RU2815830C1 - Method of laying fibre-optic cable into ground using mechanized cable layer - Google Patents

Abstract

FIELD: measurement.

SUBSTANCE: invention relates to measuring equipment using optical fibre, namely to security fibre-optic detectors, as well as to products, methods and means related to security fibre-optic detectors and their aspects. Disclosed is a method for mechanized laying of fibre-optic cable into ground, at which for laying of fibre-optic cable in ground mechanized cable laying machine with channel of flexible linear products input and V-shaped plough is used, made with possibility of unwinding device mounting on it for installation on it of fibre-optic cable drum for mechanized laying of fibre-optic cable into ground, at which water is supplied to the flexible linear elements inlet channel to ensure better contact of the cable with the ground, and upon completion of laying, performing subsequent compaction by cable layer; and/or the cable is laid along a curvilinear trajectory with alternating change in the direction of the bending radius of the trajectory so that the cable is tensioned during the laying process.

EFFECT: accelerating the process of mounting the sensitive element of a security fibre-optic detector, increasing its sensitivity and ensuring uniformity of its sensitivity, as well as realizing its purpose.

3 cl, 12 dwg

Description

[1] TECHNICAL FIELD

[2] The invention relates to measuring technology using optical fiber, namely to fiber-optic security detectors, as well as to products, methods and means related to fiber-optic security detectors and their aspects.

[3] BACKGROUND ART

[4] From RF patent No. 2648008 (D1) a device is known for collecting information about the magnitude of dynamic effects on flexible structures and the state of fiber optic end detectors. The device contains a station part, a fiber-optic transport cable connected by an optical contact to a reflectometer at one end, and the other end connected to a splitter used to branch and continue transporting the energy of probing pulses to the sensitive parts of the optical circuit of the device, adjusting optical coils, splitters of the transport part of the optical circuit; splitters designed directly to form an optical ring of the sensitive part of the device, and fiber optic end detectors. The branched transport parts of the device into parts of splitters and sections of transport cable divide the energy of the probing pulse to the required power level in order to ensure the magnitude of the reflection signals from the sensitive part of the optical circuit of the device in the nominal range from the measurement scale of the receiving device, and also deliver the energy of the laser pulse to the location connecting splitters that form optical rings of the sensitive part of the optical circuit of the device and generate signals for the return of the probing pulse.

[5] The device known from D1 has low protection from the influence of interference factors, the influence of drift of the measuring properties of the transceiver device, low accuracy in determining the impact on the sensitive element, and high installation complexity, including due to the fact that it requires the use of compensation coils. , necessary to compensate for the length of the fibers of the sensing element, uneven sensitivity along the length of the sensing element.

[6] From RF patent No. 2400897 (D2) a drum for attaching couplings with an optical cable cable is known. The drum is a rigid frame made up of elements (9, 10, 11) (round rods, profiles or strips) with a bracket and connecting points (2) for attaching couplings (1). The bracket is made in the form of a plate (3) with flanges (8) and a vertical axis (4) welded into its center; the drum is mounted on a vertical axis (4) and thus fixed on the bracket. The drum is fastened to a round concrete support of an overhead power line using tape clamps fixed in the shoulders made in the plate (3), and the drum is fastened to a polygonal concrete support (25) by means of corners in a flat plate of the bracket, in which pins passing through support trunk.

[7] The device known from D2 is not intended for winding the finished product, which is the linear part of a fiber-optic security detector for the purpose of further transporting the container and installing said linear part on the protected perimeter directly from the container, which leads to a complication of the installation process and an increase in installation time , the inability to use a vehicle for installation, the inability to use a mechanized method of laying the linear part of the fiber-optic security detector.

[8] From RF patent No. 2599527 (D3) a method of combined protection of the perimeter of an extended object is known. The invention relates to technical means for protecting the perimeters of objects and can be used for signaling blocking of the perimeters of objects and extended boundaries on flat and rough terrain. The method includes implementing seven security lines: the first warning line by laying an extended sensitive element in the form of a fiber-optic cable; the second warning line, which is carried out similarly to the first; the third line in the form of an electroshock barrier; the fourth line of security, which is performed similarly to the first and second; the fifth line of security is the boundary of the perimeter of the object, which is made in the form of a lattice fence, while a spiral security barrier and at least one sensitive element are installed on the fence; arrangement of the sixth line of security - a control and trail strip, and the seventh line, which is carried out similarly to the first, second and fourth lines. The fifth line is equipped with means of thermal and video surveillance, sound notification and lighting; optical alarm sensors are connected to the sensitive element.

[9] The fence known from D3 requires the use of a mesh to prevent undermining, and also involves irrational placement of sensitive elements on the fence, which reduces the overall effectiveness of perimeter security and complicates the process of detecting unauthorized access.

[10] From patent US3417571 (D4) a means for laying cables with a double plow is known. Means for laying a cable for simultaneously plowing a furrow and for guiding the cable into it, includes two separate traction elements with independent power supply, the means includes: (a) an elongated frame, adjustable in the longitudinal direction and hingedly connected to the rear part of the front traction element and to the front end rear traction member to keep the traction members spaced apart, (b) a protruding arm associated with a side of said frame, (c) a plow shank mounting frame mounted on a bracket, (d) a plow shank mounted on said mounting frame plow shank, (e) a cable reel frame mounted on one of the traction members, (f) a cable guide mounted on the rear side of the plow shank, and (g) a cable guide mounted on one of the traction members located between the cable frame reel and cable guide on the plow shank.

[11] The product known from D4 has a low cable laying speed and also leads to the formation of cavities in the ground, which reduce the sensitivity of the linear part of the fiber-optic security detector.

[12] From patent US5694114 (D5) a high-speed secure fiber optic system is known. A high-speed, secure fiber optic communications system that includes a coherent signaling system uses a pair of single-mode fiber optic cables in combination with one or more light sources, phase modulators, detectors, and polarization scrambling elements to form a Sagnac interferometer. The phase modulator is driven so that the oncoming light rays in the Sagnac loop follow a different optical path as they pass through the loop. When the two beams recombine at the central beam splitter of the Sagnac circuit, the two beams interfere with each other, and the data phase modulated on the light beams by the phase modulator is recovered as amplitude modulation at the output detector of the Sagnac interferometer. The coherent alarm system feeds a relatively low-frequency background signal to the Sagnac interferometer and monitors changes in the background signal that indicate the presence of an intruder.

[13] The sensitive part known from D5 does not allow detecting the impact on moving structures as part of the protected perimeter, which reduces the overall security of the perimeter, and also requires the use of electrical energy in the linear part of the system to determine the impact on the structure.

[14] From the RF patent No. 172554 (D6) an end fiber optic detector is known. An end-of-fiber optic detector (EFD) contains a housing with a working element that ensures a change in the position of the optical fibers of the sensitive part of the KOI, a sensitive part that is installed in the KOI body and connected to a transport part that ensures the connection of the KOI to an extensive optical network and the transportation of laser pulses in forward and reverse direction. The sensitive part is made of optical fibers and a splitter, the outputs of which are connected to each other by an optical fiber and form a closed loop to generate a reflection signal, a change in the geometric position of the fibers in the sensitive part of the COI in the elastic range of deformations, due to a change in the position of the working element, is such that it leads to a change possibility of forming and passing reflection signals.

[15] The KOI known from D6 is characterized by the inability to assess the serviceability of the sensor in a state where the flow of the probing pulse is blocked, which, accordingly, reduces the overall security of the protected perimeter, and also reduces the effectiveness of detecting unauthorized access. In addition, the well-known KOI from D6 has a complex design of grips that prevents simple adjustment, and is also difficult to manufacture.

[16] The device known from D2 can be taken as the closest analogue.

[17] DISCLOSURE OF INVENTION

[18] The technical problem solved by the claimed invention is the creation of a technical tool that does not have the disadvantages of the closest analogue, and also ensures readiness to use the sensitive element of the detector immediately after laying the cable in the ground and thus speeds up the installation process, increasing sensitivity and ensuring uniform sensitivity of the cable. Another technical problem solved by the claimed invention is the creation of a technical tool that expands the arsenal of technical means - fiber optic security detectors, as well as their aspects.

[19] The technical result achieved by implementing the claimed invention is to speed up the process of installing the sensitive element of a fiber-optic security detector, as well as increase its sensitivity and ensure uniformity of its sensitivity, in particular, by ensuring a tight fit of the cable to the ground in the slot in the ground formed by lowering the upper part of the cut layer of soil onto the previous base, followed by compaction directly when laying the cable of the sensitive element using a V-shaped plow, in contrast to analogues that use a plow with a vertical plane of position for laying the cable, in the groove slots of which there are cavities in which the cable As a rule, it has point contact with the ground, which significantly reduces the uniformity of cable sensitivity and the efficiency of detecting seismic ground vibrations. Another technical result achieved by implementing the present invention is the implementation of its purpose.

[20] The technical result is achieved due to the fact that a method is provided for mechanized laying of a fiber-optic cable in the ground, in which a mechanized cable-layer with an input channel for flexible linear products and a V-shaped plow is used for laying the fiber-optic cable in the ground. attaching an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of the fiber-optic cable in the ground.

[21] BRIEF DESCRIPTION OF THE DRAWINGS

[22] Exemplary embodiments of the present invention are described in detail below with reference to the accompanying drawings, which are incorporated herein by reference, and in which:

[23] In FIG. 1-5 show exemplary functional diagrams of the claimed fiber-optic security detectors and interferometers used in their composition.

[24] In FIG. Figure 6 shows an approximate general embodiment of a container device for assembling the linear part of a fiber-optic security detector.

[25] In FIG. 7 and 8 show exemplary versions of the claimed fencing.

[26] In FIG. Figure 9 shows an example version of the cable laying method and the cable laying machine used for its implementation.

[27] In FIG. Figure 10 shows an example of a dynamic fiber optic sensor.

[28] In FIG. 11 and 12 show exemplary designs of a fiber optic end sensor.

