RU2695415C2 - Method of determining degree and location of disturbance of zone fiber-optic protection system of objects and device for its implementation - Google Patents

Abstract

FIELD: optics.SUBSTANCE: invention relates to fibre-optic interferometry and can be used in equipment which enables to detect penetration into a protected perimeter, for example, for prevention of overcoming barriers of industrial enterprises. In order to realize this result in method, sensitive cable is divided into zones, each of which represents Michelson fibre-optic interferometer. To realize the principle of frequency multiplexing, the difference of optical paths in the interferometers is different, and the laser has the possibility of tuning the radiation frequency according to the saw-tooth law. Interference signal is the sum of signals with different frequencies corresponding to different zones. Separators and reference frequency grid are used to separate signals. Penetration into the protected perimeter is determined by signals at the output of synchronous detectors.EFFECT: technical result in method and device for its implementation is increase of accuracy of disturbance point determination at weak disturbance of protected perimeter.2 cl, 1 dwg

Description

The invention relates to the field of optical interferometry, and can be used in equipment that can detect penetration into a protected perimeter, for example, to warn about overcoming the barriers of industrial enterprises.

A known method of determining the degree of perturbation of the optical fiber installed around the perimeter of the protected circuit due to microvibrations that occur when breaking the protective barrier and a device for its implementation. Fiber-optic system TSO "SOVA", O.V. Gorbachev, Informost - Radioelectronics and Telecommunications No. 1 (43) 2006. A multimode fiber is used as a sensitive element, when disturbed by microvibrations and microbends, the speckle structure of the light at the fiber output changes at any point in the loop. The registration of this change allows us to judge the penetration through the protected circuit. The device comprises a series-mounted laser, a multimode optical cable, a radiation receiving unit, and a processing unit. Due to the disturbance of the cable by micro-vibrations, the speckle structure of the radiation at the input of the radiation receiving unit undergoes changes, which is recorded by the processing unit.

The main disadvantage of the method described above is the low sensitivity when determining the degree of perturbation of the fiber, as well as the inability to determine the location of the perturbation of the protected circuit.

There is also a method of determining the degree and place of disturbance of a guarded circuit in fiber-optic systems and a device for its implementation (Distributed fiber-optic systems for perimeter protection: advanced technologies, P. Ivanchenko, V. Krasovsky, Security Algorithm, No. 4, 2003.)

The pulsed radiation of coherent light is sent to a sensitive cable containing a series of Fizeau fiber interferometers in series, formed by a series of partially-reflecting planes in a single-mode fiber, made in the form of Bragg gratings, which divide the perimeter into zones, the distance between them being the same, and the laser radiation coherence length less than this distance. Radiation reflected from these planes is passed through an additional Mach-Zehnder optical fiber interferometer, in one arm of which a phase modulator is located, and in the other a fiber delay line, the length of this fiber being twice the distance between the partially reflecting planes. Thus, at the output of the Mach-Zehnder interferometer there is a pulsed interference signal corresponding to the interference of rays reflected from neighboring planes. The temporary position of the pulses corresponds to different zones. Zones correspond to different sections of the cable enclosed between adjacent reflective planes. An analysis of the phase modulated signal allows one to judge the degree of perturbation of each perimeter zone.

A device for implementing this method comprises a sequentially installed laser radiation source, a Mach-Zehnder fiber-optic interferometer and a fiber-optic cable in which a series of partially reflecting planes made in the form of Bragg gratings are sequentially initiated at the same distance. In one arm of the Mach-Zehnder interferometer, an electro-mechanical modulator of the radiation phase is installed, in the other a fiber delay line. Moreover, the branching device installed at the input of the Mach-Zehnder interferometer is made according to the X-shaped scheme, i.e. has two entrances. To the second input of this branch is connected to the input unit of the registration and signal processing. The outputs of a pulsed generator are connected to a laser light source and to a signal recording and processing unit, which initiates their operation in a pulsed mode.

