RU2595979C1 - Method of detecting intruder using ultra-wideband signal (versions) - Google Patents

Abstract

FIELD: safety systems.

SUBSTANCE: invention relates to burglar alarm systems, particularly to radio engineering methods of detecting an intruder using ultra-wideband signals. Technical result is achieved by that when receiving a pulsed ultra-wideband signal, constant component of detected signal is identified, corresponding to presence and level of external narrowband noise, exceeding of a threshold value by which bandwidth of receiving channel is adjusted in frequency domain, where there is no noise. In other versions of method, used for detecting an intruder of several frequency channels, in each channel is identified a constant component of detected signal corresponding to presence and level of external narrowband noise, and exceeding of threshold value by which channel, subjected to noise, is excluded from operation.

EFFECT: higher resistance to effect of narrow-band electromagnetic interference, including in working frequency band, and ensuring operability of method of detecting an intruder under said interference.

3 cl, 11 dwg

Description

The invention relates to the field of burglar alarms, in particular to radio-technical methods for detecting intruders intruding into a controlled area of space, and specifically to radio-technical methods for detecting using ultra-wideband (UWB) signals.

Radio engineering detection methods are based on fixing the electromagnetic field reflected from the detected object (intruder) when it appears in the controlled area [Tokarev N.N. Disturbing reflections in radio wave detection equipment. // "Infocommunication technologies." Volume 6. Special issue of "Security and Protection Technologies", 2008, p. 85]. To ensure the operability of radio detection means (CO) in the presence of interference from vegetation (tall grass, shrubs, in wooded areas) and a wide range of changes in weather conditions and natural factors (rain, wet snow, ice, etc.), they are used sounding signals of the ranges of meter and decimeter waves [Tokarev N.N. Improving the characteristics of radio wave detection methods using methods of broadband sounding. // Modern security technologies and means to ensure integrated security of facilities: materials of the IX All-Russian Scientific and Practical Conference (Russia, Penza - Zarechny, September 18-20, 2012). - Penza: Publishing House of vocational schools, 2012, p. 122]. However, in these ranges with acceptable dimensions of the antennas, their radiation pattern does not limit the sensitivity zone, and CO is subject to the influence of interfering reflections from moving massive bodies located even at a considerable distance (tree crowns, moving vehicles, etc.) [N. Tokarev . Disturbing reflections in radio wave detection equipment. // "Infocommunication technologies." Volume 6. Special issue of "Security and Protection Technologies", 2008, p. 86; Tokarev N.N. Improving the characteristics of radio wave detection methods using methods of broadband sounding. // Modern security technologies and means to ensure integrated security of facilities: materials of the IX All-Russian Scientific and Practical Conference (Russia, Penza - Zarechny, September 18-20, 2012). - Penza: Publishing House of vocational schools, 2012, p. 123]. In addition, in the meter range CO, intended for covert placement in the ground, the signal level is strongly influenced by changes in the parameters of the earth in a wide range (from dry to wet, up to the flooding of the antennas by rain and meltwater) [Tokarev N.N. Improving the characteristics of radio wave detection methods using methods of broadband sounding. // Modern security technologies and means to ensure integrated security of facilities: materials of the IX All-Russian Scientific and Practical Conference (Russia, Penza - Zarechny, September 18-20, 2012). - Penza: Publishing House of vocational schools, 2012, p. 123; Tokarev N.N. Simulation of the direct signal of radio wave detection means with underground antennas. // Radio engineering. No. 2. 2013, p. 101].

(

- абсолютная ширина спектра,

- средняя частота спектра) [Токарев Н.Н. Повышение характеристик радиоволновых средств обнаружения методами широкополосного зондирования. // Современные охранные технологии и средства обеспечения комплексной безопасности объектов: материалы IX Всероссийской научно-практической конференции (Россия, Пенза - Заречный, 18-20 сентября 2012 г.). - Пенза: Изд-во ПТУ, 2012, с. 122; Шахнович И.В. Современные технологии беспроводной связи. М.: Техносфера, 2006, с. 138]. Для расширения условий работоспособности СО с подземными антеннами также используются СШП зондирующие сигналы, позволяющие сохранить оптимальность антенн и достаточный уровень сигнала в широком диапазоне изменения параметров земли [Токарев Н.Н. Повышение характеристик радиоволновых средств обнаружения методами широкополосного зондирования. // Современные охранные технологии и средства обеспечения комплексной безопасности объектов: материалы IX Всероссийской научно-практической конференции (Россия, Пенза - Заречный, 18-20 сентября 2012 г.). - Пенза: Изд-во ПТУ, 2012, с. 125; Способ скрытного обнаружения нарушителя в контролируемой зоне. Патент №2480837, Россия, МПК G08B 13/24. Заявлено 16.06.2011 г. №2011124585/08. Опубликовано 27.04.2013. Бюл. №12]. Для сохранения оптимальности антенн в диапазоне изменения параметров земли от сухой до мокрой требуется ширина спектра зондирующего сигнала в несколько десятков мегагерц при средней частоте спектра также в несколько десятков мегагерц [Способ скрытного обнаружения нарушителя в контролируемой зоне. Патент №2480837, Россия, МПК G08B 13/24. Заявлено 16.06.2011 г. №2011124585/08. Опубликовано 27.04.2013. Бюл. №12, фиг. 3]. Такой сигнал относится к классу СШП сигналов