[2] CARRYING OUT THE INVENTION

[30] In FIG. 1-5 show approximate general diagrams of the claimed fiber-optic security detectors. Preferably, without limitation, the optical circuit of each monitored zone uses a reflectometric method for measuring interfering reflection signals, including the method of combined interferometers, and contains closed and/or open circuits and/or a combination thereof, generating reflection signals that have the same sections of optical fiber of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the applied physical effect, and for combined (combined, joint) interferometers the mentioned phase shift is created, the same for both circuits, and preferably, without limitation, at the input The splitter receives signals with different phase shifts relative to each other, and the amplitudes of the signals at the input of the splitters preferably do not change, and the result of adding the signals significantly depends on the phase difference or phase shift of the signals relative to each other by a value from 0 to 2π. In this case, it is preferable that the amplitude of the signal at the output of the splitter is equal to the sum of the amplitudes of the input signals at α=0, and at α=π it is equal to the difference in the amplitudes of the input signals, and the maximum rate of change in the amplitude of the output signal occurs, preferably, at α=π/ 2. Preferably, without limitation, the optical circuit of each controlled zone is symmetrical with an acceptable error, and the sensitive part is any of the arms of the optical circuit. Preferably, without limitation, the sensitivity of optical rings of closed circuits to mechanical influences is maximum at the beginning of the optical ring in any direction and is significantly insensitive at the farthest end of the optical ring (in the middle of the ring), and the sensitivity of the optical ring gradually decreases from the beginning of the ring to the middle of the sensitive part, at In this case, the value of the sum of reflection signals of closed loops depends on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum of reflection signals depends on the strength and dynamic characteristics (in particular, but not limited to, the speed of influence, derivatives, frequency characteristics) impact on the sensitive part of the detector. Preferably, without limitation, the open circuit of the optical circuit is a two-beam interferometer, while the sensitivity of the open circuit optical circuit to mechanical influences is the same throughout the sensitive part of the optical circuit, while the value of the sum of the reflection signals depends on the power of the emitter, the value of the branched fraction of the probing energy pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum of the reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Preferably, without limitation, for an open circuit optical circuit, it is necessary to align the length of the arms of the interferometers with an acceptable error; the length of one of the arms, if necessary, is compensated by the duration of the probing pulse, the installation of an additional coil of single-mode fiber, or the use of a serial optical chain of the required length from reserve fiber-optic cores cable. Preferably, without limitation, the claimed means makes it possible to determine the location of an impact on a structure exceeding permissible values, at least with an accuracy of the size of the controlled area and with additional acceptable accuracy within the controlled area using special software, using the ratio of the reflection signals of a coordinate-dependent closed loop and/or coordinate-independent open loop. Preferably, but not limited to, to avoid overlap in time between the reflection signals from the closed and open loops, an additional coil of the same optical fiber is installed at the end of the closed loop between the outputs of the closed loop splitter. Preferably, without limitation, to avoid symmetrical effects on the optical fibers of the sensitive parts of the detector of each controlled zone, which reduce the sensitivity of the detector, optical cores of different legs should be used in two different fiber-optic cables located on different parts of barriers and structures, including the possibility of laying one of shoulders of the sensitive part of the optical circuit into the ground. Preferably, without limitation, the optical circuit of the detector forms a tree structure with at least one reflectometer, including a specialized reflectometer with integrated or non-combined inputs and outputs, with transport branches laid in different fiber-optic cables in different ways arriving to the inputs of the optical circuit of sensitive elements, while providing the possibility of duplicating the transport part of the detector, sensitive elements and station equipment. Preferably, without limitation, the optical fibers of the transport part of the detector can partially be structurally routed in fiber-optic cables with the fibers of the sensitive part of the detector or in separate cables. Preferably, without limitation, addressing and assigning conventional numbers to sensitive parts of the detector (controlled zones) is carried out by a computing device based on the arrival time of one or a pair of reflection signals from one or two circuits of the optical circuit of each controlled zone. Preferably, without limitation, end-of-fiber sensors (COD) with static information about the position of the moving mechanism of the sensor and other controlled areas that use other methods of generating a reflectometric response can be connected to any part of the optical circuit of the detector along the length of the transport part, subject to the possibility of separating part of the energy probing pulse without disrupting the operation of existing controlled zones and the condition that reflection signals from devices do not overlap in time with existing signals from controlled zones. Preferably, without limitation, devices with different principles of operation and optical circuits can be connected to any part of the optical circuit of the detector, using a reflectometric method for measuring low-power reflection signals, subject to the condition that it is possible to separate part of the energy of the probing pulse without disrupting the operation of existing controlled zones and the condition of not overlapping time of reflection signals from devices onto existing signals from controlled zones. Preferably, without limitation, the collection of information on the magnitude of returned signals from controlled areas on the magnitude of the dynamic impact on barriers and the positions of the working elements of the CODE is carried out using an information processing device, a reflectometer and a fiber-optic cable network branched out on splitters. The placement range of controlled zones and CODE depends on the power of the emitter and the share of the probing pulse energy for each zone and can reach 50,000 m or more in each direction, the number of controlled zones is determined by the required portion of the energy of the probing pulse allocated to the controlled zones and CODE. Preferably, without limitation, the detector can be used in security alarm systems for the perimeters of small and extended areas, including monitoring the status of code sensors used for control, the position of gates and wickets, and the like, without the use of electrical energy. Preferably, but not limited to, detectors can be used in explosive environments, in conditions of 100% humidity, increased gas contamination and dust, when operating in water, including sewage, in conditions of increased radiation, in conditions that exclude the possibility of using electrical devices, in electromagnetic conditions high power interference.

[31] In FIG. Figure 1 shows an approximate functional diagram of a fiber-optic security detector, which uses combined interferometers. Preferably, without limitation, the proposed fiber optic security detector 100, which uses combined interferometers, with reference to FIG. 1 contains at least: a transceiver device 101 containing a computing device and one or more reflectometers, including those with combined outputs of the signal emitter and receiver, to which the transport part 102 of the optical circuit of the detector is connected. Preferably, without limitation, the transport part 102 of the detector 100 consists of: sections of fiber-optic cable, connecting elements, laser pulse power divider 103, consisting of splitters that reduce the power of the laser pulse energy in the distributed optical circuit of the detector to the required level. Preferably, without limitation, the sensitive elements consist of: a splitter 104, dividing the energy of the probing pulse into two parts, sections 105, 106 of sensitive elements of a fiber-optic cable, splitters 107-110, 112, 113, and the Michelson interferometer is formed jointly by the splitter 104, sections cables 105, 106, splitters-separators of interferometers 107, 108 and splitters-reflectors 112, 113, the Mach-Zehnder interferometer is formed jointly by splitter 104, sections of cable 105, 106, splitters-separators of interferometers 107, 108, splitter-adder 109 and splitters Ttter- reflector 110, optionally with coil 111. Preferably, but not limited to, the splitter 104 and the ends of the sensing element cable sections are located in one coupling, and the interferometer splitters are located in another coupling or in several couplings. For example, but not limited to, the Michelson interferometer reflector splitters 112, 113 may be located in one other coupling, and the combiner splitter 109 and reflector splitter 110, optionally with the Mach-Zehnder interferometer coil 111, in yet another coupling. Preferably, without limitation, the transport part contains several branches (at least in terms of the number of controlled zones and the applied optical circuit for dividing the energy of the probe pulse of the divider), which arrive at the input of the corresponding splitter 104, located in the corresponding coupling. By way of example, and not limitation, splitters 110, 112, 113 may each be implemented using circulators. By way of example, and not limitation, another optical delay line may be used in place of coil 111, for example, but not limited to, made by optically connecting the required length of redundant fiber optic cable strands into an optical circuit.

[32] Such a fiber optic security detector 100 preferably, but not limited to, operates as follows. Preferably, without limitation, a short laser pulse is sent from the laser radiation source to the optical circuit at the input of the power divider of the transport part of the device, where the pulse power is divided into fractions. Preferably, without limitation, the divider is made of splitters with different degrees of division; the location of the splitters of the divider corresponds to the optical design of the device and is not strictly defined. Preferably, without limitation, the energy division of the probing pulse is carried out to the required power level in order to ensure the magnitude of the reflection signals of, respectively, the Michelson interferometer and the Mach-Zehnder interferometer from the sensitive part of the optical circuit of the device in the nominal range of the measurement scale of the receiving device. Preferably, without limitation, the time of arrival of the interfering signals at the input of the receiving device depends on the speed of propagation of laser radiation in the optical fiber material, on the length of the transport part and the length of the sensitive part, including the length of the control coils. Preferably, without limitation, the magnitude of the reflection signals, respectively, of the Michelson interferometer and the Mach-Zehnder interferometer depends on the degree of signal attenuation in the optical fiber, the degree of division of the energy of the probing pulse in the transport part of the device, the magnitude of the phase shift of the returned signals of the sensitive part of the device associated with the shape difference and the length of the paths of movement of impulses in the fiber to the place of impact. Preferably, without limitation, the change in the magnitude of the sums of interferometer signals corresponds to the magnitude and nature of the elastic deformation of the sensitive part of the device arising from the dynamic impact of the intruder on the structure on which the sensitive part of the device is fixed. Preferably, without limitation, the optical design of each monitored zone uses any reflectometric measurement method, in any combination, including the method of combined interferometers, including the method of two-beam Michelson and Mach-Zehnder interferometers, and contains, respectively, Michelson interferometer circuits and Mach-Zehnder interferometer. Preferably, without limitation, the same sections of optical fibers of the cable are sensitive elements of interferometers, in which a phase shift of the probing pulse is created in accordance with the applied physical impact. Preferably, without limitation, the sensitivity of the optical circuit of the Mach-Zehnder interferometer to mechanical influences is the same throughout the sensitive part of the optical circuit, the magnitude of the reflection signal depends on the power of the emitter, the initial value of the phase difference, and the change in the value of the sum of reflection signals depends on the strength and characteristics of the impact on sensitive part of the device. Preferably, without limitation, the circuit of the optical circuit is an unbalanced two-beam Mach-Zehnder interferometer, a reflectometric method of obtaining signals, for which it is preferable to align the length of the arms of the interferometers with an acceptable error within the duration of propagation of the probing pulse, and if necessary, the length of one of the arms is compensated by installing an additional coils of single-mode fiber, or using a serial optical chain of the required length from the reserve cores of the fiber-optic cable. Preferably, without limitation, the probing pulse in the Mach-Zehnder interferometer in the proposed optical design twice separates and combines the interfering signals. Preferably, without limitation, the sensitivity of the optical circuit of the Michelson interferometer to mechanical influences is the same throughout the sensitive part of the optical circuit, the magnitude of the reflection signal depends on the power of the emitter, the initial value of the phase difference, and the change in the value of the sum of reflection signals depends on the strength and characteristics of the impact on the sensitive part devices. Preferably, without limitation, the circuit of the optical circuit of the Michelson interferometer is an unbalanced two-beam Michelson interferometer, the method of obtaining signals is reflectometric; for the operation of the interferometer it is also preferable to align the length of the arms of the sensitive element with an acceptable error. Preferably, without limitation, the probing pulse in the Michelson interferometer in the proposed optical scheme separates the signals on the splitter 104, passes through the fibers of the segments 105 and 106 of the sensitive elements, separates the signals on the splitters 107 and 108 into interferometer shares, is reflected on the splitters 112, 113 and re-passes in the opposite direction in segments 105 and 106 and addition at the splitter 104 when traveling in the opposite direction, forming a combined signal of interfering reflections that is supplied to the input of the signal receiver. Preferably, without limitation, to eliminate symmetrical effects on the optical fibers of the sensitive parts of the device of each controlled zone, which reduce the sensitivity of the device, optical cores of different arms are used in two different fiber-optic cables located on different parts of barriers and structures. Preferably, without limitation, addressing and assigning conventional numbers to sensitive parts of the device (controlled areas) is carried out by the computing device based on the arrival time of two signals, respectively, a Michelson interferometer and a Mach-Zehnder interferometer. Preferably, without limitation, other sensitive elements with a different optical circuit using the reflectometric measurement method in various combinations, as well as end-of-fiber sensors with static information, can be connected to any part of the optical circuit of the device along the length of the transport part.

