VEDANI, Carlo (Via Astico 41, VARESE, I-21100, IT)
| C L A I M S
1. A method of detecting intrusions in closed volumes, in particular for passenger compartments of vehicles, characterised in that it comprises the following steps:
- generating a main signal (10) at a main frequency (fl), propagation of which is caused in a predetermined closed volume or space;
- detecting an auxiliary signal (20) obtained from interaction between the main signal (10) and said space;
- phase-demodulating, preferably in a coherent manner, said auxiliary signal (20), sampling the same at least at a frequency (fa, fb) lower than said main frequency (fl), thus obtaining at least one corresponding demodulated signal (30, 40) ;
- carrying out a first comparison of said at least one demodulated signal (30, 40) with at least one predetermined threshold (si, s2); - generating an alarm signal (60) as a function of said first comparison.
2. A method as claimed in claim 1, characterised in that said frequency (fa, fb) lower than said main frequency (fl) is a subharmonic of said main frequency (fl).
3. A method as claimed in claim 1 or 2, characterised in that said step of phase-demodulating said auxiliary signal (20) comprises:
- demodulating said auxiliary signal (20) at a first frequency (fa) , thus obtaining a corresponding first demodulated signal (30);
- demodulating said auxiliary signal at a second frequency (fb) , thus obtaining a corresponding second demodulated signal (40) , said first and second demodulated signals being mutually out of phase by a predetermined non-zero phase displacement (d) , which phase displacement is preferably egual to 90°, at least one of said first and second frequencies (fa, fb) being lower than said main frequency (fl) .
4. A method as claimed in claim 3, characterised in that at least one, and preferably both, of said first and said second frequency (fa, fb) is a subharmonic of said main frequency (fl) .
5. A method as claimed in claim 3 or 4, characterised in that said step of generating said first demodulated signal (30) comprises the following sub-steps:
- inputting said auxiliary signal (20) to a first sarαple-and-hold circuit (120);
- activating said first sample-and-hold circuit to said first frequency (fa) , thus obtaining said first demodulated signal (30) at said sample-and-hold circuit (120) output.
6. A method as claimed in anyone of claims 3 to 5, characterised in that said step of generating said second demodulated signal (40) comprises the following sub-steps :
- inputting said auxiliary signal (20) to a second sample-and-hold circuit (130) ; - activating said second sample-and-hold circuit to said second frequency (fb) , thus obtaining said second demodulated signal (40) at said sample-and-hold circuit (130) output.
7. A method as claimed in anyone of the preceding T2007/000135
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claims, characterised in that it further comprises the following steps:
- amplitude-demodulating said auxiliary signal (20) , thus obtaining a corresponding amplitude-demodulated signal (50) ;
- carrying out a second comparison of said amplitude- demodulated signal (50) with at least one respective threshold (s3) ;
- generating said alarm signal (60) also as a function of said second comparison.
8. A method as claimed in claim 7, characterised in that it further comprises the following steps:
- carrying out an auxiliary comparison between an amplitude of the amplitude-demodulated signal (50) and at least one pre-set value (s4);
- depending on the result of said auxiliary comparison, piloting from a stand-by condition to an operating condition, a processing unit (160) designed to receive said phase-demodulated signals (30, 40) and said amplitude-demodulated signal (50) and generate said alarm signal (60) .
9. A method as claimed in claim 8, characterised in that it further comprises a step of maintaining said processing unit (160) in the stand-by condition during generation of said main signal (10) .
10. A method as claimed in anyone of the preceding claims, characterised in that the step of generating said main signal (10) comprises the following sub- steps :
- generating at least two secondary signals, having lower frequency than said main frequency; - combining said secondary signals with each other to 0135
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obtain a signal having the same frequency as said main frequency (fl) .
11. A method as claimed in claim 10, characterised in that said secondary signals are out of phase with respect to each other by a non-zero phase displacement.
12. A method as claimed in claim 10 or 11, characterised in that at least one of said secondary ' signals, and preferably both said secondary signals, have a frequency equal to half the main frequency (fl) .
13. A method as claimed in claim 10 when appendant to claim 5 or 6, characterised in that at least one of said secondary signals has the same frequency as said first and/or second frequency (fa, fb) and is used for activation of said first and/or second sample-and-hold circuit (120, 130) .
