ITTO960034A1 - ANTI-TAMPERING DEVICE, FOR EXAMPLE FOR SURVEILLANCE SYSTEMS - Google Patents

Abstract

The sensor (1) is preferably made in the form of a so-called fruit intended to be inserted in a flush-mounted box (C) of an electrical system. On the sensor casing there is an emitter (7) - receiver (8) pair, typically operating in infrared. The attempt to tamper with the sensor (S) produces a modification of the propagation characteristics between the emitter (7) and the receiver (8), with the consequent possibility of emitting a warning signal (Figure 2).

Description

DESCRIPTION of the industrial invention entitled:

Anti-tampering device, for example for surveillance systems "

TEXT OF THE DESCRIPTION

The present invention refers to anti-tampering systems. In particular (this indication must not however be interpreted in a limiting sense) the invention has been developed in view of the possible application to the protection of sensors of surveillance systems, such as for example anti-theft or anti-intrusion systems.

In this application context, the tendency has been widespread for some time to use as sensors components which are capable of being mounted in the manner of normal "fruits" in the flush-mounting boxes of the electrical systems of buildings. A solution of this type is described, for example, in the European patent EP-B-0484 293, owned by the same Applicant.

Precisely because of their typical location, at the same height, for example, as the switches and diverters of an electrical system, these sensors are very exposed to tampering, such as attempts to neutralize them. For this reason, some regulations require the provision of special anti-tamper functions (so-called "anti-tamper" functions).

To respond to this need, different solutions have already been proposed.

A known solution provides, for example, with the use of devices with magnetic operation consisting of a fixed part integral with the recessed box and housing a permanent magnet. The component part of the safety system is provided with a reed relay kept in the closed position by the magnetic field generated by the magnet mounted on the fixed part mentioned above. Moving the component from its mounting position causes the relay to move away from the magnet, with consequent opening of the relay contact and issuing of a warning signal.

This solution has the main advantage of giving rise to a very low energy consumption. On the other hand, it has several significant drawbacks.

A first drawback derives from the fact that the location of the fixed part of the anti-tamper device in the flush-mounted box is rather uncomfortable, among other things in consideration of the further reduction of the free space (already not normally very large) available inside the box for the passage of the wires.

It is also difficult to obtain a very precise positioning (required to safely achieve the closure of the relay contact): in many cases, the incorrect positioning (or even the lack of location on site) of the device is not immediately detectable.

In addition to this, each component must be provided together with the relative fixed part of the anti-tamper device, which entails additional costs. It can also happen that the fixed part of the device is not compatible with the type of flush-mounted box in which you are operating.

The present invention has the aim of providing a solution capable of giving a completely satisfactory solution to the above requirements while avoiding the aforementioned drawbacks.

According to the present invention, this object is achieved thanks to a device having the characteristics recalled in the following claims.

The invention will now be described, purely by way of non-limiting example, with reference to the attached drawings, in which:

Figure 1 schematically illustrates a typical situation of use of a device according to the invention, - Figure 2 shows a possible mounting arrangement of a device according to the invention,

Figure 3 illustrates, in the form of a block diagram, the circuit structure of a device according to the invention;

Figure 4, consisting of four superimposed time diagrams indicated by a, b, c and d, illustrates the typical trend of some signals generated in the context of a device according to the invention.

In Figures 1 and 2, C indicates as a whole a flush-mounted box of the type currently used in domestic and industrial electrical systems. The box C is intended to be embedded in a wall M and to be closed on its front side, facing the outside of the wall M, by a closing plate P in which a plurality of openings S are provided which form respective seats for the assembly of so-called "fruits" (consisting of components such as switches, shunts, electrical sockets, etc ...). Usually, the external face of the plate P is closed by a covering element F (so-called "mask"), provided with respective openings T corresponding to the seats S provided for the assembly of the components (fruits) housed in the box.

All this corresponds to completely current knowledge in the field of electrical systems and also known to the general public for the wide diffusion of the solution.

Also known, for example from the European patent EP-B-0 483 293 already cited in the introductory part of this description, is the possibility that one or more of the fruits mounted on the box are constituted, instead of by traditional components such as switches, diverters, sockets electrical, "dimmer", from sensors of a surveillance system. As in the case of the European patent EP-B-0483 293, it can be an infrared intrusion sensor included in the context of an anti-theft system (not shown as a whole).

However, it should be pointed out that the invention completely disregards the nature of the protected component, which can therefore be constituted by any fruit. The scope of the invention is therefore in no way limited to the sensors of the surveillance systems.