.To limit and standardize the sizes of the CO sensitivity zone when using omnidirectional and weakly directional antennas, they use pulsed UWB probing signals of short duration with a relative spectrum width

(

- absolute width of the spectrum,

- the average frequency of the spectrum) [Tokarev N.N. Improving the characteristics of radio wave detection methods using methods of broadband sounding. // Modern security technologies and means to ensure integrated security of facilities: materials of the IX All-Russian Scientific and Practical Conference (Russia, Penza - Zarechny, September 18-20, 2012). - Penza: Publishing House of vocational schools, 2012, p. 122; Shakhnovich I.V. Modern wireless technology. M .: Technosphere, 2006, p. 138]. To expand the working conditions of CO with underground antennas, UWB probing signals are also used to preserve the optimality of the antennas and a sufficient signal level in a wide range of changes in ground parameters [N. Tokarev Improving the characteristics of radio wave detection methods using methods of broadband sounding. // Modern security technologies and means to ensure integrated security of facilities: materials of the IX All-Russian Scientific and Practical Conference (Russia, Penza - Zarechny, September 18-20, 2012). - Penza: Publishing House of vocational schools, 2012, p. 125; The method of covert detection of an intruder in a controlled area. Patent No. 2480837, Russia, IPC G08B 13/24. Declared June 16, 2011 No. 2011124585/08. Published on April 27th, 2013. Bull. No. 12]. To maintain the optimality of the antennas in the range of changes in the parameters of the earth from dry to wet, the spectrum width of the probing signal of several tens of megahertz is required with an average frequency of the spectrum also of several tens of megahertz [Method for covert detection of an intruder in a controlled area. Patent No. 2480837, Russia, IPC G08B 13/24. Declared June 16, 2011 No. 2011124585/08. Published on April 27th, 2013. Bull. No. 12, FIG. 3]. Such a signal belongs to the class of UWB signals

.

The problem when using UWB signals is the effect of narrow-band electromagnetic interference falling into the passband of the CO receiving path. With a wide bandwidth, the likelihood of such an effect is quite high, so its elimination is a very urgent task.

One of the ways to protect against such interference is frequency rejection, which allows you to cut out the interference frequency band from the UWB signal spectrum [Immoreev I.Ya. Ultrawideband radars: new features, unusual problems, system features. // Bulletin of MSTU. Ser. Instrument making. 1998. No. 4, p. 37; Huaxia Peng, Yufeng Luo, Eugging Jao. Compact filter for ultra-wideband systems. // Electronic components. No. 11. 2014, p. 12]. However, this path is applicable when the frequency and level of interference are known in advance, and this is rare, and interference at another frequency may appear.

A radio-technical method for detecting an intruder using a pulsed probe signal with a large relative spectral width, which uses a different protection path from narrow-band electromagnetic interference, is described in the patent [Method for detecting an intruder in a controlled area. Patent No. 2455692, Russia, IPC G08B 13/24. Declared December 15, 2010 No.20151591 / 08. Published on July 10, 2012. Bull. No. 19]. It is the closest to the claimed method according to the composition of the essential features.

, и этот сигнал относится к классу СШП сигналов.This method consists in the fact that the controlled area is irradiated with a pulsed radio signal, when receiving a pulsed radio signal, changes in its amplitude are distinguished, and when these changes exceed a threshold value, an alarm is generated, while the duration of the irradiating pulsed radio signal and the transmission and transmission paths are chosen such that the duration of the received radio signal did not exceed the delay time of the signal reflected from the intruder located on the border of the controlled area, relatively direct about the signal received with a minimum delay. The delay of the reflected signal relative to the direct signal with the width of the controlled zone of several meters does not exceed 10 ns [Method for detecting an intruder in the controlled zone. Patent No. 2455692, Russia, IPC G08B 13/24. Declared December 15, 2010 No.20151591 / 08. Published on July 10, 2012. Bull. No. 19, FIG. 3], which corresponds to the bandwidth of the transmission and reception paths and the spectrum width of the pulsed probe signal of at least 200 MHz. To work in vegetation, the operating frequencies of CO should be no higher than 1 GHz. With an average frequency of the spectrum from 300 to 800 MHz, the relative width of the signal spectrum

, and this signal belongs to the class of UWB signals.