14. A device for detection of intrusions in closed volumes, in particular for passenger compartments of vehicles, characterised in that it comprises:
- a radiation generator (100) to generate a main signal (10) at a main frequency (fl) , propagation of which in a predetermined closed volume or space is caused;
- a detector (110) to detect an auxiliary signal (20) obtained by interaction between the main signal (10) and said space;
- a phase demodulator "(120, 130) , which is preferably coherent, to phase-demodulate said auxiliary signal preferably in a coherent manner, sampling the same at a frequency (fa, fb) lower than said main frequency (fl) , thus obtaining at least one corresponding demodulated signal (30, 40) ; - a processing unit (160) operatively associated with 5
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said -demodulator (120, 130) to carry out a first comparison of said at least one demodulated signal (30,40) with at least one predetermined threshold (si, s2) and generate an alarm signal (60) as a function of said first comparison.
15. A device as claimed in claim 14, characterised in that said frequency (fa, fb) is a subharmonic of said main frequency (fl) . .
16. A device as claimed in .claim 14 or 15, characterised in that said phase demodulator (120, 130) comprises :
- a first sampling module (121) to sample said auxiliary signal (20) at a first frequency (fa) and obtain said first demodulated signal (30); a second sampling module (131) to sample said auxiliary signal (20) at a second frequency (fb) and obtain said second demodulated signal (40); said first and second, demodulated signals (30, 40) being out of phase with respect to each other by a nonzero phase displacement (d) , which phase displacement (d) is preferably equal to 90°, at least one of said first and second frequencies (fa, fb) being lower than said main frequency (fl) .
17. A device as claimed in claim 16, characterised in that at least one, and preferably both, of said first and said second frequency (fa, fb) is a subharmonic of said main frequency (fl) .
18. A device as ..-claimed in claim 16 or 17, characterised in that said first sampling module (121) is included in a first sample-and-hold circuit (120) adapted to receive said auxiliary signal (20) as an — ? 3 —
input and to output said first demodulated signal (30) , said first sample-and-hold circuit (120) operating at said first frequency (fa) .
19. A device as claimed in anyone of claims 16 to 18, characterised in that said second sampling module (131) is included in a second sample-and-hold circuit (130) adapted to receive said auxiliary signal (20) as an input and to output said second demodulated signal (40), said second sample-and-hold circuit (130) operating. at said second frequency (fb) .
20. A device as claimed in anyone of claims 14 to 19, characterised in that it further comprises: - an amplitude demodulator (140) to amplitude- demodulate said auxiliary signal (20), thus obtaining a corresponding amplitude-demodulated signal (50), said processing unit (160) being operatively associated with said amplitude demodulator (140) to carry out a second comparison of said amplitude-demodulated signal (50) with at least one respective threshold (s3) , and generate said alarm signal (60) also as a function of said second comparison.
21. A device as claimed in claim 20, characterised in- that it further comprises an auxiliary comparison module (150) to compare said amplitude-demodulated signal (50) with at least one predetermined threshold
(s4) and pilot, depending on this comparison, said processing unit (160) from a stand-by condition to an operating condition.
22. A device as claimed in claim 21, characterised in that said processing unit (160) is maintained to the stand-by condition during generation of said main 5
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signal ( 10 ) .
23. A device as claimed in anyone of claims 14 to 22, characterised in that said processing unit (160) has at least two outputs to supply respective secondary signals, each having a lower frequency than said main frequency (fl) , said device further comprising ' a combination module to..combine said secondary signals with each other and obtain a signal having the same frequency as said main frequency (fl) .
24. ' A device as claimed in claim 23, characterised in that said secondary signals are out of phase with respect to each other by a non-zero phase displacement.
25. A device as claimed in claim 23 or 24, characterised in that at least one of said secondary signals, and preferably all said secondary signals, have a frequency equal to half the main frequency (fl) .
26. A device as claimed in claim 23 when appendant to claim 18 or 19, characterised in that at least one of said secondary signals has the same frequency as said first and/or second frequency (fa, fb) and is used for activation of said first and/or second sample-and-hold circuit (120, 130) . |
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"METHOD AND DEVICE FOR DETECTION OF INTRUSIONS IN CLOSED VOLUMES, . IN PARTICULAR FOR PASSENGER COMPARTMENTS OF VEHICLES"
D e-s c r i p t i o n
The present invention relates to a method of detecting intrusions in closed volumes, in particular for passenger compartments of vehicles.
The present invention also relates to a device intended for carrying out said method.
It is known that different systems for detecting intrusions in the passenger compartments of vehicles, in particular motor-vehicles, are presently available on the market.
These systems generally contemplate radiation emission to a predetermined frequency (e.g. in the ultrasonic wave range) and subsequent detection of the radiation reflected by the elements constituting the volume or space to be monitored.