Figure 2 shows the protected component, indicated as a whole with 1, in its normal mounting position inside the box c. Referring, purely by way of example, to a sensor such as that described in the European patent cited several times above, it can be noted that it is enclosed in a respective casing 2 comprising a front face, protruding outside the mask F on which it is located. its active or sensitive part. It can be, for example, an infrared sensor 3 provided at the front with a focusing lens such as a Fresnel lens associated with a respective processing circuit 4 (Figure 3) such as a so-called CPU. The latter communicates through respective terminals 5, usually located on the rear wall of the casing 2 (i.e. on the paxete which, in the normal mounting position as shown in Figure 2, faces the back wall of the flush-mounted box C) , with the related system (not shown as a whole). Communication is usually carried out via wires 6 (figure 2) connected, typically by screwing, to terminals 5.

For the sake of clarity of illustration, it should be noted that - in the currently preferred embodiment - the solution according to the invention envisages exploiting the CPU 4 usually already present in the sensor 1. This solution, although preferred, is by no means mandatory.

As already said several times, the invention lends itself to being applied also to components other than sensors, and in particular to components without autonomous processing capacity: in this case, the signals that will be presented below as emitted and received by the CPU 4 can be received and transmitted to and from the system of which component 1 is a part through wires such as the wires indicated with 6.

For a better understanding of the typical context of application of the invention, it should be noted that the mounting conditions of the component 1 inside the box C can be highly differentiated according to numerous factors.

First of all, the box C, and in particular its bottom wall, towards which the component 1 extends, can be made with different materials, for example with plastic materials having surface characteristics (more or less smooth surface) and / or different chromatic (color).

Secondly, the box C may have been accidentally soiled, before and after the collection, with various materials such as lime, paints, etc.

The depth of recess of the box in the wall M may also be different from time to time; since component 1 is usually supported on the front plate P, applied flush with wall M, component 1 itself can be at different distances from time to time with respect to the back wall of box C.

Furthermore, in box C there are normally both the connection wires 6 of the component 1 in question, and the connection wires of the other components present in the box C, and also possible through wires, not belonging to any component.

Finally, component 1 may not be the only sensor (or possibly the only emitter) present in box C: it may therefore be important to ensure that sensors of the same or similar type do not disturb each other during operation.

In order to take into account the above requirements, the currently preferred embodiment of the invention provides for arranging, preferably (but not necessarily) on the rear face of the casing 2 of the component 1, an optoelectronic pair formed by an emitter 7 and by a receiver 8. The emitter 7 introduces into the cavity defined by the box C (see Figure 2) an optical radiation (typically in the infrared range, even if this choice is not mandatory). Typically, the emitter 7 is an infrared emitter such as a LED, while the photoreceiver 8 which detects at least a fraction of the radiation generated by the emitter 7, is a photodiode with spectral characteristics complementary to those of the emitter 7.

In a nutshell, the solution according to the invention is based on the fact that the radiation generated (usually towards the back wall of the box C) by the emitter 7 spreads inside the box C itself, being reflected and diffused according to a distribution of fairly complex propagation lines, determined by the complex of factors mentioned above: nature and shape of the box C, possible presence of numerous diffusion / reflection sources such as wires, etc.). The intensity of the radiation picked up by the receiver 8 therefore depends on this set of factors.

At the time of installation, the anti-tamper device can therefore be calibrated according to the conditions of propagation of the radiation from the emitter 7 to the receiver 8 in the specific mounting situation.

Any modification of these propagation conditions induced by the displacement, even minimal of the component 1 (such as the displacement that can derive from an attempt to tamper with if not from an attempt of total removal), is therefore detected by the receiver 8 as a variation of the detection signal captured, with the corresponding emission, through the CPU 4 (if present) and the connection line 6, of a warning message intended for the system of which the sensor 1 is part.

In the currently preferred embodiment, the control unit of the device (hereinafter 3i will explicitly refer to the CPU 4 even if - as already mentioned - the use of this specific solution is not mandatory) sends with a periodicity interval given (for example 200-500 milliseconds) an activation signal to a driving circuit 9. The circuit 9 applies to the emitter (led) 7 a ramp driving signal such as to cause the emitter 7 to turn on starting from a minimum brightness level (signal intensity) to then reach a maximum level in sufficiently short terms, for example 5 milliseconds.