This method provides that during reception, additional radio signals in other frequency bands are allocated relative to the frequency band of the first radio signal, and an alarm signal is generated when changes in the amplitude of all radio signals exceed threshold values [Method for detecting an intruder in a controlled area. Patent No. 2455692, Russia, IPC G08B 13/24. Declared December 15, 2010 No.20151591 / 08. Published on July 10, 2012. Bull. No. 19, paragraph 5 of the formula]. Improving the resistance to narrowband electromagnetic interference is achieved due to the fact that the probability of simultaneous interference in all frequency channels is very small, and the probability of an alarm when exposed to interference is also very small.

The disadvantage of this detection method is the ability to skip the intruder when exposed to narrowband electromagnetic interference on at least one of the reception channels. With a sufficient level of interference and its sufficient duration, it can suppress the received pulse signal in the channel, then when the intruder appears, there will be no increase in the amplitude of the pulse signal in this channel, and the alarm signal will not be generated, which corresponds to the skip of the intruder and loss of operability.

The objective of the claimed invention is to provide a method for detecting an intruder using a UWB signal that is operable when exposed to narrow-band electromagnetic interference, including in the frequency band of the UWB signal.

To solve this problem, the claimed invention detects the fact of the presence of interference and suppresses (excludes) its action regardless of frequency.

The problem is solved by various variants of the method. In all cases, the detection of the fact of the presence of interference is carried out by the same set of operations (actions), and the suppression or exclusion of the action of interference on the operability of the method is carried out in various ways. Accordingly, in variants of the method, various not only distinctive, but also distinguishing features are used. Therefore, the prototype of the first variant of the method is the main claim of the patent [Method for detecting an intruder in a controlled area. Patent No. 2455692, Russia, IPC G08B 13/24. Declared December 15, 2010 No.20151591 / 08. Published on July 10, 2012. Bull. No. 19], and the prototype of the remaining options is the same prototype, taking into account paragraph 5 of the formula.

In the first method, when an interference is detected, the working frequency band is tuned into the frequency domain not affected by the interference.

To do this, in the method for detecting an intruder using UWB signal, namely, that the controlled area is irradiated with a pulse UWB radio signal, when receiving a pulse UWB radio signal, changes in its amplitude are distinguished, when these changes exceed the threshold level of the signal, the main alarm signal is generated, according to the claimed invention, the spectral width the irradiating radio signal is selected greater than the bandwidth of the received radio signal; when detecting the received pulsed radio signal, select the constant component of the detected signal, corresponding to the presence and level of extraneous narrow-band interference, when this constant component exceeds a predetermined threshold level of interference, the frequency band of the received radio signal within the spectrum of the irradiating radio signal is shifted to a decrease in the constant component of the detected signal below the threshold level of interference, when the constant component of the detected threshold signal is exceeded the level of interference in the entire range of tuning the frequency band received signal forming an additional alarm to indicate the electromagnetic suppression.

In the second method, several operating frequency bands (several detection channels) are used, and if there is interference in one of the channels, this channel is excluded from operation.

To do this, in the method for detecting an intruder using an ultra-wideband (UWB) signal, namely, that the controlled area is irradiated with a pulsed UWB radio signal, when receiving a pulsed UWB radio signal, n reception channels are allocated in n frequency bands within the total spectral width of the UWB radio signal, and the amplitude changes pulse radio signal in the receiving channels and when these changes exceed the threshold level of the signal form the main alarm signal, according to the claimed invention when receiving and detecting The envelope of the received pulsed radio signal in each of the n frequency channels controls the appearance and level of the DC component of the detected signal, corresponding to the presence of extraneous narrow-band interference, when this level exceeds the specified threshold level of interference in the ith reception channel (i≤n) for the time this channel is exceeded disconnect from the formation of the main alarm, when the level of the DC component of the detected signal exceeds a predetermined threshold level of interference in several or all n ka Alah form an additional alarm to indicate the electromagnetic suppression.

The third method differs from the second in that the signals of the individual frequency channels are added up, and the intruder is detected by changes in the total signal. This allows full use of the UWB signal frequency band.

To do this, in the method of detecting an intruder using an ultra-wideband (UWB) signal, namely, that the controlled area is irradiated with a pulsed UWB radio signal, when receiving a pulsed UWB radio signal, n reception channels are allocated in n frequency bands within the total spectral width of the UWB radio signal, in each channel emit a signal corresponding to the amplitude of the received pulsed radio signal, according to the claimed invention, these signals are summed when exceeding the changes in the total signal threshold level with the signals generate the main alarm, when receiving and detecting the envelope of the received pulsed radio signal in each of the n frequency channels, the appearance and level of the constant component of the detected signal corresponding to the presence of extraneous narrow-band interference is controlled when this level exceeds a predetermined threshold level of interference in the ith reception channel ( i≤n) for the time of exceeding, this channel is excluded from the summed, when the level of the constant component of the detected signal exceeds the specified threshold level p Fires in several or all n channels generate an additional alarm signaling electromagnetic suppression.