[33] Preferably, without limitation, the described fiber-optic security detector 100, which uses combined interferometers, refers to technical security equipment in which a single-mode fiber-optic cable is used as a sensitive element. Preferably, without limitation, the described device is intended for zonal organization of security lines. Preferably, without limitation, the described device can operate in conditions of increased industrial interference and natural influences and is intended for the protection of territories equipped with flexible mesh barriers, with canopies and tops made of reinforced razor tape or on barriers equipped with partially flexible and elastic elements, including a tunnel alarm . Preferably, without limitation, the proposed device is built using standard standard equipment used in fiber optic technology and special software. Preferably, without limitation, the proposed fiber-optic multi-zone signaling device for protecting the perimeters of small and extended objects is based on the use of a highly sensitive effect of the dependence of the phase-polarization, amplitude and frequency characteristics of the magnitude of the returned signals of the Michelson interferometer and the Mach-Zehnder interferometer, formed during the passage of part of the energy of the laser probing pulse radiation through an optical fiber in the forward and reverse directions, in the circuits of the optical circuit of the device, modulated by the physical influences of the intruder. Preferably, without limitation, the proposed device uses a reflectometric method to obtain reflection signals in order to determine their dynamic properties. Preferably, but not limited to, the reflection signals or return signals are received at the input of the receiving device sequentially and are separated from each other by the time of arrival. Preferably, without limitation, the addressing of return (reflection) signals from sensitive elements and optical sensors is carried out by an unambiguous correspondence between the range of placement of the sensitive element and the time of arrival of the reflection signal at the input of the receiving device. Preferably, but not limited to, the reflection signals of the Michelson interferometer and the Mach-Zehnder interferometer should arrive at the input of the receiving device at different times, this time being controlled by the length of the sensing element, or an additional coil, or redundant fibers of the sensing element, or other optical delay line, as described in this document.

[34] Thus, as the described fiber-optic security detector 100, which uses combined interferometers, a fiber-optic security detector is declared, which uses combined interferometers, at least containing a station part with a transceiver device connected to a linear part of the mentioned detector, and the linear part is a branched optical circuit based on splitters and a fiber-optic cable, which, through connecting couplings and a transport cable, connect the transceiver device and the sensitive elements of the security fiber-optic detector, containing closed and open circuits that generate signals reflections, in which the same sections of optical fiber of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created, in accordance with the physical effect exerted, identical for both circuits, with the closed circuit being a Mach-Zehnder interferometer, and the open circuit is a Michelson interferometer. Optionally, the Michelson interferometer reflector splitters and the combiner splitter and the Mach-Zehnder interferometer reflector splitter are placed in a single coupling. Optionally, the Michelson interferometer reflector splitters and the combiner splitter and the Mach-Zehnder interferometer reflector splitter are located in different couplings. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line, made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit, or made in the form of a coil of optical fiber. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the dividers of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, the branched optical circuit is configured to transmit the reflection signals of the Mach-Zehnder interferometer after they are reflected in the opposite direction, where they are re-divided and pass through sections of the sensitive elements in the opposite direction with a change in the phase of the reflection signals, after which the summation of the reflection signals and their interference. Optionally, the branched optical circuit is configured to transmit the reflection signals of the Mach-Zehnder interferometer along a separate path to the transceiver device without modification. Moreover, the Mach-Zehnder interferometer and the Michelson interferometer are two-beam interferometers, the sensitivity of which to mechanical influences is the same throughout the sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals , and the change in the value of the sum of the reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector, while the Mach-Zehnder interferometer and the Michelson interferometer are not balanced, and the lengths of the interferometer arms are aligned with an acceptable error depending on the duration of the laser probing pulse, while the length of one of the arms is, if necessary, compensated by any optical delay line.

[35] Thus, the linear part of the fiber-optic security detector 100, which uses combined interferometers, is declared as a linear part, which is a branched optical circuit based on splitters and a fiber-optic cable, which are connected to each other by means of couplings and a transport cable a transceiver device and sensitive elements of a fiber-optic security detector, containing closed and open circuits that generate reflection signals, in which the same sections of optical fiber cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the applied physical impact, the same for both loops, with the closed loop being a Mach-Zehnder interferometer and the open loop being a Michelson interferometer. Optionally, the Michelson interferometer reflector splitters and the combiner splitter and the Mach-Zehnder interferometer reflector splitter are placed in a single coupling. Optionally, the Michelson interferometer reflector splitters and the combiner splitter and the Mach-Zehnder interferometer reflector splitter are located in different couplings. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line, made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the dividers of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, the branched optical circuit is configured to transmit the reflection signals of the Mach-Zehnder interferometer after they are reflected in the opposite direction, where they are re-divided and pass through sections of the sensitive elements in the opposite direction with a change in the phase of the reflection signals, after which the summation of the reflection signals and their interference. Optionally, the branched optical circuit is configured to transmit the reflection signals of the Mach-Zehnder interferometer along a separate path to the transceiver device without modification. Moreover, the Mach-Zehnder interferometer and the Michelson interferometer are two-beam interferometers, the sensitivity of which to mechanical influences is the same throughout the sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals , and the change in the value of the sum of the reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector, while the Mach-Zehnder interferometer and the Michelson interferometer are not balanced, and the lengths of the interferometer arms are aligned with an acceptable error depending on the duration of the laser probing pulse, while the length one of the arms is, if necessary, compensated by any optical delay line.

[36] Thus, the connecting coupling of the security fiber optic detector 100, which uses combined interferometers, is declared as a connecting coupling, which is a connecting coupling in which the optical circuit of the security fiber optic detector is located, containing elements of closed and open circuits that form reflection signals, in which the same sections of optical fiber of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created, in accordance with the physical effect exerted, identical for both circuits, with the closed circuit being a Mach-Zehnder interferometer, and the open circuit the circuit is a Michelson interferometer. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the dividers of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Moreover, the Mach-Zehnder interferometer and the Michelson interferometer are two-beam interferometers, the sensitivity of which to mechanical influences is the same throughout the entire sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Mach-Zehnder interferometer and the Michelson interferometer are unbalanced, with the lengths of the arms of the interferometers aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms, if necessary, being compensated by some optical delay line. Optionally, the optical delay line is an optical delay line made by connecting the required length of reserve cores of a fiber optic cable into an optical circuit or made in the form of a coil of optical fiber.

[37] Thus, the optical circuit of the fiber-optic security detector 100, which uses combined interferometers, is declared as an optical circuit, which is combined interferometers for the fiber-optic security detector, implementing an optical circuit containing closed and open circuits that generate reflection signals , in which the same sections of optical fiber of the cable are sensitive elements of interferometers, in which a phase shift of the probing pulse is created in accordance with the applied physical effect, identical for both circuits, and the closed circuit is a Mach-Zehnder interferometer, and the open circuit is Michelson interferometer. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the dividers of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Moreover, the Mach-Zehnder interferometer and the Michelson interferometer are two-beam interferometers, the sensitivity of which to mechanical influences is the same throughout the entire sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Mach-Zehnder interferometer and the Michelson interferometer are unbalanced, with the lengths of the arms of the interferometers aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms, if necessary, being compensated by some optical delay line. Optionally, the optical delay line is a hardware delay line made by connecting the required length of reserve cores of a fiber optic cable into an optical circuit or made in the form of a coil of optical fiber.

[38] Thus, as a signaling method, a signaling method using a fiber-optic security detector 100 with a linear part with combined interferometers is claimed, in accordance with which: they provide placement of sensitive elements of the linear part of the fiber-optic security detector, which is a branched optical circuit, which, by means of splitters, couplings and fiber-optic cable, is placed on the fencing elements (on the canopy, and/or on the canvas, and/or on the anti-undermining fence), a laser pulse is generated from the output of the transceiver device to the input of the mentioned linear part and the returned pulses are received, which are reflection signals, to the input of the transceiver device along the same path, but in the opposite direction, and the linear part contains an optical circuit of combined interferometers for a fiber-optic security detector, containing closed and open circuits that generate reflection signals, which have the same segments optical fibers of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the applied physical effect, the same for both circuits, with the closed circuit being a Mach-Zehnder interferometer, and the open circuit being a Michelson interferometer, while recording the change in value the sum of reflection signals corresponding to the magnitude and nature of the elastic deformation of the sensitive elements. Optionally, the reflector splitters of the Mach-Zehnder interferometer and the adder splitter and reflector splitter of the Michelson interferometer are placed in one coupling. Optionally, the splitter-reflectors of the Mach-Zehnder interferometer and the splitter-adder and splitter-reflector of the Michelson interferometer are placed in different couplings. Optionally, a transceiver device is provided which is a reflectometer with a combined input and output. Optionally, a branched optical circuit is provided containing an optical delay line made by connecting into an optical circuit the required length of reserve cores of a fiber-optic cable or made in the form of a coil of optical fiber. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer based on the circulator is performed. Optionally, the dividers of the optical circuit of the Michelson interferometer are based on circulators or splitters. Optionally, a branched optical circuit is made with the ability to transmit reflection signals of the Mach-Zehnder interferometer after they are reflected in the opposite direction, where they are re-separation and pass through sections of the sensitive elements in the opposite direction with a change in the phase of the reflection signals, after which the summation of the reflection signals and their interference. Optionally, a branched optical circuit is configured with the ability to transmit the reflection signals of the Mach-Zehnder interferometer along a separate path to the transceiver device without modification. Moreover, they provide a Mach-Zehnder interferometer and a Michelson interferometer, which are two-beam interferometers, the sensitivity of which to mechanical influences is the same throughout the sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the difference the phases of the returned signals, and the change in the value of the sum of the reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector, while the Mach-Zehnder interferometer and the Michelson interferometer are not balanced, and the lengths of the interferometer arms are aligned with an acceptable error depending on the duration of the laser probing pulse, in this case, the length of one of the arms is, if necessary, compensated by any optical delay line.