The disadvantage of these methods and devices for its implementation is the presence of additional spurious reflections in the sensitive cable, which in time coincide with the main ones, but characterize other zones. These crosstalk reduce the likelihood of detection while simultaneously penetrating in two or more places in the guarded perimeter. In fact, pulsed radiation reflected, for example, from the junction of the third and fourth zones, coincides in time with the radiation successively reflected from the boundary of the second and third zones, then in the reverse direction from the junction of the first and second zones and again from the boundary of the second and third zone.

With an increase in the number of zones, the number of spurious reflections also increases, which ultimately limits the total number of zones.

The closest in technical essence and accepted by the author for the prototype is the application for invention No. 2007122828/28 of 06/18/2007. author Hopov VV, A method for determining the degree and place of disturbance of a fiber-optic system when guarding an object and a device for its implementation.

In the prototype method, the radiation of coherent light, the frequency of which is changed according to a sawtooth law, is divided into two beams, the first of which is sent from one direction to the first branch of the Mach-Zehnder fiber optic interferometer, and the second through an additional branch from the opposite direction to the second branch of the same interferometer. Due to the installation of a fiber coil in one arm in close proximity to the first branch of the interferometer, it has different shoulder lengths, and their difference is less than the coherence length of the laser radiation. Due to this, as well as a linear change in the frequency of light, sinusoidal signals whose frequencies are equal are recorded at the second inputs of the first branch of the interferometer and the additional branch. Since the perturbation of the perimeter reaches the photodetectors at different times, then this delay is used to judge the location of the perturbation of the guarded circuit. To determine the degree of perturbation of the perimeter, a reference unperturbed sinusoidal signal is formed by creating an additional Mach-Zehnder fiber interferometer. To do this, before and after the fiber spool, two additional beams branch along the second beam with the help of additional branches, combine them with the help of a third additional branch, and a reference sinusoidal signal is recorded at its output. By comparing the phases of the reference and the signal from the second output of the first branch of the interferometer, they judge the degree of perturbation of the perimeter.

A device for implementing the prototype method comprises a laser with a fiber-optic output and a fiber-optic coupler installed in series and connected, one of the outputs of which is connected to the input of the first fiber-optic branch of the Mach-Zehnder interferometer, and the other output of this branch is connected to the input of an additional bidirectional branch , in turn, the output of which is connected to the input of the second fiber-optic branch of the Mach-Zehnder interferometer. Blocks of registration of interference signals are connected to the second inputs of the first and additional branches. To increase the accuracy of determining the location of the perimeter perturbation, a fiber coil is installed in one of the arms of the interferometer, while the difference in the path of the interfering rays is less than the coherence of light. Due to the change in the frequency of the laser light according to the sawtooth law and the presence of the aforementioned difference in travel, the interference signal is a sinusoid. This makes it possible to record with good accuracy the delay of the perturbation of the beams propagating in the Mach-Zehnder interferometer in opposite directions when the perimeter is perturbed. And this delay is unambiguously related to the perturbation site of the perimeter.

To register the degree of perturbation of the perimeter, an additional Mach-Zehnder interferometer is used, which is formed by an additional first branch, installed in front of the fiber spool, and additional second and third branches. The third is installed after the coil, and the second combines the bundles branched by the first and third branches. Thus, at the output of the second branch, an additional interference signal is recorded, of the same frequency as the first two signals, but with an unperturbed phase. Comparison of an additional unperturbed signal with a perturbed signal using a synchronous detector allows one to judge the degree of perturbation of the perimeter.

The disadvantage of these methods and devices for its implementation is the dependence of the accuracy of determining the place of penetration into the guarded perimeter on the magnitude of the disturbance of the fiber cable. Therefore, the use of such a system by laying a sensitive cable in the ground is limited.

The problem to which the invention is directed is to create a method for determining the degree and place of perturbation of a zone fiber-optic security system for objects and a device for its implementation, which can solve the problem in any operating conditions.