The reflected radiation is then suitably processed and, if the physical characteristics of this radiation are someway altered relative to predetermined pre-set values representative of standard "non-intrusion" conditions of the closed volume, then an alarm signal is generated aimed at warning the vehicle's proprietor and/or the personnel in charge of security.
A type of analysis that can be carried out on the reflected wave substantially consists in a coherent phase demodulation, supplying two signals that are
shifted 90° out of phase from each -other (as described in the United States Patent No. 6,057,760, for example) .
Of the two wattless components, both the amplitude for a first individualisation of a possible intrusion situation and the time evolution are evaluated, to determine behaviour of the vector defined by said two components and evaluate the course thereof in the complex plane, so as to confirm occurrence of intrusion or not as a function of the number of revolutions carried out by said vector in the complex space in a predetermined time interval .
It is to be noted that the two wattless components are obtained by multiplying the reflected signal by two substantially equal signals, shifted 90° out of phase with respect to each other and both having the same frequency of the initially generated signal.
Taking into account the fact that the frequency of the starting signal can be in the order of 40 kHz, it is apparent that a method like that described above is very expensive both in terms of required power and in terms of hardware circuitry used to perform the analysis .
In fact, for being able to manage three signals at frequencies in the order of tens of kHz substantially simultaneously, it is necessary for the processor used to be able to operate to some speed; in addition, since a high-frequency operation involves a corresponding current input, this type of operations are very expensive from the point of view of energy consumption.
Accordingly, the present invention aims at making available a method and a device capable of detecting intrusions in a reliable manner while at the same time reducing the energy consumption for processing of the different signals used.
Another aim of the invention is- to provided a method and a device that, without reducing the reliability of the process for detecting intrusions, can also utilise a processing unit having a lower computational capacity as compared with those required in the systems made available by the .state of the art.
It is a further aim to reduce the risk of cross-talks between the different signals that are processed in accordance with the method and device of the invention.
An auxiliary aim of the invention is to further reduce power consumption, minimising use of the available hardware depending on the characteristics of the detected signals.
The foregoing and still further aims are substantially achieved by a method and a device for detection of intrusions in closed volumes, in particular for passenger compartments of vehicles in accordance with the features recited in the appended claims.
Further features and advantages will become more apparent from the detailed description of a preferred embodiment of a method and an apparatus in accordance with the invention. This description is provided with reference to the accompanying drawings given by way of non-limiting example, in which: - Fig. 1 shows a block diagram of a device in
accordance with the invention;
- Fig. 2 is an alternative embodiment of the device shown in Fig. 1; and
- Fig. 3 shows the time course of signals that can be used in the device and method of the invention.
With reference to Fig. 1, a device in accordance with the invention through which the method of the present invention is put into practice is generally identified with reference numeral 1.
The method of the invention first of all comprises a step of generating a main signal 10 at a main frequency fl, propagation of which in a predetermined space is caused.
The main signal 10 preferably is an ultrasonic radiation of a frequency that can be included between 20 kHz and 60 kHz. In particular, the main signal 10 can have a frequency of 40 kHz.
Propagation of the main signal 10 is caused in the space, typically a closed volume, in which detection of possible intrusions is carried out.
Preferably the main signal 10 is not emitted continuously but periodically, the period being in particular included between 100 ms and 300 ms and each pulse having a duration included between 30 ms and 100 ms.
As mentioned above, this closed volume can be the passenger compartment of a vehicle, and in particular the passenger compartment of a motor-vehicle.
The main signal 10, in the absence of intrusions or cross-talks, creates a stationary field inside the space to be monitored.
As better clarified in the following, in case of intrusions, disturbances in said stationary field will be caused that will be conveniently detected so as to notify the vehicle's proprietor in a suitable manner and/or the staff charged with monitoring of same.
Different techniques can be used for generation of the main signal 10.
A first mode consists in generating a signal, by a processor for example, at the desired main frequency fl, said signal being directed to a suitable device for propagation of the main signal 10 (in this connection see Fig. 1) .
Alternatively, at least two secondary signals can be generated, both of them being at a lower frequency than the main frequency fl, and the same can be combined to obtain the signal at the main frequency fl to be sent to the device suitable for propagation of the . main signal 10 (Fig. 2) .
Preferably, the secondary signals are out of phase with respect to each other by a non-zero phase displacement and the secondary signals can have the same frequency, for example.