[39] In FIG. Figure 2 shows an approximate functional diagram of a fiber-optic security detector 200, which uses an open-loop interferometer with two arms (two-beam Michelson interferometer). Preferably, without limitation, the proposed fiber optic security detector 200, which uses an open-loop interferometer with two arms (dual-beam Michelson interferometer) with reference to FIG. 2 contains at least: a transceiver device 201 containing a computing device and one or more reflectometers, including those with combined outputs of the signal emitter and receiver, to which the transport part 202 of the optical circuit of the detector is connected. Preferably, without limitation, the transport part 202 of the detector 200 consists of: sections of fiber-optic cable, connecting elements, laser pulse power divider 203, consisting of splitters that reduce the power of the laser pulse energy in the distributed optical circuit of the detector to the required level. Preferably, without limitation, the sensitive elements consist of: a splitter 204, dividing the energy of the probing pulse into two parts, sections 205, 206 of sensitive elements of a fiber-optic cable, splitters-reflectors 207, 208, and the Michelson interferometer is formed jointly by the splitter 204, cable sections 205 , 206 and splitter-reflectors 207, 208. Preferably, without limitation, splitters 204, 207, 208 can be placed either in one coupling or in different ones. Preferably, without limitation, the transport part contains several branches (at least in terms of the number of controlled zones and the applied optical circuit for dividing the energy of the probe pulse of the divider), which arrive at the input of the corresponding splitter 204, located in the corresponding coupling. By way of example, and not limitation, splitters 207, 208 may each be implemented using circulators. Preferably, without limitation, the open-loop optical circuit of a Michelson interferometer requires alignment of the length of the arms with an acceptable error, which, if necessary, is compensated by the duration of the probing pulse, or adjustment of the length of one of the arms by installing an additional optical delay line from a single-mode fiber. By way of example, and not limitation, the optical delay line can be a coil of single-mode fiber or other optical delay line, for example, but not limited to, made by connecting into an optical circuit the required length of redundant strands of a fiber optic cable.

[40] Such a fiber optic security detector 200 preferably, but not limited to, operates as follows. Preferably, without limitation, a short laser pulse is sent from the laser radiation source to the optical circuit at the input of the power divider of the transport part of the device, where the pulse power is divided into fractions. Preferably, without limitation, the divider is made of splitters with different degrees of division; the location of the splitters of the divider corresponds to the optical design of the device and is not strictly defined. Preferably, without limitation, the division of the energy of the probing pulse is carried out to the required power level in order to ensure the magnitude of the reflection signals from the two-beam Michelson interferometer of the sensitive part of the optical circuit of the device in the nominal range of the measurement scale of the receiving device. Preferably, without limitation, the time of arrival of the interfering signals at the input of the receiving device depends on the speed of propagation of laser radiation in the optical fiber material, on the lengths of the transport part and the sensitive part, including the length of the control coils. Preferably, without limitation, the magnitude of the reflection signals of the Michelson interferometer depends on the degree of signal attenuation in the optical fiber, the degree of division of the energy of the probing pulse in the transport part of the device, the magnitude of the phase shift of the returned signals of the sensitive part of the device associated with the difference in the shape and length of the pulse paths in the fiber to place of impact. Preferably, without limitation, the change in the value of the sum of the interferometer signals corresponds to the magnitude and nature of the elastic deformation of the sensitive part of the device arising from the dynamic impact of the intruder on the structure on which the sensitive part of the device is fixed. Preferably, without limitation, the optical design of each monitored area uses any reflectometric measurement method in any combination, including dual-beam Michelson interferometers. Preferably, without limitation, both pieces of optical fiber 205 and 206 are sensitive elements of the Michelson interferometer, the impact on which creates corresponding changes in the phase shift of the probing pulse, which reach the reflectors, optionally made on the splitters 207 and 208, and return back along the same path. paths in the cable sections of the sensitive elements 205 and 206, re-passing the place of influence on the sensitive element, reaching the splitter 204, where the reflected pulses are added, their interference and further movement in the opposite direction along the same path of the transport part and the divider to the receiving device. Preferably, without limitation, the sensitivity of the optical circuit of the Michelson interferometer to mechanical influences is the same throughout the sensitive part of the optical circuit, the magnitude of the reflection signal depends on the power of the emitter, the degree of division of the energy of the probing pulse, the initial value of the phase difference, and the change in the value of the sum of the reflection signals depends on the strength and characteristics of the impact on the sensitive part of the device. Preferably, without limitation, the open-loop optical circuit of the Michelson interferometer is an unbalanced two-beam Michelson interferometer, the method of obtaining signals is reflectometric; for the operation of the interferometer, it is preferable to align the length of the arms of the sensitive element with an acceptable error. Preferably, without limitation, to eliminate symmetrical effects on the optical fibers of the sensitive parts of the device of each controlled zone, which reduce the sensitivity of the device, optical cores of different arms are used in two different fiber-optic cables located on different parts of barriers and structures. Preferably, without limitation, addressing and assigning conventional numbers to sensitive parts of the device (controlled areas) is carried out by the computing device based on the arrival time of the Michelson interferometer signal. Preferably, without limitation, end-of-fiber sensors with static information and other controlled areas using other methods of generating a reflectometric response can be connected to any part of the optical circuit of the device along the length of the transport part.

[41] Preferably, without limitation, the described fiber-optic security detector 200, which uses an open-loop interferometer with two arms (double-beam Michelson interferometer), refers to technical security equipment in which a single-mode fiber-optic cable is used as a sensing element. Preferably, without limitation, the described device is intended for zonal organization of security lines. Preferably, without limitation, the described device can operate in conditions of increased industrial interference and natural influences and is intended for the protection of territories equipped with flexible mesh barriers, with canopies and tops made of reinforced razor tape or on barriers equipped with partially flexible and elastic elements, including a tunnel alarm . Preferably, without limitation, the proposed device is built using standard standard equipment used in fiber optic technology and special software. Preferably, without limitation, the proposed fiber optic multi-zone alarm device for protecting the perimeters of small and extended objects is based on the use of a highly sensitive effect of the dependence of the phase-polarization, amplitude and frequency characteristics of the magnitude of the returned signals of the Michelson interferometer, formed when part of the energy of the probing pulse of laser radiation passes through the optical fiber in forward and reverse directions, in the circuits of the optical circuit of the device, modulated by the physical influences of the intruder. Preferably, without limitation, the proposed device uses a reflectometric method to obtain reflection signals in order to determine their dynamic properties. Preferably, but not limited to, the reflection signals or return signals are received at the input of the receiving device sequentially and are separated from each other by the time of arrival. Preferably, without limitation, the addressing of return (reflection) signals from sensitive elements and optical sensors is carried out by an unambiguous correspondence between the range of placement of the sensitive element and the time of arrival of the reflection signal at the input of the receiving device. Preferably, without limitation, the reflection signals of Michelson interferometers from different sections of the optical circuit should arrive at the input of the receiving device at different times, this time is regulated by the length of the transport part, or an additional coil, or reserve fibers of the sensitive element, or another optical delay line, for example from reserve fibers transport part as described in this document.

[42] Thus, as the described fiber-optic security detector 200, which uses an open-ended interferometer with two arms, a fiber-optic security detector is claimed, which uses an open-ended interferometer with two arms, at least containing a station part with a transceiver device connected to the linear part of the said detector, wherein the linear part is a branched optical circuit based on splitters and a fiber-optic cable, which, through connecting couplings and a transport cable, connect the transceiver device and the sensitive elements of the security fiber-optic detector, containing an open a circuit that generates reflection signals, in which sections of optical fiber are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the applied physical effect, and the open circuit is a Michelson interferometer. Optionally, the Michelson interferometer splitters are housed in a single coupling. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, Michelson interferometer splitters are based on circulators or splitters. Optionally, the Michelson interferometer is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the entire sensitive part, and the value of the sum of the circuit reflection signals depends on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Michelson interferometer is unbalanced, with the lengths of the interferometer arms being aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms being compensated by some optical delay line.

[43] Thus, as another linear part, the linear part of the fiber optic security detector 200 is declared, which uses an open interferometer with two arms, which is a branched optical circuit based on splitters and a fiber optic cable, which, through connecting couplings and transport cables are connected to each other by a transceiver device and the sensitive elements of a fiber-optic security detector, containing an open circuit that generates reflection signals, in which sections of the optical fiber are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the physical impact provided, and the open circuit is a two-beam Michelson interferometer. Optionally, the Michelson interferometer splitters are housed in a single coupling. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, the separating elements of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, the Michelson interferometer is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the entire sensitive part, and the value of the sum of the circuit reflection signals depends on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Michelson interferometer is unbalanced, with the lengths of the interferometer arms being aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms being compensated by some optical delay line. Optionally, the optical delay line is an optical delay line made by connecting the required length of reserve cores of a fiber optic cable into an optical circuit or made in the form of a coil of optical fiber.

[44] Thus, as another coupling, the coupling of the fiber-optic security detector 200 is declared, which uses an open-loop interferometer with two arms, which is a coupling in which the optical circuit of the fiber-optic security detector is located, containing open-loop elements , which generates reflection signals of an open circuit, in which sections of the optical fiber cable are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the applied physical effect, and the open circuit is a two-beam Michelson interferometer. Optionally, the separating elements of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, the Michelson interferometer is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the entire sensitive part, and the value of the sum of the circuit reflection signals depends on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Michelson interferometer is unbalanced, with the lengths of the interferometer arms being aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms being compensated by some optical delay line. Optionally, the optical delay line is an optical delay line made by connecting the required length of reserve cores of a fiber optic cable into an optical circuit or made in the form of a coil of optical fiber.

[45] Thus, as another optical circuit, an optical circuit of a fiber-optic security detector 200 is claimed, which uses an open-loop interferometer with two arms, which is an open-loop interferometer for a fiber-optic security detector, implementing an optical circuit containing an open circuit that forms reflection signals, in which sections of optical fiber are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the applied physical effect, and the open circuit is a Michelson interferometer. Optionally, the separating elements of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, the Michelson interferometer is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the sensitive part, and the value of the sum of the circuit reflection signals depends on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Michelson interferometer is unbalanced, with the lengths of the arms of the interferometer aligned with an acceptable error depending on the duration of the laser probing pulse, while the length of one of the arms is compensated by some kind of optical delay line. Optionally, the optical delay line is a hardware delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber.

[46] Thus, as another signaling method, a signaling method using a fiber-optic security detector 200 with a linear part with an open interferometer with two arms is claimed, according to which: they provide placement of the sensitive elements of the linear part of the fiber-optic security detector, which is a branched optical circuit, which is placed on the fencing elements (on the canopy, and/or canvas, and/or on the anti-undermining barrier) using splitters, connecting couplings and fiber-optic cables), a laser pulse is generated from the output of the transceiver device to the input of the mentioned linear part and obtain the returned pulse, which is a reflection signal, to the input of the transceiver device along the same path, but in the opposite direction, and the linear part contains an optical circuit of an open interferometer for a fiber-optic security detector, containing an open circuit that generates reflection signals, in which sections of the optical fiber are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the applied physical impact, while the change in the magnitude of the reflection signal corresponding to the magnitude and nature of the elastic deformation of the sensitive elements is recorded. Optionally, Michelson interferometer splitters are placed in the coupling. Optionally, a branched optical circuit is provided containing an optical delay line made by connecting into an optical circuit the required length of reserve cores of a fiber-optic cable or made in the form of a coil of optical fiber. Optionally, the dividers of the optical circuit of the Michelson interferometer are based on circulators or splitters. Optionally, a Michelson interferometer is provided, which is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the entire sensitive part, and the value of the sum of the circuit reflection signals depends on the power of the emitter, the magnitude of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change The magnitude of the sum of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, an unbalanced Michelson interferometer is provided, and the lengths of the interferometer arms are aligned with an acceptable error depending on the duration of the laser probing pulse, while the length of one of the arms is compensated by some optical delay line.