The problem is solved in that in the method for determining the degree and place of disturbance of the zone fiber-optic system of object protection, the interferometer of the sensitive cable is performed in the form of a sequential series of Michelson interferometers, the number of zones being equal to the number of these interferometers, the difference in the path lengths of interfering beams in which is less than the coherence of light while this difference for all interferometers of the sensitive cable is not the same, the radiation at the input of all interferometers of the sensitive cable is sent using bidirectional couplers connected in series using single-mode fiber segments, the length of these segments being more than the coherence length of the light used, recorded at the second input of the object bidirectional branching device, as a result of interference in all interferometers of the sensitive cable, the sum of sinusoidal signals with different frequencies corresponding to different the values of the difference of the shoulders of the Michelson interferometers, from the sinusoidal signal of the additional interferometer a grid of reference frequencies by multiplying its frequency by coefficients equal to the ratio of the travel difference in the arms of the Michelson interferometers and the additional interferometer and adding a constant value using a number of mixers, one of the inputs of which are sent sinusoidal signals corresponding to one of the frequencies of the formed grid, and to the second inputs the interference signal, which is recorded at the second input of the object bidirectional branch, allocate a number of intermediate frequency signals corresponding to the post yannoy additive during the formation of the grid frequency, the phase of these signals are judged on the perturbation zone and the number of the mixer on the location of the perturbation.

The task in the device for determining the degree and location of the disturbance of the zone fiber-optic system of object protection is solved by the fact that a series of branching points of the sensitive cable are installed sequentially behind the output of the object branch, each of which corresponds to one zone, the input of the first connected to the output of the object branch, and each input subsequent branches are connected to the outputs of previous branches by means of a fiber segment, the length of which is longer than the coherence length of the laser light, behind the second output each branch of the sensitive cable has a Michelson fiber-optic interferometer containing a branch, two lengths of fiber of different lengths, with mirror coatings on one end, and the input of the corresponding branch of the Michelson interferometer is connected to the output of each branch of the sensitive cable, and the second ends of the segments are connected to its outputs fibers whose length difference is less than the laser light coherence length and is not the same for all Michelson interferometers, the second output of the first branch Itel is connected to the input of the first additional branching device, and the output of the fiber coil is connected to the second input of the second additional branching unit, the registration unit of the interference signal of the additional interferometer contains one polarizer sequentially installed after the output of the second additional branching device with the possibility of rotation of its orientation around the axis coinciding with the output of the second additional branching device , one photodetector, the output of which is the output of this unit, the interference registration unit the signal has three outputs, which are the outputs of the photodetectors, the unit for recording the interference signal of the additional interferometer is connected to the first inputs of the reference frequency formers, the number of which is equal to the number of Michelson interferometers in the sensitive cable, the intermediate frequency generator output is connected to the second inputs of the former, and the output frequency each shaper is determined by the expression

Fn = Fref * Ln / Lref + Fprom, where

Fref is the frequency of the interference signal of the additional interferometer,

Ln is the shoulder length difference of the n-th Michelson interferometer of the sensitive cable,

Lref - shoulder length difference of an additional interferometer,

Fprom - intermediate frequency,

the output of each reference frequency grid former is connected to the first inputs of a group of three mixers, the number of mixer groups is equal to the number of reference frequencies, and the three outputs of the interference signal recording unit are connected to the second inputs of the mixers of each group, the outputs of the mixers of each group are connected to the signal adder block containing three quadrators, an adder and a circuit for dividing the signal frequency into two, and the input of each quadrator is the input of the block, the outputs of the quadrators are connected to the inputs of the adder, turn adder output is connected to the input signal frequency dividing circuit into two, the output of which is the output of adder blocks, each of which is connected to a first input of determining disturbance zones of blocks are designed as synchronous detectors, the second input of which is connected to the intermediate frequency generator.

The invention is illustrated by drawings, where in FIG. 1 shows a diagram of a device.

In order to exclude the dependence of the accuracy of determining the location of the disturbance on the degree of disturbance, it is necessary to divide the perimeter into zones. At the same time, it is necessary to determine the perturbations in the zones at the same time, despite the fact that they are united by a single fiber that supplies radiation to them. One way to implement this approach is frequency division multiplexing. Those. zones should correspond to signals with different frequencies.

