field exhibits amplitude and phase distributions, with respect to the angular coordinates (azimuth and elevation) of a polar coordinate system, which distributions have a defined dependence on the distance between points 10a and 10b. In order to fulfil the far-field conditions, the distance DINF needs to satisfy the well known relationships : DINF >> λ DINF > Lmax ² / λ, where Lmax is the largest linear dimension of the antenna 5 of the RFID tag 3 and λ is the wavelength of the resultant electromagnetic field.

The resultant electromagnetic field is measured, by the measurement unit 7 placed at the distance DINF from the reference point 12 of the structure 2, to obtain relative amplitude and/or phase measurements. The amplitude measurements of the resultant electromagnetic field are acquired by the processing unit 8 to build a portion of the radiation surface of the RFID tags 3 at the distance DINF as a function of the azimuth and elevation directions. Null directions are determined by means of such a radiation surface. The null radiations are the directions in which the electromagnetic field intensity is substantially equal to zero and which delimit the main lobe of the radiation surface. The angle between two null directions depends on the ratio between the distance between points 10a and 10b and the wavelength λ of the resultant electromagnetic field, according to simple relationships, which are known from the electromagnetism theory. The phase measurements of the resultant electromagnetic field are acquired by the processing unit 8 to be used alternatively or in combination with the amplitude measurements. The resultant electromagnetic field phase depends on the ratio between the distance between points 10a and 10b and the wavelength λ of the resultant electromagnetic field, according to simple relationships, which are known from the electromagnetism theory.

The choice of the type of measurement to employ is made according to the quality of the radio channel involved.

The electromagnetic field at the distance DINF is measured soon after coupling the RFID tags 3 to the structure 2 in order to have measurements of a reference resultant electromagnetic field, which in the following will be referred to as "reference electromagnetic field" for the sake of simplicity and which corresponds to a reference position of the points 10a and 10b defined by the reference distance D. The reference electromagnetic field measurements are stored in the internal memory 9.

Afterwards, the electromagnetic field is measured each time the state of health of the structure 2 is required to be monitored, that is each time it is required to test whether the portion 11 has undergone deformations in terms of a mutual displacement between points 10a and 10b, and more specifically whether there has been a change of distance between points 10a and 10b with respect to the reference distance D.

The subsequent measurements of the resultant electromagnetic field are then compared with the measurements of the reference electromagnetic field in order to establish possible variations of the resultant electromagnetic field. The variations of the distance between points lOa and 10b with respect

to the reference distance D are determined as a function of variations of the resultant electromagnetic field on the basis of the above mentioned relationships. The accuracy in determining the deformations depends on the alleged order of magnitude of the deformations with respect to the wavelength λ of the resultant electromagnetic field. Therefore, in order to measure deformations in the centimetre range the RFID tags 3 are preferably of the kind operating in the microwave band, such as those having an operating frequency F inside the 2,45 GHz band or inside the 5,8 GHz band. Similarly, in order to measure deformations in the millimetre range, the RFID tags 3 are preferably of the kind operating at millimetre- wave frequencies.

Figure 2 illustrates a second embodiment of the present invention. The second embodiment differs from that of figure 1 in that the system 1 comprises more than two RFID tags 3, and in particular three RFID tags 3 designed to be coupled to the structure 2 at respective not-aligned points of it, which points are referred to as 10a, 10b, 10c and are positioned at relative reference distances Dab, Dae, Dbc from each other. The reference distances Dab, Dae and Dbc define a reference arrangement of the points 10a, 10b and 10c.

Furthermore, the method for remote monitoring

deformations of a structure implemented by the processing unit 8 according to the second embodiment envisages to interrogate the RFID tags 3 in pairs and to measure the resultant electromagnetic field produced by each interrogation of RFID tag 3 in pairs. In particular, the interrogation is carried out at least for one of the combinations without repetition of a pair of RFID tags 3, that is, the two RFID tags 3 fixed in points 10a and 10b, and/or those fixed in points 10a and 10c, and/or those fixed in points 10b and 10c.

That way it is possible to monitor the deformations of a portion 11 of structure 2 comprised in the polygon whose vertexes are the points 10a, 10b, and 10c with respect to the reference arrangement. As an example, mutual displacements among points 10a 10b and 10c, that is the variations of the distances between the same points 10a 10b and 10c with respect to the reference distances Dab, Dae and Dbc may be further processed to find the instantaneous rotation centre of the portion 11 with respect to a fixed reference system.