[47] In FIG. Figure 3 shows a functional diagram of the controlled zone of a fiber-optic security detector, which uses an interferometer with two arms (two-beam Mach-Zehnder interferometer). Preferably, without limitation, the proposed fiber optic security detector 300, which uses a two-arm interferometer (dual-beam Mach-Zehnder interferometer) with reference to FIG. 3 contains at least: a transceiver device 301 containing a computing device and one or more reflectometers, including those with combined outputs of the signal emitter and receiver, to which the transport part 302 of the optical circuit of the detector is connected. Preferably, without limitation, the transport part 302 of the detector 300 consists of: sections of fiber-optic cable, connecting elements, laser pulse power divider 303, consisting of splitters that reduce the power of the laser pulse energy in the distributed optical circuit of the detector to the required level. Preferably, without limitation, the sensing elements consist of: a splitter 304, dividing the energy of the probing pulse into two parts, sections 305, 306 of the sensing elements of the fiber-optic cable, the adder splitter 307 and the reflector splitter 308, and the Mach-Zehnder interferometer is formed jointly by the splitter 304, cable sections 305, 306 and splitters 307, 308. Preferably, without limitation, splitters 304, 307, 308 can be placed either in one coupling or in different ones. Preferably, without limitation, the transport part contains several branches (at least in terms of the number of controlled zones and the applied optical circuit for dividing the energy of the probe pulse of the divider), which arrive at the input of the corresponding splitter 304, located in the corresponding coupling. By way of example, and not limitation, splitters 307, 308 may each be implemented using circulators. Preferably, without limitation, the branched optical circuit of the Mach-Zehnder interferometer is configured to generate interference signals in the forward direction. Preferably, without limitation, the branched optical circuit is configured to reflect in the reverse direction the interference signals generated by the Mach-Zehnder interferometer in the forward direction, where they are re-separation and pass through the segments of the sensitive elements in the reverse direction with a repeated change in the phase of the signals, after which it is ensured final addition of reflection signals, their interference and transmission to the receiving device. Preferably, without limitation, the signal generated by the Mach-Zehnder interferometer in the forward direction is transmitted in a branched optical circuit along a separate path to the transceiver device. Preferably, without limitation, the open-loop optical circuit of a Mach-Zehnder interferometer requires alignment of the length of the arms with an acceptable error, which, if necessary, is compensated by the duration of the probing pulse, or adjustment of the length of one of the arms by installing an additional optical delay line from a single-mode fiber. By way of example, and not limitation, the optical delay line can be a coil of single-mode fiber or other optical delay line, for example, but not limited to, made by connecting into an optical circuit the required length of redundant strands of a fiber optic cable.

[48] Such a fiber optic security detector 300 preferably, but not limited to, operates as follows. Preferably, without limitation, a short laser pulse is sent from the laser radiation source to the optical circuit at the input of the power divider of the transport part of the device, where the pulse power is divided into fractions. Preferably, without limitation, the divider is made of splitters with different degrees of division; the location of the splitters of the divider corresponds to the optical design of the device and is not strictly defined. Preferably, without limitation, the division of the energy of the probing pulse is carried out to the required power level in order to ensure the magnitude of the reflection signals of the Mach-Zehnder interferometer from the sensitive part of the optical circuit of the device in the nominal range of the measurement scale of the receiving device. Preferably, without limitation, the time of arrival of the interfering signals at the input of the receiving device depends on the speed of propagation of laser radiation in the optical fiber material, on the length of the transport part and the length of the sensitive part, including the length of the control coils. Preferably, without limitation, the magnitude of the reflection signals of the Mach-Zehnder interferometer depends on the degree of signal attenuation in the optical fiber, the degree of division of the energy of the probing pulse in the transport part of the device, the magnitude of the phase shift of the returned signals of the sensitive part of the device associated with the difference in the shape and length of the pulse paths in fiber to the point of impact. Preferably, without limitation, the change in the value of the sum of the interferometer signals corresponds to the magnitude and nature of the elastic deformation of the sensitive part of the device arising from the dynamic impact of the intruder on the structure on which the sensitive part of the device is fixed. Preferably, without limitation, the optical design of each monitored zone uses any reflectometric measurement method in any combination, including the method of two-beam interferometers, in particular the Mach-Zehnder interferometer method. Preferably, without limitation, the same sections of the optical fiber of the cable are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the applied physical impact. Preferably, without limitation, the sensitivity of the optical circuit of the Mach-Zehnder interferometer to mechanical influences is the same throughout the sensitive part of the optical circuit, the magnitude of the reflection signal depends on the power of the emitter, the initial value of the phase difference, and the change in the value of the sum of reflection signals depends on the strength and characteristics of the impact on sensitive part of the device. Preferably, without limitation, the circuit of the optical circuit of the Mach-Zehnder interferometer is an unbalanced two-beam Mach-Zehnder interferometer, the method of obtaining signals is reflectometric; for the operation of the interferometer it is also preferable to align the length of the arms of the sensitive element with an acceptable error. Preferably, without limitation, the probing pulse in the Mach-Zehnder interferometer in the proposed optical design separates the signals at the splitter 304, passes through the fiber segments 305 and 306 of the sensitive elements, adds and interferes with the signals at the splitter 307, reflects the signals in the opposite direction at the splitter 308, repeated passage of the signal through the splitter 307, separation of the signals and following in the opposite direction in segments 305 and 306 and final addition on the splitter 304 when following in the opposite direction, at the output of the splitter 304, a combined signal of interfering reflections is formed, which then arrives at the input of the signal receiver . Preferably, without limitation, to eliminate symmetrical effects on the optical fibers of the sensitive parts of the device of each controlled zone, which reduce the sensitivity of the device, optical cores of different arms are used in two different fiber-optic cables located on different parts of barriers and structures. Preferably, without limitation, the addressing and assignment of conditional numbers to the sensitive parts of the device (controlled areas) is carried out by the computing device based on the arrival time of the reflection signal of the Mach-Zehnder interferometer. Preferably, without limitation, end-of-fiber sensors with static information and other controlled areas using other methods of generating a reflectometric response can be connected to any part of the optical circuit of the device along the length of the transport part.

[49] Preferably, without limitation, the described fiber-optic security detector 300, which uses an interferometer with two arms, refers to technical security equipment in which a single-mode fiber-optic cable is used as a sensing element. Preferably, without limitation, the described device is intended for zonal organization of security lines. Preferably, without limitation, the described device can operate in conditions of increased industrial interference and natural influences and is intended for the protection of territories equipped with flexible mesh barriers, with canopies and tops made of reinforced razor tape or on barriers equipped with partially flexible and elastic elements, including a tunnel alarm . Preferably, without limitation, the proposed device is built using standard standard equipment used in fiber optic technology and special software. Preferably, without limitation, the proposed fiber-optic multi-zone alarm device for protecting the perimeters of small and extended objects (fiber-optic security detector) is based on the use of the highly sensitive effect of the dependence of the phase-polarization, amplitude and frequency characteristics of the magnitude of the returned signals of the Mach-Zehnder interferometer generated during the passage of a part energy of the probing pulse of laser radiation through the optical fiber in the forward and reverse directions, in the circuits of the optical circuit of the device, modulated by the physical influences of the intruder. Preferably, without limitation, the proposed device uses a reflectometric method to obtain reflection signals in order to determine their dynamic properties. Preferably, but not limited to, the reflection signals or return signals are received at the input of the receiving device sequentially and are separated from each other by the time of arrival. Preferably, without limitation, the addressing of return (reflection) signals from sensitive elements and optical sensors is carried out by an unambiguous correspondence between the range of placement of the sensitive element and the time of arrival of the reflection signal at the input of the receiving device. Preferably, but not limited to, the reflection signals of the Mach-Zehnder interferometer should arrive at the input of the receiving device at different times, this time being controlled by the length of the sensing element, or an additional coil, or redundant fibers of the sensing element, or other optical delay line, as described herein .

[50] Thus, as the described fiber-optic security detector 300, which uses an open interferometer with two arms, a fiber-optic security detector is claimed, which uses a closed interferometer with two arms, at least containing a station part with a transceiver device connected to the linear part of the said detector, wherein the linear part is a branched optical circuit based on splitters and a fiber-optic cable, which, through connecting couplings and a transport cable, connect the transceiver device and the sensitive elements of the security fiber-optic detector, containing a closed circuit a circuit that generates reflection signals, in which sections of optical fiber are sensitive elements of the interferometer and create a phase shift of the probing pulse for the circuit, wherein the closed circuit is a Mach-Zehnder interferometer. Optionally, the Mach-Zehnder interferometer splitters are located in the coupling. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the Mach-Zehnder interferometer is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the entire sensitive part, and the value of the sum of the contour reflection signals depends on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value the amount of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Mach-Zehnder interferometer is unbalanced, with the lengths of the interferometer arms aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms being compensated by some kind of optical delay line. Optionally, the branched optical circuit of the Mach-Zehnder interferometer is configured to generate interference signals in the forward direction. Optionally, the branched optical circuit is configured to reflect in the opposite direction the interference signals generated by the Mach-Zehnder interferometer in the forward direction, where they are re-separation and pass through sections of the sensitive elements in the opposite direction with a repeated change in the phase of the signals, after which the final addition of the signals is ensured reflections, their interference and travel to the receiving device. Optionally, the signal generated by the Mach-Zehnder interferometer in the forward direction is transmitted in a branched optical circuit along a separate path to the transceiver device.

[51] Thus, as another linear part, the linear part of the fiber-optic security detector 300 is claimed, which uses an interferometer with two arms, which is a branched optical circuit based on splitters and a fiber-optic cable, which are connected through connecting couplings and a transport cable interconnect the transceiver device and the sensitive elements of the security fiber-optic detector, containing a closed loop that generates reflection signals, in which sections of the optical fiber are sensitive elements of the interferometer and create a phase shift of the probing pulse for the loop, and the closed loop is a Mach-Zehnder interferometer. Optionally, the Mach-Zehnder interferometer splitters are located in the coupling. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the Mach-Zehnder interferometer is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the sensitive part, and the value of the sum of the contour reflection signals depends on the power of the emitter, the magnitude of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change The magnitude of the sum of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Mach-Zehnder interferometer is unbalanced, with the lengths of the interferometer arms aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms being compensated by some kind of optical delay line. Optionally, the branched optical circuit of the Mach-Zehnder interferometer is configured to generate interference signals in the forward direction. Optionally, the branched optical circuit is configured to reflect in the opposite direction the interference signals generated by the Mach-Zehnder interferometer in the forward direction, where they are re-separation and pass through sections of the sensitive elements in the opposite direction with a repeated change in the phase of the signals, after which the final addition of the signals is ensured reflections, their interference and travel to the receiving device. Optionally, the signal generated by the Mach-Zehnder interferometer in the forward direction is transmitted in a branched optical circuit along a separate path to the transceiver device.