To illustrate this mode of operation, reference can be made to figure 4, whose diagrams are represented with a common time scale (abscissa scale), noted with t

In particular, the diagram above (indicated with letter a) represents in an arbitrary ordinate scale, the activation pulse applied at intervals T (typically equal to 200-500 milliseconds) to the ramp driver circuit 9.

The diagram indicated with b represents instead (also here in a scale of arbitrary ordinates) the intensity of both the driving signal generated by the circuit 9 and - apart from possible nonlinearities - the intensity of the signal produced by the emitter 7. This signal affects on the receiver 8 with an intensity determined by the specific propagation conditions inside the box C. The output signal of the receiver 8 senses a signal trend such as that schematically illustrated in diagram c of figure 4, it is sent, to a comparator 10, in which it is compared with a reference level W shown in pieces in the same diagram c of Figure 4.

As already mentioned, the overall ramp rise time {referred to both diagram b and diagram c) is chosen equal to a time interval TI of the order, for example, of 5 milliseconds, therefore a time interval of substantially shorter duration (for example by two orders of magnitude) than the interval T, which corresponds to the repetition interval of the tamper test.

The output signal of the comparator 10 is obviously constituted by a logic signal which assumes two different values ("low" and "high", or "0" and "1", in the example illustrated) respectively when the signal coming from the receiver 8 is respectively below and above the level of the threshold W.

The duration of the permanence at one of the two logic levels in question (with reference to diagram d of figure 4, reference can be made, for example, to the logic level "high" or "1") provides an indication of the time necessary for the signal derived starting from receiver 8 is able to reach the threshold level W.

This time interval depends - ceteris paribus - on the propagation conditions of the radiation between the emitter 7 and the detector 8, and is therefore not determinable a priori. However, once the component 1 has been placed inside the box C with the application of the plate P and the so-called escutcheon F, the propagation conditions in question being univocally fixed, it has a predetermined duration.

Consequently, any displacement of the component 1 with respect to the initial mounting position (for example the displacement resulting from an attempted tampering) automatically results in a change in the conditions of propagation of the radiation between the emitter 7 and the receiver 8 (for example because the component 1 has moved away from the back wall of the box C, because one or more of the connection wires and / or the wires present in the box has moved, etc.) and determines a variation of the signal trend deriving from the action threshold (diagram d of figure 4) as well as schematically illustrated with dashed line and with dashed line and dot in the same diagram d of figure 4. This signal is sent to the CPU 4 which, having detected a change in the trend of the signal in question identifies the tampering attempt and sends a respective warning signal to the system in which component 1 is included.

In practice, CPU 4 counts - in a known way - the duration of the interval or intervals of time in which the signal shown in diagram d remains at the "high" (or low "logic level, which is equivalent) and, whenever it detects a deviation from the duration determined during calibration, for example when component 1 has been mounted in box C, it generates a warning signal.

Naturally, during the assembly and / or calibration of component 1, it is possible to check for the presence of anomalous conditions, for example if it is found that the optical radiation captured by the receiver 8 is so weak that it does not allow the threshold level to be reached. W for the entire interval TI of duration from the power supply ramp of the emitter 7. In this case the installer can intervene, for example, on the driving circuit 9, on the comparator 10 (by varying the position of the threshold W) and / or on the intervention logic of the CPU 4 or even remedy the physical cause (eg inside the C box overall too absorbent) that gives rise to the faulty operation. In a complementary way, the installer can immediately detect and remedy the presence of accidental conditions of complete or substantial short-circuit between the emitter 7 and the receiver 8 (for example due to the accidental presence of a reflective element applied in correspondence with the back wall of the casing 2) capable of causing the conditions of propagation of the radiation between the two elements 7, 8 are in fact unaffected by the position of the component 1.

In this regard it is interesting to note how (even in the case of an infrared photodetector) the receiver 8 is at least partially sensitive also to the visible ambient light. This feature is important for detecting tampering attempts made by trying to eradicate box C as a whole from wall M. Box C is in fact usually provided on its side walls with slits, openings, etc. such as for example facilitated breaking lines, wire passage openings, etc ... As soon as the box C is detached from the wall M of the box, the ambient light enters the box itself, and can thus be picked up by the detector 8 with possible consequ issuing a warning signal.

It will be appreciated that the device according to the invention is capable of being calibrated according to the actual application. Practical tests conducted by the Applicant have shown that even very absorbent environments still cause sufficient propagation conditions of the radiation between elements 7 and 8. The absorption of energy is generally a function of the reflection characteristic and of the repetition rate of the operating phases. of the device. In any case, the preferred operating conditions mentioned above (repetition of the tamper test at intervals T of the order of 200-500 milliseconds, ramp duration T1 equal to 5 milliseconds) allow to obtain a very low average consumption.