All three methods of detecting an intruder solve the same problem using similar main distinguishing features - detecting the fact of interference and eliminating the influence of this interference on the detection of an intruder. But in order to exclude the influence of interference, the first method uses the tuning of the frequency band of a single detection channel, and the second and third methods exclude one of several channels subject to interference. The lack of a complete set of features of one of the methods that are completely repeated in other methods does not allow us to formulate one of them as an additional point of the other. At the same time, all methods are interconnected by a single goal and the technical result achieved, therefore they are combined in a single application for variants of a method for detecting an intruder using a UWB signal.

The technical result obtained in the claimed invention is to ensure the operability of a method for detecting an intruder using UWB signal when exposed to narrow-band electromagnetic interference. An additional result is the possibility of generating a message on the effect of electromagnetic interference and separation of the alarm signal caused by the detection of the intruder and the alarm signal caused by electromagnetic suppression in the entire operating frequency band used, i.e. Get more information about the cause of the alarm.

The technical result obtained is most relevant for the meter and decimeter wave ranges, when non-directional and weakly directional antennas are most susceptible to electromagnetic interference, since they do not limit the angular directions of their arrival. In addition, in these ranges the largest number of unlicensed and random sources of radiation.

At the same time, the traditional field of UWB applications is focused on higher frequency ranges where frequency bands of units of gigahertz can be obtained. In these ranges, as a rule, the frequencies of narrow-band sources of extraneous radiation are known in advance and can be suppressed by obstruction filters [Immoreev I.Ya. Ultrawideband radars: new features, unusual problems, system features. // Bulletin of MSTU. Ser. Instrument making. 1998. No. 4, p. 37; Huaxia Peng, Yufeng Luo, Eugging Jao. Compact filter for ultra-wideband systems. // Electronic components. No. 11. 2014, p. 12], therefore, the problem of the influence of electromagnetic interference is not so relevant. Probably, for this reason, and also because of the comparative novelty of UWB technologies and the insufficient practice of their implementation, the ways to solve the problem of the effect of electromagnetic interference devices with an unknown frequency on the UWB are poorly developed and practically not reflected in the information sources. The invention is one of the first methods for detecting an intruder using UWB signal, in which the problem of suppressing extraneous electromagnetic interference in the working frequency band is solved.

The inventive method for detecting an intruder using UWB signal is illustrated by the drawings shown in FIG. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11.

FIG. 1 illustrates the operation of intruder detection methods using UWB signal in the absence of interference.

FIG. 2 illustrates the principle of suppressing narrowband interference in the first way.

FIG. 3 illustrates the principle of detecting narrowband interference.

In FIG. 4 shows diagrams of two variants of the device (a, b) that implements the first detection method.

FIG. 5 illustrates the principle of suppressing narrowband interference in a second way.

In FIG. Figure 6 shows the spectrogram of (a) a real irradiating pulse UWB signal and frequency characteristics (b) of real bandpass filters in n (n = 4) reception channels.

In FIG. 7 shows a diagram of one of the possible devices (a) for implementing the second method of detecting an intruder and a timing diagram (b) of the main signals of the device.

FIG. 8 shows timing diagrams of the summed and summed signals in the third detection method.

In FIG. 9, 10 and 11 show examples of implementation of the device elements: sampling-storage circuit with a reset (Fig. 9), a gated peak detector with a reset (Fig. 10) and a controlled band-pass filter (Fig. 11).

In the claimed method, as well as in the prototype method, a pulse UWB signal is used to irradiate the controlled zone from a few nanoseconds to tens of nanoseconds with a spectrum width of up to several hundred megahertz. This ensures the limitation of the width of the monitored zone (sensitivity zone) between the transmitter (Rx) and the receiver (Rx) located at opposite ends of the monitored zone [Method for detecting an intruder in the monitored zone. Patent No. 2455692, Russia, IPC G08B 13/24. Declared December 15, 2010 No.20151591 / 08. Published on July 10, 2012. Bull. No. 19]. This ensures the limitation and normalization of the sensitivity zone and resistance to interference from the movement of massive distant objects.

In FIG. 1a shows a pulsed radio signal 1, which is emitted during reception, as well as its envelope 2. The duration of the received signal, depending on the bandwidth of the reception channel, is from units to tens of nanoseconds. When receiving, a signal 3 corresponding to the amplitude of the received pulse radio signal 1 is also isolated. When the intruder crosses the controlled zone (sensitivity zone), the signal level 3 changes, as shown in FIG. 1 b When changes in signal level 3 exceed threshold level 4 of the signal, the main alarm 5 is generated.