[52] Thus, as another coupling, the coupling of the fiber-optic security detector 300 is claimed, which includes a closed interferometer with two arms, which is a coupling in which the optical circuit of the fiber-optic security detector is located, containing a closed circuit, forming a reflection signal, in which sections of the optical fiber of the cable are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the applied physical effect, and the closed loop is a Mach-Zehnder interferometer. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the Mach-Zehnder interferometer is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the sensitive part, and the value of the sum of the contour reflection signals depends on the power of the emitter, the magnitude of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change The magnitude of the sum of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Mach-Zehnder interferometer is unbalanced, with the lengths of the interferometer arms aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms being compensated by some kind of optical delay line. Optionally, the optical delay line is an optical delay line made by connecting the required length of reserve cores of a fiber optic cable into an optical circuit or made in the form of a coil of optical fiber.

[53] Thus, as another optical circuit, an optical circuit of a fiber-optic security detector 300 is claimed, which uses a closed interferometer with two arms, which is a closed interferometer for a fiber-optic security detector, implementing an optical circuit containing a closed circuit that forms a reflection signal, in which the same sections of optical fiber of the cable are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the physical effect exerted, and the closed loop is a Mach-Zehnder interferometer. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the Mach-Zehnder interferometer is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the entire sensitive part, and the value of the sum of the contour reflection signals depends on the power of the emitter, the magnitude of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change The magnitude of the sum of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Mach-Zehnder interferometer is unbalanced, with the lengths of the interferometer arms being aligned with an acceptable error depending on the duration of the laser probing pulse, with the length of one of the arms being compensated by some kind of optical delay line. Optionally, the optical delay line is an optical delay line made by connecting the required length of reserve cores of a fiber optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, the branched optical circuit of the Mach-Zehnder interferometer is configured to generate interference signals in the forward direction. Optionally, the branched optical circuit is configured to reflect in the reverse direction the interference signals generated by the Mach-Zehnder interferometer in the forward direction, where they are re-separation and pass through sections of the sensitive elements in the opposite direction with a repeated change in the phase of the signals, after which the final addition of the signals is ensured reflections, their interference and travel to the receiving device. Optionally, the signal generated by the Mach-Zehnder interferometer in the forward direction is transmitted in a branched optical circuit along a separate path to the transceiver device.

[54] Thus, as another signaling method, a signaling method using a fiber-optic security detector 300 with a linear part with a closed interferometer with two arms is claimed, according to which: they provide placement of the sensitive elements of the linear part of the fiber-optic security detector, which is a branched optical circuit, which is placed on the fencing elements (on the canopy, and/or canvas, and/or on the anti-undermining barrier) using splitters, connecting couplings and fiber-optic cables), a laser pulse is generated from the output of the transceiver device to the input of the mentioned linear part and obtain the returned pulse, which is a reflection signal, to the input of the transceiver along the same path, but in the opposite direction, and the linear part contains an optical circuit of a closed interferometer for a fiber-optic security detector, containing a closed circuit that generates a reflection signal, in which sections of optical fiber cable are sensitive elements of the interferometer, in which a phase shift of the probing pulse is created in accordance with the applied physical impact, and the closed loop is a Mach-Zehnder interferometer, while the change in the magnitude of the reflection signal corresponding to the magnitude and nature of the elastic deformation of the sensitive elements is recorded. Optionally, the Mach-Zehnder interferometer splitters are placed in the coupling. Optionally, a branched optical circuit is provided containing a hardware delay line made by connecting into an optical circuit the required length of reserve cores of a fiber-optic cable or made in the form of a coil of optical fiber. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer based on the circulator is performed. Optionally, a Mach-Zehnder interferometer is provided, which is a two-beam interferometer, the sensitivity of which to mechanical influences is the same throughout the sensitive part, and the value of the sum of the circuit reflection signals depends on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, an unbalanced Mach-Zehnder interferometer is provided, and the lengths of the interferometer arms are aligned with an acceptable error depending on the duration of the laser probing pulse, while the length of one of the arms is compensated by some optical delay line. Optionally, the branched optical circuit of the Mach-Zehnder interferometer is configured to generate interference signals in the forward direction. Optionally, the branched optical circuit is made with the ability to reflect in the reverse direction the interference signals generated by the Mach-Zehnder interferometer in the forward direction, where they are re-separation and pass through sections of the sensitive elements in the opposite direction with a repeated change in the phase of the signals, after which the final addition of the signals is ensured reflections, their interference and travel to the receiving device. Optionally, the signal generated by the Mach-Zehnder interferometer is transmitted in the forward direction in a branched optical circuit along a separate path to the transceiver device.

[55] In FIG. Figure 4 shows a functional diagram of a fiber-optic security detector, which uses combined interferometers. Preferably, without limitation, the proposed fiber optic security detector 400, which uses combined interferometers, with reference to FIG. 4 contains at least: a transceiver device 401 containing a computing device and one or more reflectometers, including those with combined outputs of the signal emitter and receiver, to which the transport part 402 of the optical circuit of the detector is connected. Preferably, without limitation, the transport part 402 of the detector 400 consists of: sections of fiber-optic cable, connecting elements, laser pulse power divider 403, consisting of splitters that reduce the power of the laser pulse energy in the distributed optical circuit of the detector to the required level. Preferably, without limitation, the sensitive elements consist of: a splitter 404, dividing the energy of the probing pulse into two parts, sections 405, 406 of sensitive elements of a fiber-optic cable, splitters 407-410, and the Sagnac interferometer is formed jointly by a splitter 404, cable sections 405, 406 , splitters 407, 408, coil 411, the Mach-Zehnder interferometer is formed jointly by splitter 404, cable sections 405, 406, splitter-adder 409 and splitter-reflector 410. Preferably, without limitation, the splitter 404 and the ends of the cable sections of the sensing elements are placed in one coupling, and the interferometer splitters are in another coupling or in several couplings. For example, without limitation, the Sagnac interferometer splitters 407, 408 may be located in one other coupler, and the combiner splitter 409 and the Mach-Zehnder interferometer splitter-reflector 410 can be housed in yet another coupler. Preferably, without limitation, the transport part contains several branches (at least in terms of the number of controlled zones and the applied optical circuit for dividing the energy of the probe pulse of the divider), which arrive at the input of the corresponding splitter 404, located in the corresponding coupling. As an example, but not limitation, any optical delay line 411 can be used as part of the fiber optic security detector 400, for example, but not limited to, made by connecting into an optical circuit the required length of the reserve cores of the fiber optic cable, or made in the form optical fiber reels.

[56] Such a fiber optic security detector 400 preferably, but not limited to, operates as follows. Preferably, without limitation, a short laser pulse is supplied from the laser radiation source to the optical circuit at the input of the power divider of the transport part of the device, where the pulse power is divided into fractions. Preferably, without limitation, the divider is made of splitters with different degrees of division; the location of the splitters of the divider corresponds to the optical design of the device and is not strictly defined. Preferably, without limitation, the energy division of the probing pulse is carried out to the required power level in order to ensure the magnitude of the reflection signals of, respectively, the Sagnac interferometer and the Mach-Zehnder interferometer from the sensitive part of the optical circuit of the device in the nominal range of the measurement scale of the receiving device. Preferably, without limitation, the time of arrival of the interfering signals at the input of the receiving device depends on the speed of propagation of laser radiation in the optical fiber material, on the length of the transport part and the length of the sensitive part, including the length of the control coils. Preferably, without limitation, the magnitude of the reflection signals, respectively, of the Sagnac interferometer and the Mach-Zehnder interferometer depends on the degree of signal attenuation in the optical fiber, the degree of division of the energy of the probing pulse in the transport part of the device, the magnitude of the phase shift of the returned signals of the sensitive part of the device associated with the shape difference and the length of the paths of movement of impulses in the fiber to the place of impact. Preferably, without limitation, the change in the magnitude of the sums of interferometer signals corresponds to the magnitude and nature of the elastic deformation of the sensitive part of the device arising from the dynamic impact of the intruder on the structure on which the sensitive part of the device is fixed. Preferably, without limitation, the optical design of each monitored zone uses any reflectometric measurement method, in any combination, including the method of combined interferometers, including the method of two-beam Sagnac and Mach-Zehnder interferometers, and contains, respectively, Sagnac interferometer circuits and Mach-Zehnder interferometer. Preferably, without limitation, the same sections of optical fibers of the cable are sensitive elements of interferometers, in which a phase shift of the probing pulse is created in accordance with the applied physical impact. Preferably, without limitation, the sensitivity of the optical circuit of the Mach-Zehnder interferometer to mechanical influences is the same throughout the sensitive part of the optical circuit, the magnitude of the reflection signal depends on the power of the emitter, the initial value of the phase difference, and the change in the value of the sum of reflection signals depends on the strength and characteristics of the impact on sensitive part of the device. Preferably, without limitation, the circuit of the optical circuit is an unbalanced two-beam Mach-Zehnder interferometer, a reflectometric method of obtaining signals, for which it is preferable to align the lengths of the interferometer arms with an acceptable error within the limits of the duration of propagation of the probing pulse, and if necessary, the length of one of the arms is compensated by installing an additional coils of single-mode fiber, or using a serial optical chain of the required length from the reserve cores of the fiber-optic cable. Preferably, without limitation, the probing pulse in the Mach-Zehnder interferometer in the proposed optical design twice separates and combines the interfering signals. Preferably, but not limited to, the sensitivity of the optical circuit of the Sagnac interferometer to mechanical influences is maximum at the beginning of the optical ring (at the side of the splitter 404) in any direction and is significantly insensitive at the farthest end of the optical ring (at the middle of the ring on the coil 411), with the sensitivity of the optical ring gradually decreasing from the beginning of the ring to the middle of the ring of the sensitive part, the value of the sum of interfering reflection signals depends on the power of the emitter, the initial value of the phase difference of the returned signals, and the change in the value of the sum of interfering reflection signals depends on the location, strength and dynamic characteristics of the impact on the sensitive part of the Sagnac interferometer. The output reflection signals of the Mach-Zehnder interferometer and the Sagnac interferometer are generated at the output of the splitter 404 in the reverse direction with a time delay determined by the length of the optical delay line 411 (coil 411 or other optical delay line) installed in the optical ring of the Sagnac interferometer. To delay the reflection signal of the closed circuit of the Sagnac interferometer relative to the reflection signal of the Mach-Zehnder interferometer, an adjusting coil 411 is installed, the length of which is calculated based on the condition: the signal delay time must be no less than the duration of the probing pulse. By way of example, and not limitation, another optical delay line may be used in place of coil 411, for example, but not limited to, made by connecting into an optical chain the required length of redundant fiber optic cable strands. Preferably, without limitation, to eliminate symmetrical effects on the optical fibers of the sensitive parts of the device of each controlled zone, which reduce the sensitivity of the device, optical cores of different arms are used in two different fiber-optic cables located on different parts of barriers and structures. Preferably, without limitation, the addressing and assignment of conventional numbers to the sensitive parts of the device (controlled areas) is carried out by the computing device based on the arrival time of two signals, respectively, the Sagnac interferometer and the Mach-Zehnder interferometer. Preferably, without limitation, other sensitive elements with a different optical circuit using the reflectometric measurement method in various combinations, as well as end-of-fiber sensors with static information, can be connected to any part of the optical circuit of the device along the length of the transport part.