In the prototype circuit, the interference signal is a sinusoid, due to two factors, the first is the sawtooth law of the laser radiation frequency change, and the second is the travel difference in the arms of the interferometer. In fact, in this case, the frequencies of the interfering rays, due to the delay relative to each other, are shifted, and the result of their interference is a sinusoid with a frequency equal to the magnitude of this shift. Therefore, if we make the shoulder difference of all interferometers of the sensitive cable different, then the signals corresponding to different zones will be characterized by different frequencies, i.e. The principle of frequency multiplexing is implemented. The interference signal registration unit registers the interference of beams in all interferometers of the sensitive cable, and the relative polarization orientation of these beams can take any value from 0 to 90 degrees, i.e. the signal can vary from zero to a maximum value. To eliminate this drawback, the light aperture at the output of the object branch is divided into three zones, in each of which a polarizer is installed, and their orientations are different. 120 degrees is the optimal value for the relative orientation of the polarizers. A photodetector is installed behind each of the polarizers, the phase of the signals from the photodetectors can differ by 180 degrees, so they are summed only after filtering and squaring.

If the sensitive cable is disturbed, the phase of the interference signals is modulated. In order to determine it, a signal with the same frequency but an unperturbed phase is needed. For this, a grid of reference frequencies is created. Since the frequency of the signals is proportional to the difference in the arms of the interferometers, it is possible to obtain a signal of the same frequency as in the interferometers of the sensitive cable by multiplying the unperturbed signal frequency of the additional interferometer by coefficients equal to the ratio of the travel difference in the arms of the Michelson interferometers and the additional interferometer.

The inventive method can be implemented using a device, a diagram of which is presented in FIG. 1. The figure shows a laser with fiber-optic output 1, which includes a sawtooth law for tuning the radiation frequency, the first branch 2, the object branch 3, the interference signal recording unit 4, the first additional branch 5, the second additional branch 6, fiber coil 7, block for recording the interference signal of an additional interferometer 8, branching of the sensitive cable 9, fiber segments 10, branching of fiber-optic Michelson interferometers 11, fiber segments with a mirror coating 12, the shapers of the reference frequency grid 13, the intermediate frequency Generator 14, the group of mixers 15, the blocks of the adders of the signal 16, the blocks determine the perturbation of the zones 17.

The output of the laser 1 is connected to the input of the fiber optic branch 2, the output of which is connected to the input of the object branch 3, the interference signal recording unit 4 is connected to the other input of the branch 3, the second output of the first branch 2 is connected to the input of the first additional branch 5, the first output of which is connected to the first input of the second additional branch 6, the second output of the first additional branch 5 is connected to the input of the fiber spool 7, the output of which is connected to the second input of the second additional branch 6, to the output of the branch 6, the registration unit of the interference signal of the additional interferometer 8 is connected, to the output of the object branch 3, the branches 9 of the sensitive cable are connected using fiber segments 10, the inputs of the branches of Michelson 11 optical fiber interferometers are connected to the second outputs of the branches 9, to the outputs branching 11 connected segments of fiber with a mirror coating 12, with the output of the registration unit of the interference signal of an additional interferometer 8 connected first e inputs of the reference frequency shapers 13, the output of the intermediate frequency generator 14 is connected to its second inputs, the outputs of each reference frequency shapers 13 are connected to the first inputs of the mixer groups 15, combining the three mixers, one of the three outputs is connected to the second input of each mixer group block registration interference signal 4, to the outputs of each of the group of mixers 15 is connected one of the three inputs of the block of adders signal 16, the outputs of the adders of the signal connected to the first inputs of the blocks defined disturbances of zones 17, and the output of the intermediate frequency generator 14 is connected to its second inputs.

A device for determining the degree and place of disturbance of a zone fiber optic security system of an object operates as follows. Coherent radiation from the output of laser 1, the frequency of which changes according to a sawtooth law by changing the current, is fed to a branch 2 input using a single-mode fiber. Since the device as a whole is interferometric, all fiber-optic components are single-mode. The branch 2 sends part of the radiation to the input of the bidirectional branch 3, which on the one hand directs the radiation further to the sensitive cable, and on the other hand, in the reverse direction, it is used to register the interference of pairs of rays in the interferometers of the sensitive cable. For this, an interference signal recording unit 4 is connected to its second output (input).