In FIG. 2a shows the spectrum 6 of the probing (irradiating) signal, FIG. 2, b - spectrum 7 of the received signal. Spectrum 6 of the probing signal is much wider than spectrum 7 of the received signal. In the first detection method, only part of the spectrum 6 of the probing signal is used, however, the width of the spectrum 7 of the received signal should be sufficient to form a sensitivity zone of a given width. The appearance of narrowband interference with spectrum 8 (see Fig. 2, a) within the frequency band 7 of the received signal can completely suppress the received signal. To eliminate the influence of interference, the spectrum of the signal 7 is shifted within the spectrum 6 of the probing signal to position 9 (see Fig. 2, b), as shown by the dashed arrow.

As narrowband interference is detected, FIG. 3. It shows the same received pulse signal 1 with envelope 2 as in FIG. 1a, but with superimposed narrow-band interference 10, which is a continuous harmonic process. When receiving by detection, the envelope 2 of the pulse signal 1 is emitted together with the envelope 11 of the narrow-band interference 10. The envelope 11 of the interference 10 has a constant or slowly (due to narrow-band) changing level corresponding to the level of interference. At a certain threshold interference level shown in FIG. 3 by dashed line 12, the interference starts to suppress pulse signal 2 and can suppress it completely. Therefore, when the interference level 11 exceeds this threshold level 12, the frequency band of the received signal (the average frequency of the input PFP filter) is shifted, as shown in FIG. 2b, to reduce the level of interference below the threshold level.

The implementation of the described method for detecting an intruder can be carried out in various ways, for example, by parallel inclusion in the PFP line of switchable filters, with analog processing of signal levels and noise, or by converting them into digital form and digital processing.

In FIG. 4a, a diagram of one embodiment of a device implementing the first detection method is shown. The device contains a PRD 13 with an antenna irradiating the controlled area, and an Rx including a receiving antenna with a bandpass filter 14, tunable in frequency control voltage, a broadband amplifier 15, an amplitude detector 16 of the envelope of the received pulsed radio signal. The signal from the output of the amplitude detector 16 is divided into two channels - signal and interference.

In the signal channel, as is usual in detection devices, a signal corresponding to the amplitude of the envelope of the pulse signal is extracted using a peak detector 17. This signal changes when the intruder crosses the controlled zone (sensitivity zone). The low-pass bandpass filter 18 detects changes in the signal level in a certain frequency range caused by the movement of the intruder in a certain range of speeds. The output signal of the band-pass filter 18 corresponds to signal 3 (see Fig. 1, b), it enters the first threshold circuit 19, where it is compared with the threshold level 4 of the signal (see Fig. 1, b). When this level is exceeded, the alarm driver 20 generates the main alarm 5 (see Fig. 1, b).

The interference channel contains a low-pass filter (LPF) 21, which forms an interference level 11, smoothing a short pulse signal 2 (see Fig. 3). In the absence of interference, this level is absent or very small (PFP intrinsic noises). In the second threshold circuit 22, this level is compared with the threshold level 12 (see Fig. 3) interference. When this level is exceeded, the pulse generator 23 starts and starts counting the pulse counter 24. The outputs of the pulse counter 24 are connected to a digital-to-analog converter (DAC) 25, which generates a control voltage for tuning the frequency of the band-pass filter 14. The range of variation of the output voltage of the DAC 25 is chosen so that the range tuning of the band-pass filter 14 was in the frequency band 6 (see Fig. 2, a) of the emitted signal Rx 13. When the threshold level of interference is exceeded, the control voltage of the band-pass filter 14 it changes until its frequency band extends beyond the limits of the interference (from position 7 to position 9 in Fig. 3, b) and the interference level 11 (see Fig. 3) from the output of the low-pass filter 21 falls below the threshold interference level 12 (see Fig. 3) of the second threshold circuit 22. The pulse generator 23 stops generating pulses, the counter 24 stops in the state in which the output voltage of the DAC 25 brought the bandpass filter 14 beyond the limits of the interference. The device continues to work and detect the intruder in the new frequency band. In the event of interference in this new frequency band, the frequency tuning process is repeated and a new position of the working frequency band is found where there is no interference. In the event that interference is present in the entire tuning range of the bandpass filter, the output of the second threshold circuit 22 constantly receives a signal that the threshold level of interference is exceeded, the pulse generator 23 and the counter 24 with the DAC 25 constantly rebuild the bandpass filter 14 in range until the interference disappears into some kind of frequency band. If a frequency band without interference is not found within a specified time, a duration selector 26 provides a signal to the alarm driver 20 and the suppressor (additional alarm) driver 27, which alerts you to electromagnetic suppression of the operating frequency band.