[57] Preferably, without limitation, the described fiber-optic security detector 400, which uses combined interferometers, refers to technical security equipment in which a single-mode fiber-optic cable is used as a sensitive element. Preferably, without limitation, the described device is intended for zonal organization of security lines. Preferably, without limitation, the described device can operate in conditions of increased industrial interference and natural influences and is intended for the protection of territories equipped with flexible mesh barriers, with canopies and tops made of reinforced razor tape or on barriers equipped with partially flexible and elastic elements, including a tunnel alarm . Preferably, without limitation, the proposed device is built using standard standard equipment used in fiber optic technology and special software. Preferably, without limitation, the proposed fiber optic multi-zone alarm device for protecting the perimeters of small and extended objects is based on the use of a highly sensitive effect of the dependence of the phase-polarization, amplitude and frequency characteristics of the magnitude of the returned signals of the Sagnac interferometer and the Mach-Zehnder interferometer, formed during the passage of part of the energy of the laser probing pulse radiation through an optical fiber in the forward and reverse directions, in the circuits of the optical circuit of the device, modulated by the physical influences of the intruder. Preferably, without limitation, the proposed device uses a reflectometric method for obtaining reflection signals in order to determine their dynamic properties and localize the impact location within the controlled area. Preferably, but not limited to, the reflection signals or return signals are received at the input of the receiving device sequentially and are separated from each other by the time of arrival. Preferably, without limitation, the addressing of return (reflection) signals from sensitive elements and optical sensors is carried out by an unambiguous correspondence between the range of placement of the sensitive element and the time of arrival of the reflection signal at the input of the receiving device. Preferably, but not limited to, the reflection signals of the Sagnac interferometer and the Mach-Zehnder interferometer should arrive at the input of the receiving device at different times, this time being controlled by the length of the sensing element, or an additional coil, or redundant fibers of the sensing element, or other optical delay line, as described in this document.

[58] Thus, the described fiber-optic security detector 400, which uses combined interferometers, is a fiber-optic security detector, which uses combined interferometers, at least containing a station part with a transceiver device connected to a linear part of the mentioned detector, and the linear part is a branched optical circuit based on splitters and a fiber-optic cable, which, through connecting couplings and a transport cable, connect the transceiver device and the sensitive elements of the security fiber-optic detector, containing closed circuits that generate reflection signals, in which the same sections of optical fiber of the cable are sensitive elements of interferometers, in which a phase shift of the probing pulse is created in accordance with the applied physical effect, identical for both circuits, with one closed circuit being a Mach-Zehnder interferometer, and the other closed circuit representing is a Sagnac interferometer. Optionally, the combiner splitter and reflector splitter of the Mach-Zehnder interferometer and the Sagnac interferometer splitters are placed in the same coupling. Optionally, the combiner splitter and reflector splitter of the Mach-Zehnder interferometer and the splitters of the Sagnac interferometer are placed in different couplings. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line, made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit, or made in the form of a coil of optical fiber. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the branched optical circuit of the Mach-Zehnder interferometer is configured to generate interference signals in the forward direction. Optionally, the branched optical circuit is configured to reflect in the opposite direction the interference signals generated by the Mach-Zehnder interferometer in the forward direction, where they are re-separation and pass through sections of the sensitive elements in the opposite direction with a repeated change in the phase of the signals, after which the final addition of the signals is ensured reflections, their interference and travel to the receiving device. Optionally, the signal generated by the Mach-Zehnder interferometer in the forward direction is transmitted in a branched optical circuit along a separate path to the transceiver device. Moreover, the Mach-Zehnder interferometer and the Sagnac interferometer are two-beam interferometers, and the sensitivity of the optical circuit of the Mach-Zehnder interferometer to mechanical influences is the same throughout the sensitive part, and the sensitivity of the optical circuit of the Sagnac interferometer to mechanical influences is maximum at the beginning of the optical ring of any direction and significantly insensitive at the farthest end of the optical ring (in the middle of the ring), and the sensitivity of the optical ring gradually decreases from the beginning of the ring to the middle of the ring of the sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the difference phases of the returned signals, and the change in the value of the sum of the reflection signals depends on the strength, the dynamic characteristics of the impact on the sensitive part of the detector and for the Sagnac interferometer - on the location of the impact on the sensitive part of the detector, while the Mach-Zehnder interferometer is not balanced, and the length of the arms of the Mach-Zehnder interferometer aligned with a permissible error depending on the duration of the laser probing pulse, while the length of one of the arms is, if necessary, compensated by any optical delay line.

[59] Thus, as another linear part, the linear part of the fiber-optic security detector 400 is declared, which uses combined interferometers, which is a branched optical circuit based on splitters and a fiber-optic cable, which are connected between is a transceiver device and sensitive elements of a fiber-optic security detector, containing closed circuits that generate reflection signals, in which the same sections of optical fiber of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the provided physical impact, the same for both loops, with one closed loop being a Mach-Zehnder interferometer and the other closed loop being a Sagnac interferometer. Optionally, the splitter-adder and splitter-reflector of the Mach-Zehnder interferometer and the splitters of the Sagnac interferometer are placed in one coupling. Optionally, the splitter-adder and splitter-reflector of the Mach-Zehnder interferometer and the splitters of the Sagnac interferometer are placed in different couplings. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line, made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit, or made in the form of a coil of optical fiber. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Optionally, the branched optical circuit of the Mach-Zehnder interferometer is configured to generate interference signals in the forward direction. Optionally, the branched optical circuit is configured to reflect in the opposite direction the interference signals generated by the Mach-Zehnder interferometer in the forward direction, where they are re-separation and pass through sections of the sensitive elements in the opposite direction with a repeated change in the phase of the signals, after which the final addition of the signals is ensured reflections, their interference and travel to the receiving device. Optionally, the signal generated by the Mach-Zehnder interferometer in the forward direction is transmitted in a branched optical circuit along a separate path to the transceiver device. Moreover, the Mach-Zehnder interferometer and the Sagnac interferometer are two-beam interferometers, and the sensitivity of the optical circuit of the Mach-Zehnder interferometer to mechanical influences is the same throughout the sensitive part, and the sensitivity of the optical circuit of the Sagnac interferometer to mechanical influences is maximum at the beginning of the optical ring of any direction and significantly insensitive at the farthest end of the optical ring (in the middle of the ring), and the sensitivity of the optical ring gradually decreases from the beginning of the ring to the middle of the ring of the sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the difference phases of the returned signals, and the change in the value of the sum of the reflection signals depends on the strength, the dynamic characteristics of the impact on the sensitive part of the detector and for the Sagnac interferometer - on the location of the impact on the sensitive part of the detector, while the Mach-Zehnder interferometer is not balanced, and the length of the arms of the Mach-Zehnder interferometer aligned with a permissible error depending on the duration of the laser probing pulse, while the length of one of the arms is, if necessary, compensated by any optical delay line.

[60] Thus, as another coupling, the coupling of the fiber-optic security detector 400, which uses combined interferometers, is declared, which is a coupling in which the optical circuit of the fiber-optic security detector is located, containing elements of closed circuits that generate signals reflections in which the same sections of optical fiber of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the physical effect exerted, identical for both circuits, with one closed circuit being a Mach-Zehnder interferometer, and the other closed the circuit is a Sagnac interferometer. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Moreover, the Mach-Zehnder interferometer and the Sagnac interferometer are two-beam interferometers, and the sensitivity of the optical circuit of the Mach-Zehnder interferometer to mechanical influences is the same throughout the sensitive part, and the sensitivity of the optical circuit of the Sagnac interferometer to mechanical influences is maximum at the beginning of the optical ring of any direction and is significantly insensitive at the farthest end of the optical ring (in the middle of the ring), and the sensitivity of the optical ring gradually decreases from the beginning of the ring to the middle of the ring of the sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference returned signals, and the change in the sum of the reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Mach-Zehnder interferometer is not balanced, and the lengths of the arms of the Mach-Zehnder interferometer are aligned with an acceptable error depending on the duration of the laser probing pulse, while the length of one of the arms is, if necessary, compensated by some optical delay line. Optionally, the optical delay line is an optical delay line made by connecting the required length of reserve cores of a fiber optic cable into an optical circuit or made in the form of a coil of optical fiber.

[61] Thus, as another optical circuit, an optical circuit of a fiber-optic security detector 400 is claimed, which uses combined interferometers, which are combined interferometers for a fiber-optic security detector, implementing an optical circuit containing closed circuits that generate reflection signals, in which the same sections of optical fiber of the cable are sensitive elements of interferometers, in which a phase shift of the probing pulse is created in accordance with the applied physical effect, identical for both circuits, with one closed circuit being a Mach-Zehnder interferometer, and the other closed circuit representing is a Sagnac interferometer. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is made on the basis of a circulator. Moreover, the Mach-Zehnder interferometer and the Sagnac interferometer are two-beam interferometers, and the sensitivity of the optical circuit of the Mach-Zehnder interferometer to mechanical influences is the same throughout the sensitive part, and the sensitivity of the optical circuit of the Sagnac interferometer to mechanical influences is maximum at the beginning of the optical ring of any direction and significantly insensitive at the farthest end of the optical ring (in the middle of the ring), and the sensitivity of the optical ring gradually decreases from the beginning of the ring to the middle of the ring of the sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the difference phases of the returned signals, and the change in the value of the sum of the reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Optionally, the Mach-Zehnder interferometer is not balanced, and the lengths of the arms of the Mach-Zehnder interferometer are aligned with an acceptable error depending on the duration of the laser probing pulse, while the length of one of the arms is, if necessary, compensated by some optical delay line. Optionally, the optical delay line is an optical delay line made by connecting the required length of reserve cores of a fiber optic cable into an optical circuit or made in the form of a coil of optical fiber.