A reduction to zero of the interference signal due to the non-optimal orientation of the polarization of the interfering rays can be eliminated if three differently oriented polarizers are placed behind the output of the branching device 3 and are not overlapping, installed in the same plane, the sum of the areas of which is equal to the optical aperture of the fiber, each of which has photodetectors . Since the phases of the signals at the output of the photodetectors can differ by 180 degrees, they can be added, firstly, after filtering, and secondly, for example, after squaring. Therefore, block 4 has three outputs, each of which is the output of a photodetector.

The branch 2 sends the other part of the radiation to an additional interferometer consisting of branches 5, 6 and in one of the arms of which a fiber coil 7 is installed, the length of which is less than the laser coherence length. This Mach-Zehnder fiber optic interferometer serves to provide a reference signal with an unperturbed phase. To register the interference signal in block 8, a polarizer is also installed, but since the signal is the only sinusoid, the maximum amplitude of the signal is achieved by rotating the orientation of this polarizer.

Through the branch 3, the laser radiation is directed into a sensitive cable, which is the sum of Michelson's fiber-optic interferometers connected in series. The cable is divided into zones by means of couplings in which the components of these interferometers are installed, in addition, the length of these zones must be greater than the coherence length of the laser radiation so that the light reflected from the mirrors of different interferometers does not interfere with each other. In the couplings are branching 9, which are designed to branch laser radiation into interferometers. They are connected by fiber segments 10. Moreover, the closer to the beginning of the cable the branch is located, the less light part it branches into the interferometer. For example, if there are four zones, the first branch has a ratio of 1 to 3, the second 1 to 2 and the third 1 to 1. With these parameters, the amplitudes of the interference signals will be equal. In the same couplings there are Michelson 11. interferometer branches. Its inputs are connected to the outputs of the 9 branches, branching a smaller part of the world. To the outputs of the branching 10 connected segments of fiber with the applied mirrors at the ends, they are not equal and their length difference is not the same for all zones. This is what allows the principle of frequency multiplexing to be implemented. The ends of the coated sections 12 are located in the coupling of the next zone or in a separate coupling, if this is the last zone. A cable option is also possible when, to increase the sensitivity, the segments are located in the subsequent and previous couplings relative to the one in which the branches 9 and 11 are located. In this embodiment, the number of couplings is doubled.

The signal from the output of block 8 is fed to the first input of the reference frequency formers 13. The sinusoidal signal of the intermediate frequency from the generator 14 is received at the second input. The ratio of the travel difference in the arms of the Michelson interferometers and the additional interferometer can be represented by a fraction, for example, up to the third decimal place . In this case, the denominator is 1000, and the numerator is several times larger or smaller. It depends on the relationship mentioned above. Those. if we multiply the initial frequency by the number in the numerator, and then divide by 1000, then the procedure for multiplying the initial frequency by a fraction is implemented. For multiplication in block 13, a system with phase-locked loop is used, that is, a feedback loop: a controlled oscillator-frequency divider — a phase detector-low-frequency filter — a controlled oscillator. Moreover, the second input of the phase detector is the first input of block 13, i.e. it receives a signal that must be multiplied. The number to be multiplied is a parameter of the frequency divider located in the feedback circuit. Dividing by the denominator 1000 is a similar frequency divider. In the same block, an offset occurs, multiplied by the coefficient of the initial frequency, by a constant value equal to the intermediate frequency. This is done using a classic mixer, consisting of a multiplier of two signals and a filter. The intermediate frequency signal is supplied to the second input of block 13 from the intermediate frequency generator 14.

In mixers 15, the signals from block 4 are subtracted from the unperturbed and shifted frequencies from blocks 13 and the potentially disturbed frequencies of the signals. Since there are three of these signals, there are three mixers, i.e. mixers 15 are divided into groups. These groups correspond to zones. At this stage, the total signal corresponding to the cable is divided into separate signals corresponding to the zones. This is achieved by the fact that each group receives its own local oscillator frequency from blocks 13.