The same device can be implemented according to the circuit shown in FIG. 4, b. It contains the same functional units 13-17, 21 as the previous one, but the processing in the signal channel, in the interference channel, the frequency control of the bandpass filter 14 is carried out by the microcontroller 28. The functions performed by the microcontroller 28 are the same as those described above for the previous one device options. Its inputs “Signal” and “Interference” are the inputs of the signal channel and the interference channel, respectively, the output “Frequency” is the output of the frequency control of the bandpass filter 14. The microcontroller 28 also has outputs “Alarm”, “Suppression” for issuing the corresponding signals, and “Interface” circuit for remote control of the device (setting thresholds, forced installation and manual frequency adjustment, etc.) and outputting information about the device status and its modes, current signals of the intruder's passage, etc.

The principle underlying the second detection method is illustrated in FIG. 5. It shows the spectrum of 6 probing (irradiating) signal and n frequency bands of 29 reception channels. When narrow-band interference 8 appears in any frequency channel, this channel is excluded from operation (the frequency channel with interference 8 is shown by hatching). In FIG. Fig. 6 shows the real spectrum 6 of the probing (irradiating) signal (Fig. 6, a) and the frequency characteristics of 29 bandpass filters of the frequency channels at n = 4 (Fig. 6, b). The principle of detecting the presence of interference in each frequency channel is the same as described above and explained in FIG. 3.

The essence of the detection method will be clearer when describing a specific device that implements this method. Such a device can also be performed in various ways. For example, its PFP can contain n parallel bandpass filters with frequency characteristics 29 and n parallel channels similar to the device described above for implementing the first method. However, it is more economical to execute it in the form of one common hardware channel with sequential processing of n frequency channels.

A diagram of such a device is shown in FIG. 7a, a in FIG. 7b shows time diagrams of the main signals of the device. The device contains the same as in FIG. 4, PRD 13, frequency tunable band-pass filter 14, broadband amplifier 15, amplitude detector 16 of the envelope of the received pulsed radio signal. The PRM also includes a gated peak detector 30 in the signal channel, a sampling-storage circuit 31 in the interference channel, and a microcontroller 32. The signal timing diagrams in FIG. 7b are numbered, and their numbers are shown in circles in the diagram of FIG. 7, and in the places corresponding to the belonging of these signals to the circuit elements. In FIG. 7 are marked: 33 - the output signal of the controlled band-pass filter 14, 34 - the frequency control signal of the band-pass filter 14 from the "Frequency" output of the microcontroller 32, 35 - the signal from the output of the amplitude detector 16 of the envelope of the received signal, 36 - the strobe of control of the interference sampling-storage circuit 31 from the output of "Strobe P" of the microcontroller 32, 37 - a strobe pulse controlling the gated peak detector 30; from the output of "Strobe C" of the microcontroller 32, 38 - a signal of zeroing (reset) of the sampling-storage circuit 31 and a gated peak detector 30 from the output "Reset" ikrokontrollera 32, 39 - signal output from the sample-and-hold circuit 31 (noise level) at the input "noise" of the microcontroller 32, 40 - signal output from the gated peak detector 30 (signal level) at the input "signal" the microcontroller 32.

The operation of the device is controlled by a microcontroller 32, which at the right time starts the PRD 13 and generates control signals for the elements of the device. The PRD 13 emits short radio pulse signals with a wide spectrum of 6, these signals are received by the PRM and are allocated in the bandpass filter 14 as a sequence of radio pulses 33. The microcontroller 32 periodically with a period T changes the frequency of the bandpass filter 14 using the control signal 34. FIG. 7b, two periods of operation of the device are distinguished: from t ₁ to t ₁ + T in the absence of interference, and from t ₁ + T to t ₁ + 2T in the presence of narrow-band interference. Charts 33 and 34 show that in the first of these periods, at the corresponding tuning frequency of the band-pass filter 14, the received pulse signal 1 is allocated at its output without interference. In the second period, the tuning frequency of the band-pass filter 14 is such that a narrow-band noise gets into the filter passband, and a continuous harmonic noise 10 is superimposed on the output of the band-pass filter 14 on the received pulse signal 1. Diagram 35 shows that after detecting the received signals 33 at the output of the amplitude detector 16 of the envelope there are envelopes 2 of the received pulse signal, and in the second period, the envelope 2 is partially suppressed by the constant component of the detected signal, respectively uyuschey level 11 noise.

The microcontroller 32 in each period of operation corresponding to a certain frequency of the bandpass filter 14, generates a strobe 36 noise and a strobe 37 of the signal. These strobe pulses control the sampling and storage circuit 31 and the gated peak detector 30, which are stored and stored until the reset pulses 38, respectively, the noise level 11 (see diagram 39) and signal level 3 (see diagram 40), corresponding to the amplitude value of the envelope 2 pulsed signals (see diagram 35). The noise and signal levels in each period corresponding to a certain frequency of the band-pass filter are supplied to the microcontroller 32, where they are averaged (filtered) and compared with the corresponding threshold levels of interference 12 and signal 4 (see Fig. 1).