In particular, in the case in which several components 1 such as the one described in detail above are mounted in the same box C, it is possible to synchronize the operation of the respective anti-tampering devices in such a way that the execution of the tamper test in a component does not temporally overlap the carrying out the same test in another component, so as to prevent the respective anti-tampering devices from influencing each other. This operating mode can be easily implemented, for example, by using the solution for regulating the access of several systems to a bus described in the European patent application 95109682.5, owned by the same Applicant.

Naturally, without prejudice to the principle of the invention, the details of implementation of the embodiment may be widely varied with respect to what is described and illustrated, without thereby departing from the scope of the invention. This applies in particular as regards the possibility of using, for the purposes of detecting tampering, radiation or, in general, wave fields other than optical infrared radiation to which explicit reference was made previously. For example, it is possible to use optical radiation in the visible range. Furthermore, instead of electromagnetic radiation it is possible to use, for example, ultrasonic radiation. In the latter case, under normal conditions (absence of tampering) a wave field is established inside the flush-mounting box C which is disturbed in the presence of an attempted tampering. This solution lends itself to being realized both by resorting to an emitter / receiver pair, and by using a single capsule with transceiver function, therefore capable of acting both as a means for the generation of the ultrasonic wave front, and as a means for the detection of the itself (ultrasonic capsules that perform these functions are currently commercially available).

Claims (13)

CLAIMS 1. Tamper detection device for components such as for example sensors (1) mounted, in use, in respective containment boxes (C), characterized in that it comprises: - generating means (7) for producing a detection signal propagating in said containment box (C) under given conditions, and detection means (4, 8) sensitive to said detection signal propagating in said containment box (C), whereby any tampering with component (1) produces the variation of said given conditions and a consequent variation of said detectable detection signal by said detecting means (8), and - warning means (4, 6) connected to said detection means (8) for signaling the variations of said detection signal detected by said detection means (8). 2. Device according to claim 1, characterized in that said generating means (7) generate, as a detection signal, an infrared optical signal. 3. Device according to claim 1 or claim 2, characterized in that said element {1) is enclosed in a casing (2) and said generator means (7) and said detector means (8) are arranged, at least in part, on the casing (2) of said component. 4. Device according to claim 3, characterized in that said casing (2) has a facing face, in the condition of use, inside said respective containment box (C) and by the fact that said generating means (7) and said detector means (8) are arranged, at least in part, on said face. 5. Device according to any one of the preceding claims, characterized in that it comprises generator means (7) and detector means (8) which are distinct from each other. 6. Device according to any one of the preceding claims, characterized in that said generator means (7) are activated at discrete time intervals (Tl). 7. Device according to any one of the preceding claims, characterized by the fact that said generating means (7) have associated driving means (9) acting with variable intensity, so that said detection signal has an intensity which varies over time and by the fact that said detection means (4, 8) detect the moment in which said detection signal detected by said detector means reaches a predetermined level (W), the variation in the time of said moment being indicative of the variation of said given conditions. 8. Device according to claim 7, characterized by the fact that said driving means (9) pilot said generating means (7) with a signal having a general ramp pattern and by the fact that said sensing means (4, 8) detect the reaching , by said detection signal, of a respective threshold level (W). 9. Device according to claim 6, characterized in that said generating means (7) are activated with a given periodicity (T) and by the fact that, at each activation, said generating means (7) are activated for a time interval ( Tl) with a duration substantially shorter than the period of said periodicity given (T). 10. Device according to claim 6, characterized in that said given periodicity (T) corresponds to a period of the order of 200-500 milliseconds. 11. Device according to claim 9 or claim 10, characterized in that, at each activation, said generator means (7) are activated for a time interval (Tl) of the order of 5 milliseconds. Device according to any one of the preceding claims, characterized in that said detector means comprise a receiver (8) sensitive to said detection signal with associated processing means (4) of the signal generated by said receiver (3), said means of processing signaling (6) also said variations of said detection signal. 13. Device according to any one of the preceding claims, capable of being used in a system comprising a plurality of distinct components (1) mounted in a common containment box (C) and each provided with a tamper detection device according to any of the preceding claims, characterized in that said generating means (7) associated with the tamper detection devices of said distinct components (1) are activated in respective discrete time intervals (Tl) separated from the activation time intervals of the respective generating means (7) associated with the other components mounted in said common containment box (C). All substantially as described and illustrated for the specified purposes.