In one embodiment of the invention, at least one of the secondary signals has a frequency corresponding to half the main frequency fl and preferably all secondary signals have a frequency corresponding to half the main
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frequency fl .
The step of combining the secondary signals with each other can be carried out by performing a logic exclusive-OR operation; by giving the suitable dimension to the frequencies and phase displacements of the secondary signals, it is therefore possible to obtain a signal having the same frequency as the main frequency f1.
Shown in Fig. 3 by way of example is the time course of two secondary signals (a) and (b) having a frequency corresponding to half the main frequency fl and suitably out of phase with respect to each other, together with the time course (c) of the signal resulting from the exclusive~OR combination (the last- mentioned signal having the same frequency as the main frequency fl) .
It is to be noted that this second technique for generation of the main signal 10 can be advantageously employed also in a manner independent of the other technical characteristics shown in the present specification such as use of a lower frequency than the main frequency fl for phase demodulation of the auxiliary signal 20, for example.
The method in accordance with the invention further contemplates a step of detecting an auxiliary signal 20, obtained by interaction between the main signal 10 and said space or closed volume.
Practically, upon generation and propagation of the main signal 10, detection of signal 20 occurs which is obtained, through reflection or diffraction for
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example, by the interaction between the main signal 10 and the different surfaces and objects present onboard the vehicle (e.g. seats, dashboard, inner walls- of the doors, etc . ) .
The auxiliary signal 20 is then phase-demodulated preferably in a coherent manner, sampling the same at least at a frequency '' fa, fb lower than the main frequency fl (i.e. the characteristic frequency of the main signal 10) .
Preferably, the sampling frequency ' of the auxiliary signal 20 is a subharmonic of the main frequency fl; in other words, the first frequency fl is a whole multiple of this sampling frequency. Following said sampling, at least one phase-demodulated signal 30, 40 is obtained.
In the preferred embodiment, the phase demodulation is carried out in such a manner as to obtain a first and a second demodulated signals 30, 40. The first demodulated signal 30 is obtained through sampling of the auxiliary signal 20 at a first frequency fa. The second demodulated signal 40 is obtained through sampling of the auxiliary signal 20 at a second frequency fb; the first and second demodulated signals 30, 40 are mutually out of phase by a predetermined phase displacement d different from zero and preferably of 90°. In other words, the first and second demodulated signals 30, 40 are two wattless signals.
It will be recognised that at least one of the first and second frequencies fa, fb is lower than the main frequency f1.
Preferably, at least one of the first and second
T2007/000135
frequencies fa, fb is a subharmonic of the main frequency fl.
In more detail, both the first and second frequencies fa, fb can be subharmonics of the main frequency f1.
For instance, the ratio of the main frequency fl to the first and/or second frequency fa, fb is included between 1 and 10; by way of example, this ratio can be 2.
Advantageously, should the main frequency fl of the main signal 10 be obtained from combination of said secondary signals, at least one of the first and second frequencies fa, fb can be equal to the frequency of one of said secondary signals (example shown in Fig. 2) .
Therefore, it is possible that the same output of the processor designed to control generation of the main signal 10 and analysis of the auxiliary signal 20 is used both to supply one of the secondary signals utilised for generation of the main signal 10, and to demodulate the auxiliary signal 20 and obtain at least one of the first and second demodulated signals 30, 40.
In more detail, the first and second demodulated signals 30, 40 can be obtained through respective first and second sample-and-hold circuits 120, 130 to the input of which the auxiliary signal 20 is placed and which output said demodulated signals 30, 40.
The first sample-and-hold circuit 120 is activated to a frequency equal to the first frequency fa; the second sample-and-hold circuit 130 is activated to a frequency equal to the second frequency fb .
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Preferably, the demodulated signals 30, 40 at the output of the sample-and-hold circuits 120, 130 are suitably filtered before being inputted to a processing, unit 160 carrying out further processing of same.
This filtering operation can be of the band-pass type, the passband being defined between 30 Hz and 500 Hz, and more preferably between 40 Hz and 400 Hz.
At least one first comparison is herein carried out between the first and second demodulated signals 30, 40 and one or more predetermined thresholds si, s2.
Said one or more predetermined thresholds si, s2 are representative of "non-intrusion" conditions of the monitored space.
Preferably the first comparison also comprises a comparison between the phases of the two demodulated signals 30, 40. Depending on said first comparison, an alarm signal 60 is generated, if necessary.
It is to be noted that the predetermined thresholds si, s2 can be both individual values, under or above which the intrusion conditions are defined, and value intervals, at the inside or outside of which said intrusion conditions are defined.