Changes in signal level 3 at the intersection of the sensitivity zone by the intruder in different frequency channels have the same shape and somewhat different time scale due to the different transverse size of the Fresnel zones at different frequencies. When crossing the area near the Rx-Rx line (first Fresnel zone), signal level 3 has a deep minimum at all frequencies of the range, as shown in FIG. 8. When changes in the signal level exceed the threshold level of signal 4 in all or several (when implementing the detection algorithm k of n) frequency channels (periods corresponding to certain frequencies of the band-pass filter), the microcontroller 32 generates the main alarm signal at the “Alarm” output.

If the interference level exceeds the threshold level of interference in a given frequency channel, the microcontroller 32 disconnects this channel from operation so that it does not participate in the formation of an alarm. The interference level 11 can be so large that it completely suppresses the envelope of pulse signal 2 (see diagram 35). This will not interfere with the operation of the device, since the channel suppressed by interference will be disconnected from operation. Due to the overlapping frequency characteristics of the band-pass filter 14 in different frequency channels (see Fig. 5), interference can appear simultaneously in adjacent channels, then both of them will be turned off, but the device will remain operational while at least one noisy channel remains. If the interference is present in all frequency channels, or in several (when implementing the function of maintaining health m from n), the microcontroller 32 generates an additional alarm at the output "Suppression", corresponding to the electromagnetic suppression of the device. The functioning algorithm of the microcontroller 32 is laid in its program.

As in the circuit of FIG. 4, the microcontroller 32 has an “Interface” output for remote control of the device and control of its operation modes.

A third method for detecting an intruder using UWB signal is illustrated by timing diagrams of the change in signal level in the frequency channels shown in FIG. 8. It differs from the second method in that the signal levels of different frequency channels are added up, and a total signal is used to detect the intruder. In FIG. Figure 8 shows the changes in signal level 3 in different frequency channels (channel 1 - channel n) and changes in the total signal 41. When changes in the total signal 41 exceed the threshold level of signal 4, the main alarm 5 is generated.

A feature of this method is that due to the summation of different-phase changes in the signal level of 3 frequency channels in the region of the higher Fresnel zones (lateral oscillations of the signals) in the total signal, these lateral oscillations are greatly weakened, almost absent. This is due to the summation of frequency bands, i.e. with the extension of the total frequency band relative to the frequency band of one channel, and provides an additional restriction on the transverse size of the sensitivity zone and, accordingly, additional resistance to the movement of massive bodies outside the sensitivity zone.

The detection of interference in each frequency channel is carried out in the same way as in the previous methods. The method can be implemented by the same device (see Fig. 7) as the second method. Timing diagrams of the device signals are the same as in the second detection method. The difference lies in the fact that the signals of the frequency channels in the microcontroller 32 are summed up, and the main alarm signal is generated when the threshold signal is exceeded by the sum signal, if interference is detected in any frequency channel (when the interference level 11 exceeds the threshold interference level 12), this frequency channel is excluded from summable. If interference is detected in all frequency channels at the “Suppression" output of the microcontroller 32, an additional alarm signal is generated corresponding to the electromagnetic suppression of the device. The specified algorithm is laid down in the program of operation of the microcontroller 32.

In FIG. 9, 10, 11 show examples of the implementation of elements that perform the functions of generating levels of interference and signal and the frequency tuning function in the device shown in FIG. 7 a.

The retrieval-storage circuit 31 shown in FIG. 9, contains a charging key 42, a storage capacitor 43, a discharge key 44, and a voltage follower 45. A detected signal 35 is supplied to the input of the circuit. At the moment the control signal 36 "Strobe P" arrives from the microcontroller 32, the charging key 42 opens and the storage capacitor 43 is charged to the level of the DC component of the detected signal 35 (shaded areas on the signal 35, Fig. 7, b), which in each frequency change period T corresponds to the level of interference superimposed on the useful pulse signal. The accumulated voltage 39 of the capacitor 43 through the voltage follower 45 is supplied to the microcontroller 32 (input "Interference"), where it is digitized and compared with a predetermined threshold level. At the end of each period of changing the frequency of the bandpass filter, the storage capacitor 43 is discharged with a bit key 44, to which a “Reset” signal 38 is supplied from the microcontroller 32. Thus, the sample-storage scheme is prepared for the next period of frequency change.