In case a first of such points 10a, 10b, 10c is regarded as essentially fixed, as for example the point 10a, then it is worthwhile to interrogate only the pairs of RFID tags 3 that share the RFID tag 3 located at point 10a to determine the variations of the distances of points 10b and 10c from the point

10a with respect to the reference distances Dab and Dae respectively.

From the above it is clear that the functioning of the system 1 does not change substantially in case it comprises more than three RFID tags 3. In other words, a system 1 comprising more than three RFID tag 3 is basically a generalisation of the system 1 having two or three RFID tags 3 that can be used to obtain more detailed information on deformations of wider portions 11 of the structure 2 to be monitored, possibly by means of triangulation techniques.

According to a third embodiment of the present invention, which is illustrated in Figure 3 in the particular case of three RFID tags 3, the system 1 comprises a further RFID tag 3 positioned in a reference point 13 outside the structure 2 and considered fixed with respect to possible deformations or displacements of the structure 2. Particularly, the RFID tags 3 that are coupled to the structure 2 in points 1Oa ₁ 10b and 10c result to be positioned at respective reference distances Da Db Dc from the reference point 13. The method for remote monitoring deformations of the structure implemented by the processing unit 8 according to the third embodiment envisages to interrogate pairs of RFID tags 3, each pair comprising the RFID tag 3 positioned in the reference point 13 in order to determine the displacements of points 10a 10b and 10c

with respect to the reference point 13 , that is the variations of the distances of points 10a 10b and 10c from the reference point 13 with respect to the reference distances Da, Db and Dc. This makes it possible to monitor, beside the deformation of portion 11 of the structure 2, any rigid roto- translations of the portion 11 with respect to the reference point 13. From the above it is understood that the functioning of the system 1 according to the third embodiment will not change in case the system 1 comprises two or more than three RFID tags 3.

The latter embodiment highlights another possible use of the system 1. Indeed, the underlying concept of the present invention, that is the ability to remotely monitor variations of distances between any two points in the space by interrogating two RFID tags 3 associated to these points in the way previously described and by measuring the resultant electromagnetic field produced by these sources, permits to use the system 1 as a system for remote monitoring displacements of the points 10a, 10b, and 10c of the structure 2 with respect to one of them, as for example point 10a, or with respect to an external reference point 13, with an accuracy within one millimetre. In other words, the system 1 implements a function of fine localization of objects, or parts of a same object or structure, which objects or parts of an object a coupled to

respective RFID tags 3.

The main advantages of the system 1 for remote monitoring deformations of a structure described above, compared with existing systems used for the same purpose, derive from the fact that each pair of RFID tags 3 constitutes both the deformation sensor and the communication device used to transmit the information acquired by the sensor to the interrogation unit 6. This results, firstly, in much lower costs with respect to existing solutions. Secondly, the very limited size and weight of the RFID tags 3 allow to attach the RFID tag 3 to any structure 2, for instance to a sail of a boat, to a body shell of a car, or into an artificial limb, thus broadening the fields of application of the system 1.

Furthermore the system 1 works without straining the deformation sensor, which consists of two or three RFID tags 3, and this results in a further twofold advantage. First of all, it is possible to couple the deformation sensor to the structure 2 to be monitored in a non- invasive way. In addition, it is possible to monitor the magnitude of a crack in the structure 2 by means of two RFID tags 3 fixed to respective sides of such crack, up to deformations whose size may theoretically reach several wavelengths, which is impossible for any sensor based on the resonance principle.

Finally, the system 1 provides measurements

substantially independent of any changes in environmental parameters, such as the humidity of the air and in particular the temperature, as well as possible variations of the RFID tags 3 behaviour, for example due to aging or exposure to the environment , since the null directions of the field depend exclusively on the array factor, and thus on the ratio between the distance between the RFID tags 3 and the wavelength λ. Therefore the system 1 does not require nor complex and delicate calibration procedures for compensating variations of the environmental parameters, nor the detection of values of the same. On the contrary, the environmental conditions may directly affect the results provided by sensors known so far, which need to be calibrated appropriately. As an example, a temperature variation always originates variations of the size of a resonant cavity and thus of its own resonance frequency, that could be erroneously understood as due to a deformation of the structure 2.