Three signals of each group of mixers are fed to the inputs of the adder 16. These signals have the same frequency, but can differ in phase by 180 degrees. Before folding, they are in block 16 squared using a voltage quadrator. Addition occurs using a classic adder, made using an operational amplifier, the constant component is removed by a transition capacitor. As a result of the squaring operation, the signal frequency doubled. In block 16, the signal frequency is divided into two using sequentially installed comparator and a single-bit counter.

From the output of blocks 16, a digital intermediate-frequency signal is fed to the first inputs of the blocks for determining the disturbance of zones 17, and the second inputs of these blocks are fed by a signal from the generator 14. The blocks 17 are synchronous detectors. A potentially disturbed signal from blocks 16 and an unperturbed signal of the same frequency from block 14 are compared. The signal from the output of the synchronous detector has an arbitrary initial phase, therefore, block 17 is equipped with a high-pass filter to filter the DC component. Thus, at the output of this filter, the voltage reflects the instantaneous value of the disturbance of the sensitive cable zone, and the block number corresponds to the location of the disturbance.

Currently, the industry produces laser diodes with distributed feedback, their parameters are most suitable for creating a difference in the frequency of the rays. For example, model FF-1530-1610-40-DFB-BTF-B. (FRANKFURT LASER) Wavelength 1.55 μm. This model has a built-in isolator. The coherence length of these lasers reaches 50 m, which is less than the length of a typical zone (100-200 m) and at the same time more than the path difference in the arms of interferometers (1-10 m). The tuning is carried out by changing the temperature of the diode. It is more convenient to change the temperature of the laser by changing its current. With the mentioned values of the difference of the arms of the interferometers, the signal frequencies lie in the range of 10-100 KHz. This is quite sufficient for recording processes with a frequency band of not more than 5 KHz. The frequency spectrum of the perturbation of optical fibers by man, wind, etc. does not exceed this value.

As single-mode branching, LASER2000 С-NS-A-C-50-H-22-1550-FC / FC products with a division ratio of 50% can be used.

The photodetectors in blocks 4 and 8 are made according to the classical scheme of a photodiode-current-voltage converter using an operational amplifier. For example, photodiodes are Hamamatsu G 8370-01 products, and the AD 8055 operational amplifier is from Analog Device.

The squaring procedure in blocks 16 can be performed using the Analog Device AD633 multiplier, and the voltage adder using the TL081 operational amplifier.

The synchronous detector in block 17 can also be performed using an AD633 analog multiplier and an RC filter chain.

Thus, the present invention due to a combination of features will allow, by eliminating the dependence of determining the accuracy of the penetration site on the degree of perturbation of the sensitive cable, to more reliably protect industrial facilities.

Claims (8)