The gated peak detector 30 of FIG. 10 contains the same elements 42, 43, 44, 45, but the signal 37 "Strobe C" is used to control the key 42, and to store the voltage corresponding to the amplitude of the useful pulse signal on the capacitor 43, the storage capacitor 43 is charged through a transistor 46. The accumulated voltage 40 is supplied through a voltage follower 45 to the microcontroller 32 (to the “Signal” input), where it is digitized and compared with a threshold level or summed with signals from other frequency channels, depending on the version of the detection method being implemented. The voltage drop across the capacitor 43 before the start of the next frequency change period is carried out by the same signal 38 "Reset".

The frequency change of the bandpass filter is carried out by the microcontroller 32 by changing the control voltage 34 at the output of the "Frequency". In FIG. 11 shows an example implementation of a controlled band-pass filter 14. The filter is made according to a five-link scheme using coupled strip lines 47 and varicaps 48 that perform the functions of controlled capacitors. Varicaps with cathode leads are grounded by a high-frequency signal with capacitors 49 and combined to supply a control voltage at the “Frequency” input. With a change in the control voltage, the capacitance of the varicaps and the filter tuning frequency change. The filter bandwidth is determined by the parameters of the strip lines 47. The frequency characteristics of the filter during voltage tuning are shown in FIG. 6 b

In the process of tuning the frequency of the channels, the microcontroller 32 stores the digitized levels of interference and signal in each period corresponding to a particular frequency channel, accumulates them, averages and processes them according to the algorithms described above.

The microcontroller has outputs “Alarm” for supplying an alarm signal to actuators and “Suppression” for supplying information about the cause of the alarm signal. In addition, it has an “Interface” output circuit for two-way communication with external devices. A remote control is carried out along this chain — changing threshold levels, a multi-channel processing algorithm (for example, setting the k, m values when generating an alarm signal and an operation suppression signal), and if necessary, changing the channel tuning frequencies. This circuit also provides additional information to external devices - channel tuning frequencies, channel numbers that are subject to interference and are turned off, set threshold levels, etc.

The ability to control the multi-channel processing algorithm and the operating frequencies of the channels is an additional technical result achieved in the claimed methods for detecting an intruder using a UWB signal.

Claims (3)

1. The method of detecting an intruder using an ultra-wideband (UWB) signal, which consists in the fact that the controlled area is irradiated with a pulse UWB radio signal, when a pulse UWB radio signal is received, changes in its amplitude are distinguished, when these changes exceed the threshold signal level, they form the main alarm signal, characterized in that that the width of the spectrum of the irradiating radio signal is chosen greater than the bandwidth of the received radio signal, when detecting the received pulsed radio signal, select the constant component of the detected signal, corresponding to the presence and level of extraneous narrow-band interference, when this constant component exceeds a predetermined threshold level of interference, the frequency band of the received radio signal within the spectrum of the irradiating radio signal is shifted to a decrease in the constant component of the detected signal below the threshold level of interference, when the constant component of the detected threshold signal is exceeded the level of interference in the entire range of tuning the frequency band received signal forming an additional alarm to indicate the electromagnetic suppression. 2. A method for detecting an intruder using an ultra-wideband (UWB) signal, namely, that the controlled area is irradiated with a pulse UWB radio signal, when receiving a pulsed UWB radio signal, n reception channels are allocated in n frequency bands within the total spectrum width of the UWB radio signal the radio signal in the receiving channels and when these changes exceed the threshold level of the signal, the main alarm signal is generated, characterized in that when receiving and detecting the envelope the emitted pulsed radio signal in each of the n frequency channels, the appearance and level of the constant component of the detected signal corresponding to the presence of extraneous narrow-band interference are controlled, when this level exceeds the specified threshold level of interference in the ith reception channel (i≤n), this channel is disconnected from the the formation of the main alarm signal, when the level of the constant component of the detected signal exceeds the specified threshold level of interference in several or all n channels A valid alarm signaling electromagnetic suppression. 3. A method for detecting an intruder using an ultra-wideband (UWB) signal, namely, that the controlled area is irradiated with a pulsed UWB radio signal, when receiving a pulsed UWB radio signal, n reception channels are allocated in n frequency bands within the total spectrum width of the UWB radio signal, in each channel, a signal corresponding to the amplitude of the received pulsed radio signal, characterized in that the signals corresponding to the amplitudes of the received pulsed radio signals of each of the n frequency channels, sum when the changes in the total signal exceed the threshold level of the signal, the main alarm is generated, when receiving and detecting the envelope of the received pulsed radio signal in each of the n frequency channels, the appearance and level of the constant component of the detected signal corresponding to the presence of extraneous narrow-band noise is controlled when this level exceeds the specified threshold the interference level in the ith reception channel (i≤n) for the time of exceeding this channel is excluded from the summed, if the level is constantly exceeded of the detected signal of a given threshold level of interference in several or all n channels generate an additional alarm signaling about electromagnetic suppression.

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