Advantageously, the method in accordance with the invention involves a -combination between said phase demodulation and an amplitude demodulation, above all to make identification of possible intrusions by device 1 more reliable.
It is also to be noted that a combination between a
phase demodulation and an amplitude demodulation is advantageous also irrespective of the sampling frequency used for the phase demodulation; in fact, the fact by itself of carrying out a logic operation of the "AND" type between the result of the verification carried out on the phase-demodulated signal 30, 40 and the result of the verification carried out on the amplitude-demodulated signal 50 allows a much more reliable process to be obtained, in terms of correct distinction between the intrusion conditions and the non-intrusion conditions, in which temperature variations or shocks suffered by the vehicle can give rise to generation of wrong alarm signals.
The auxiliary signal 20 can be therefore amplitude- demodulated as well, thus obtaining a corresponding amplitude-demodulated signal 50.
Then a second comparison is carried out between the amplitude-demodulated signal 50 and at least one respective threshold s3; said alarm signal 60 can be generated also as a function of this second comparison.
The second comparison can be carried out, in a quite equivalent manner, with a single threshold value or with a plurality of values defining one or more intervals .
Advantageously, the alarm signal 60 is generated if both the first and second comparisons give a result stating occurrence of an intrusion in the monitored space .
On the contrary, i.e. if at least one of the two comparisons gives a negative result, the alarm signal
60 is not generated; in this way accuracy and reliability of the method are increased, since the situations in which an intrusion really occurs are distinguished in a more precise manner.
In the preferred embodiment, a preliminary analysis carried out on the amplitude-demodulated signal 50 can be employed to reduce., consumptions of the circuitry implementing the method of the invention.
In fact, the processing unit 160 designed for analysis of the first and second demodulated signals 30, 40 can be normally maintained to a stand-by condition at which no operation is substantially carried out by the same.
Should the amplitude-demodulated signal 50 exceed a pre-set value s4, under which the fact that an intrusion has occurred is very unlike, then the processing unit 160 would be "awoken" and brought to an operating condition at-«which also the phase-demodulated signals 30, 40 are processed and the amplitude- demodulated signal 50 is further analysed to obtain possible confirmation of the preliminarily detected intrusion.
In particular, the processing unit 160 is maintained to the stand-by condition during generation of the main signal 10.
Figs. 1 and 2 show a block diagram of two possible embodiments of a device 1 in accordance with the present invention.
The above described method can be performed through said device 1.
Device 1 comprises a radiation generator 100 to generate the main signal 10 at the first frequency fl. Propagation of the main signal 10 in the predetermined closed volume, such as the driver and passenger compartment of a vehicle, is caused.
The radiation generator 100 may for example comprise an ultrasonic transducer to convert the electric signal at frequency fl to an ultrasonic wave.
It will be recognised that, while a single generator 100 is shown in Fig. 1 by way of example, device 1 can be also equipped with a plurality of generators quite identical with generator 100. In this way the area to be monitored can be covered in a very precise and reliable manner.
By way of example, a car can be taken into account in which two generators are directed to the opposite sides of the vehicle (for instance, if the generators and respective receivers are positioned in the middle of the roof) , so that each of them impinges on one half of the vehicle's driver ^ and passenger compartment with its radiation.
Advantageously, device 1 further comprises an interface 105 interposed between the processing unit 160 and the generator . (or generators) 100. This interface is particularly useful where more than one generator is present, since it ensures the necessary insulation between the different signals sent to the different generators .
Reference is herein again made to what stated in connection with generation of the main frequency fl of
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the main signal 10; this frequency can be directly generated by the processing unit 160 (Fig. 1) or can be obtained by combining at least two secondary signals of lower frequency than the main frequency fl (Fig. 2).
Device 1 also comprises a detector 110 to detect the auxiliary signal 20 obtained by interaction between the main signal 10 and the different elements present in the space to be monitored.
Detector 110 may for instance comprise a transducer to convert the received ultrasonic signal into an electric signal .
It will be recognised that while in Fig. 1 only one detector 110 is shown by way of example, device 1 can be also equipped with a plurality of detectors quite similar to detector 110.
The different detectors can be disposed at different positions relative to each other, so as to detect the reflected radiation emissions having different directions and origins.
In a preferred embodiment, the outputs of the different detectors are added up in an analog manner so that the circuitry connected downstream (to be described in the following) can be suitably "alerted" even if one detector alone receives a radiation that can be representative of an intrusion.