1. A method for determining the degree and place of perturbation of a zone fiber-optic object security system, which consists in sending part of the light source radiation with a frequency modulated according to a sawtooth law using the first input of an object bidirectional branching device into a sensitive cable containing a fiber optic interferometer with different the path length of the interfering beams, and this difference is less than the coherence length of the radiation source, the interference of the rays of the interferometer is recorded in the form of a sinusoidal of the signal, whose frequency corresponds to the difference in the path lengths of the interfering beams, the other part of the light source radiation is sent to an additional fiber-optic interferometer with different arm lengths, the difference of these arms being also less than the coherence length of the radiation source, the interference of light rays in the additional interferometer is recorded as a sinusoidal signal, the frequency of which corresponds to the difference of the arms of the additional interferometer, comparing the phases of the unperturbed interference signal to An additional interferometer and the interference signal of the interferometer in the sensitive cable are used to judge the degree of disturbance of the security system, and at the place of installation of the sensitive cable - the zone of penetration into the guarded perimeter, characterized in that the interferometer of the sensitive cable is made in the form of a series of Michelson interferometers, and the number of zones is equal to the number of these interferometers, the difference in the path lengths of interfering beams in which is less than the coherence length of light, while this difference is for all and the cable’s terferometers are not the same, the radiation at the input of all the cable’s interferometers is sent using bi-directional couplers connected in series using single-mode fiber segments, the length of these segments being more than the coherence length of the light used, is recorded at the second input of the object bi-directional branching device as a result of interference in all sensitive interferometers cable sum of sinusoidal signals with different frequencies corresponding to different values To the differences in the arm difference of Michelson interferometers, a grid of reference frequencies is formed from the sinusoidal signal of the additional interferometer by multiplying its frequency by coefficients equal to the ratio of the travel difference in the arms of Michelson interferometers and the additional interferometer and adding a constant value using a number of mixers, one of whose inputs is sinusoidal signals corresponding to one of the frequencies of the formed grid, and to the second inputs an interference signal that is recorded at the second m of the input of the object bidirectional branch, a number of intermediate frequency signals are allocated that correspond to the constant addition during the formation of the frequency grid, the phase of these signals is used to judge the disturbance of the zones, and the number of the mixer indicates the location of the disturbance. 2. A device for determining the degree and place of perturbation of a zone fiber-optic system of object protection for implementing the method according to claim 1, comprising a sequentially mounted laser unit with a fiber-optic output with the possibility of tuning the radiation frequency according to a sawtooth law, a first branch, an object branch, a sensitive cable wherein the laser output is connected to the input of the first branch, the first output of which is connected to the first input of the object branch, the regi block is connected to the second input of the object branch interference signal, containing three polarizers, three photodetectors, the polarizers being installed in the same plane, and the orientation of their polarization axes is different, and the sum of the areas is equal to the output aperture of the interfering rays, a photodetector is installed behind each polarizer, components of an additional fiber-optic interferometer, namely the first additional branch, a fiber spool whose length is less than the coherence length of the laser light, the second additional branch, and the first output of the first of the second additional branch is connected to the first input of the second additional branch, the second output of the first additional branch is connected to the input of the fiber coil, the unit for recording the interference signal of the additional interferometer is connected to the output of the second additional branch, characterized in that a number of branches of the sensitive cable are installed in series behind the output of the object branch each of which corresponds to one zone, and the input of the first is connected to the output of the object branch, and Each input of the next branching device is connected to the output of the previous branching device by means of a fiber length longer than the coherence of the laser light, a Michelson fiber-optic interferometer containing a branching device, two lengths of fiber of different lengths, with mirror coatings on one, is installed behind the second output of each branch of the sensitive cable the end, and to the output of each branch of the sensitive cable is connected the input of the corresponding branch of the Michelson interferometer, and to its the ends are connected to the second ends of the fiber segments, the difference of the lengths of which is less than the coherence length of the laser light and is not the same for all Michelson interferometers, the second output of the first branch is connected to the input of the first additional branch, and the output of the fiber coil is connected to the second input of the second additional branch, the registration unit of the interference signal of the additional the interferometer contains one polarizer sequentially installed behind the output of the second additional branching device with the possibility of rotation Its orientation around the axis coinciding with the output of the second additional branching device, one photodetector, the output of which is the output of this unit, the interference signal registration unit has three outputs, which are the outputs of the photodetectors, the interference signal recording unit of the additional interferometer is connected to the first inputs of the reference frequency formers , the number of which is equal to the number of Michelson interferometers in the sensitive cable, connected to the second inputs of the former shaper course of the intermediate frequency oscillator, and the frequency at the output of each generator is determined by the expression Fn = Fref * Ln / Lref + Fprom, where Fref is the frequency of the interference signal of the additional interferometer, Ln is the shoulder length difference of the n-th Michelson interferometer of the sensitive cable, Lref - shoulder length difference of an additional interferometer, Fprom - intermediate frequency, the output of each reference frequency grid former is connected to the first inputs of a group of three mixers, the number of mixer groups is equal to the number of reference frequencies, and the three outputs of the interference signal recording unit are connected to the second inputs of the mixers of each group, the outputs of the mixers of each group are connected to the signal adder block containing three quadrators, an adder and a circuit for dividing the signal frequency into two, and the input of each quadrator is the input of the block, the outputs of the quadrators are connected to the inputs of the adder, turn adder output is connected to the input signal frequency dividing circuit into two, the output of which is the output of adder blocks, each of which is connected to a first input of determining disturbance zones of blocks are designed as synchronous detectors, the second input of which is connected to the intermediate frequency generator.

Images