Device 1 also comprises a phase demodulator 120, 130 to phase demodulate the auxiliary signal 20 preferably in a coherent manner, so as to obtain at least one corresponding phase-demodulated signal 30, 40.
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In particular the phase demodulator 120, 130 carries out sampling of the auxiliary signal 20 at a frequency fa, fb that is lower, being preferably a subharmonic, than the main frequency f1. In more detail, the phase demodulator comprises a first and a second sampling modules 121, 131.
The first sampling module 121 carries out sampling, at the first frequency fa, of the auxiliary signal 20 to obtain the first demodulated signal 30. The second sampling module 131 carries out sampling, at the second frequency fb, of the auxiliary signal 20 to obtain the second demodulated signal 40.
The first and second demodulated signals 30, 40 are mutually out of phase by a non-zero phase displacement d. Preferably said phase displacement d corresponds to 90°.
In the preferred embodiment the first sampling module 121 is included in a first sample-and-hold circuit 120 receiving the auxiliary signal 20 as an input and " outputting the first demodulated signal 40.
The first and second sample-and-hold circuits 120, 130 are operated at the first and second frequencies fa, fb respectively, so that the respective demodulated signals 30, 40 have the desired frequency and phase relation.
Advantageously, should the main frequency fl of the main signal 10 be obtained by combining said secondary signals, at least one of the first and second frequencies fa, fb can be equal to the frequency of one of said secondary signals.
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Therefore, one same output of the processing unit 160 can be used both to supply one of the secondary signals used for generation of the main signal 10, and to supply the respective sampling frequency fa, fb to the first and/or the second sample-and-hold circuits 120, 130, so as to demodulate the auxiliary signal 20 and obtain at least one of the first and second demodulated signals 30, 40.
Preferably device 1 is further provided with at least one filter 125 to filter the first demodulated signal. 30 before the same is inputted to the processing unit 160.
The first filter 125 can be a band-pass filter the passband of which is defined between 30 Hz and 500 Hz, and in particular between 40 Hz and 400 Hz.
Preferably device 1 is also provided with a second filter 135 to filter the second demodulated signal 40 before the same is inputted to the processing unit 160.
The second filter 135 can be a band-pass filter the passband of which is defined between 30 Hz and 500 Hz and in particular between 40 Hz and 400 Hz.
As mentioned above, the processing unit 160 is designed to carry out at least one comparison between the two wattless components 120, 130 and respective pre-stored thresholds si, s2.
Depending on this comparison, the alarm signal 60 can be generated.
Advantageously, device 1 also comprises an amplitude
demodulator 140, to amplitude-demodulate the auxiliary signal 20 so as to obtain a corresponding amplitude- demodulated signal 50.
Preferably device 1 is further provided with a third filter 145, to filter the amplitude-demodulated signal 50 before the same is inputted to the processing unit 160.
The third filter 145 can be a band-pass filter the passband of which is defined between 10 Hz and 500 Hz, and in particular between 40 Hz and 400 Hz.
The processing unit 160 is therefore operatively associated with the amplitude demodulator 140 to carry out a second comparison between the amplitude- demodulated signal 50 and at least one respective threshold s3.
The alarm signal 60 can therefore be generated also as a function of the second comparison. In other words, as above said, if both the first and second comparisons give confirmation of an occurred intrusion, then the alarm signal 60 is generated.
Preferably, the processing unit 160 is maintained to a stand-by condition when its intervention is not required. This stand-by condition is maintained both during generation and propagation of the main signal 10 and during reception of the auxiliary signal 20, until the amplitude-demodulated signal 50 overcomes a pre- stored threshold s4.
In this case, the processing unit 160 is brought to an operating condition to process the demodulated signals
30, 40, 50 and verify whether an intrusion has really occurred.
To compare the amplitude-demodulated signal 50 with said pre-stored threshold s4, device 1 is provided with an auxiliary comparison module, denoted at 150 in Fig. 1.
This auxiliary comparison module 150 can for instance be of the analog type; in this case, the pre-stored threshold can be defined by a pre-set reference voltage value.
The invention achieves important advantages.
First of all, the method and device of the invention allow power consumptions to be minimised since the processing unit is only activated when required, and operation of same takes place at reduced frequencies (i.e. speeds) as compared with systems of known type.
Another advantage resides in that, by virtue of use of different frequencies for the main signal and the signals utilised for phase demodulation, the risk of cross-talks between the different signals processed is greatly reduced and in particular the risk of crosstalks between these signals and the signal received at frequency fl that generally is of a very low intensity.