[62] Thus, as another signaling method, a signaling method using a fiber-optic security detector 400 with a linear part with combined interferometers is claimed, in accordance with which: the placement of sensitive elements of the linear part of the fiber-optic security detector, which is a branched optical circuit, is provided , which is placed on the fencing elements (on the canopy, and/or on the canvas, and/or on the anti-undermining fence) using splitters, connecting couplings and fiber-optic cables), a laser pulse is formed from the output of the transceiver device to the input of the mentioned linear part and the returned pulses are received , which are reflection signals, to the input of the transceiver device along the same path, but in the opposite direction, and the linear part contains an optical circuit of combined interferometers for a fiber-optic security detector, containing closed circuits that generate reflection signals, which have the same sections of optical cable fibers are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the applied physical effect, identical for both circuits, with one closed circuit being a Mach-Zehnder interferometer, and the other closed circuit being a Sagnac interferometer, and the change is recorded the magnitude of the sum of reflection signals, corresponding to the magnitude and nature of the elastic deformation of the sensitive elements. Optionally, the splitter-adder and splitter-reflector of the Mach-Zehnder interferometer and the splitters of the Sagnac interferometer are placed in one coupling. Optionally, the splitter-adder and splitter-reflector of the Mach-Zehnder interferometer and the splitters of the Sagnac interferometer are placed in different couplings. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, one of the splitters of the optical circuit of the Mach-Zehnder interferometer is based on a circulator. Optionally, the branched optical circuit of the Mach-Zehnder interferometer is configured to generate interference signals in the forward direction. Optionally, the branched optical circuit is configured to reflect in the reverse direction the interference signals generated by the Mach-Zehnder interferometer in the forward direction, where they are re-separation and pass through sections of the sensitive elements in the opposite direction with a repeated change in the phase of the signals, after which the final addition of the signals is ensured reflections, their interference and travel to the receiving device. Optionally, the signal generated by the Mach-Zehnder interferometer in the forward direction is transmitted in a branched optical circuit along a separate path to the transceiver device. Moreover, they provide a Mach-Zehnder interferometer and provide a Sagnac interferometer, which are two-beam interferometers, and the sensitivity of the optical circuit of the Mach-Zehnder interferometer to mechanical influences is the same throughout the sensitive part, and the sensitivity of the optical circuit of the Sagnac interferometer to mechanical influences is maximum at the beginning of the optical ring of any direction and is significantly insensitive at the farthest end of the optical ring (in the middle of the ring), and the sensitivity of the optical ring gradually decreases from the beginning of the ring to the middle of the ring of the sensitive part, and the values of the sums of the reflection signals of the interferometer circuits depend on the power of the emitter, the value of the branched fraction of the energy of the probing pulse, the initial value of the phase difference of the returned signals, and the change in the value of the sum of the reflection signals depends on the strength, the dynamic characteristics of the impact on the sensitive part of the detector and for the Sagnac interferometer - on the location of the impact on the sensitive part of the detector, while the Mach-Zehnder interferometer is not balanced, and the length of the interferometer arms The Mach-Zehnders are aligned with a permissible error depending on the duration of the laser probing pulse, while the length of one of the arms is, if necessary, compensated by some kind of optical delay line.

[63] In FIG. Figure 5 shows an approximate functional diagram of a fiber-optic security detector, which uses joint interferometers. Preferably, without limitation, the proposed fiber optic security detector 500, which uses joint interferometers with reference to FIG. 5 contains at least: a transceiver device 501 containing a computing device and one or more reflectometers, including those with combined outputs of the signal emitter and receiver, to which the transport part 502 of the optical circuit of the detector is connected. Preferably, without limitation, the transport part 502 of the detector 500 consists of: sections of fiber-optic cable, connecting elements, laser pulse power divider 503, consisting of splitters that reduce the power of the laser pulse energy in the distributed optical circuit of the detector to the required level. Preferably, without limitation, the sensitive elements consist of: a splitter 504, dividing the energy of the probing pulse into two parts, sections 505, 506 of the sensitive elements of the fiber-optic cable, splitters 507-510, and the Michelson interferometer is formed jointly by a common splitter 504, common sections of the sensitive cable elements 505 and 506, common splitters-separators 507, 508 and splitter-reflectors 509, 510, the Sagnac interferometer is formed jointly by a common splitter 504, common cable sections of sensitive elements 505 and 506, common splitters-separators 507, 508 with closed terminals and a coil 511 Preferably, but not limited to or necessarily, splitters 504-510 are located in one or more couplings. By way of example, and not limitation, Michelson and Sagnac interferometer elements may be placed in the same or different couplings on one or both sides of the sensor element segments 505, 506. Preferably, the transport part contains several branches (at least in terms of the number of controlled zones and the applied optical circuit for dividing the energy of the probe pulse of the divider), which arrive at the input of the corresponding splitter 504, located in the corresponding coupling. By way of example, and not limitation, splitters 509, 510 may each be implemented using circulators. By way of example, and not limitation, another optical delay line may be used in place of coil 511, for example, but not limited to, made by connecting into an optical chain the required length of redundant fiber optic cable strands.

[64] Such a fiber optic security detector 500 preferably, but not limited to, operates as follows. Preferably, without limitation, a short laser pulse is sent from the laser radiation source to the optical circuit to the input of the transport part of the device and then to the input of the power divider; the pulse power is divided into fractions at the divider. Preferably, without limitation, the divider is made of splitters with different degrees of division; the location of the splitters of the divider corresponds to the optical design of the device and is not strictly defined. Preferably, without limitation, the energy division of the probing pulse is carried out to the required power level in order to ensure the magnitude of the reflection signals of, respectively, the Michelson interferometer and the Sagnac interferometer from the sensitive part of the optical circuit of the device in the nominal range of the measurement scale of the receiving device. Preferably, without limitation, the time of arrival of the interfering signals at the input of the receiving device depends on the speed of propagation of laser radiation in the optical fiber material, on the length of the transport part and the length of the sensitive part, including the length of the control coils. Preferably, without limitation, the magnitude of the reflection signals, respectively, of the Michelson interferometer and the Sagnac interferometer depends on the degree of signal attenuation in the optical fiber, the degree of division of the energy of the probing pulse in the transport part of the device, the magnitude of the phase shift of the returned signals of the sensitive part of the device associated with the difference in shape and length paths of movement of impulses in the fiber to the place of impact. Preferably, without limitation, the change in the value of the sum of the reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector, arising from the dynamic impact of the intruder on the structure on which the sensitive part of the device is fixed. Preferably, without limitation, the optical design of each monitored area uses any reflectometric measurement method, in any combination, including the method of two-beam interferometers, including the Michelson interferometer and Sagnac interferometer methods, and contains, respectively, a Michelson interferometer circuit and a Sagnac interferometer circuit. Preferably, without limitation, the same sections of the optical fiber of the cable simultaneously serve as sensitive elements of both interferometers, in which a phase shift of the probing pulse is created in accordance with the physical impact, identical for both circuits. Preferably, but not limited to, the sensitivity of the optical circuit of the Sagnac interferometer to mechanical influences is maximum at the beginning of the optical ring (at the side of the splitter 504) in any direction and is significantly insensitive at the farthest end of the optical ring (at the middle of the ring on coil 511), with the sensitivity of the optical ring gradually decreasing from the beginning of the ring to the middle of the ring of the sensitive part, the value of the sum of the reflection signals depends on the power of the emitter, the initial value of the phase difference of the returned signals and the location of the impact, and the change in the value of the sum of the reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Preferably, without limitation, the sensitivity of the optical circuit of the Michelson interferometer to mechanical influences is the same throughout the sensitive part of the optical circuit, the magnitude of the reflection signal depends on the power of the emitter, the initial value of the phase difference, and the change in the value of the sum of reflection signals depends on the strength and dynamic characteristics of the impact on the sensitive part of the detector. Preferably, without limitation, the open circuit of the optical circuit of the Michelson interferometer is an unbalanced two-beam Michelson interferometer, a reflectometric signal receiving method; for the operation of the interferometer, preferably, without limitation, it is necessary to align the lengths of the arms of the sensitive element with an acceptable error determined by the width of the probing pulse. Preferably, without limitation, a splitter 504 common to the two interferometers splits the power of the probing pulse into two directions into different fiber optic cables 505 and 506, forming a common sensing element of the device. The second ends of the cable of the sensitive elements are connected to splitters 507 and 508 to separate the paths of parts of the probing pulse to the reflectors of an open two-beam Michelson interferometer (to splitters 509, 510 with closed optical outputs forming a reflector) and to form a closed ring of the Sagnac interferometer (closed terminals between splitters 507 and 508 using coil 511). The output signal of the Michelson interferometer and the Sagnac interferometer is generated at the output of the splitter 504 in series in accordance with the delay set between the interferometers. To delay the reflection signal of the closed circuit of the Sagnac interferometer, an adjusting coil 511 is installed, the length of which is calculated based on the condition: the signal delay time must be no less than the duration of the probing pulse. By way of example, and not limitation, another optical delay line may be used in place of coil 511, for example, but not limited to, made by connecting into an optical chain the required length of redundant fiber optic cable strands. If necessary, in order to equalize the length of the open-loop arms of the Michelson interferometer, an adjustment coil is installed in the shorter open-loop arm, eliminating the significant difference in the lengths of the Michelson interferometer arms. By way of example, but not limitation, instead of such a coil, another optical delay line can also be used, for example, but not limited to, made by connecting into an optical circuit the required length of reserve cores of a fiber optic cable. Preferably, but not limited to, to avoid overlap in time of the reflection signals from the closed and open loops, if necessary, an additional coil of the same optical fiber or other hardware delay line is installed in one of the loops, as described herein. Preferably, without limitation, the addressing and assignment of conventional numbers to the sensitive parts of the device (controlled areas) is carried out by the computing device based on the arrival time of two signals, respectively, the Michelson interferometer and the Sagnac interferometer. Preferably, without limitation, end-of-fiber sensors with static information and other controlled areas using other methods of generating a reflectometric response can be connected to any part of the optical circuit of the device along the length of the transport part.

[65] Preferably, without limitation, the described fiber-optic security detector 500, which uses joint interferometers, refers to technical security equipment in which a single-mode fiber-optic cable is used as a sensing element. Preferably, without limitation, the described device is intended for zonal organization of security lines. Preferably, without limitation, the described device can operate in conditions of increased industrial interference and natural influences and is intended for the protection of territories equipped with flexible mesh barriers, with canopies and tops made of reinforced razor tape or on barriers equipped with partially flexible and elastic elements, including a tunnel alarm . Preferably, without limitation, the proposed device is built using standard standard equipment used in fiber optic technology and special software. Preferably, without limitation, the proposed device allows you to determine the location of the impact on the structure exceeding the permissible values, at least with an accuracy of the size of the controlled area and with additional acceptable accuracy within the controlled area using software, using the ratio of the reflection signals of the coordinate-dependent closed loop (Sagnac interferometer) and coordinate-independent open loop (Michelson interferometer). Preferably, but not limited to, additional spools of the same optical fiber or other hardware delay lines are installed at the end of the closed loop or in both arms of the open loop as described herein. Preferably, without limitation, optical cores of different legs are used in two different fiber optic cables located on different parts of barriers and structures. Preferably, without limitation, the optical fibers of the transport part of the partial device are structurally routed in fiber optic cables with the fibers of the sensitive part of the device or in separate cables. Preferably, without limitation, the optical fibers of the sensitive part of the device are simultaneously delay lines for the probing pulse and must be no less than a given length, while for controlled areas whose dimensions are less than the required length, compensation coils or the length of the sensitive fibers are sequentially installed in the optical chain of the sensitive elements element is increased by sequentially connecting redundant fiber optic cable cores in both arms of the sensing element (as implemented with reference to the hardware delay lines described herein).

[66] Thus, as the described fiber-optic security detector 500, which uses joint interferometers, a fiber-optic security detector is declared, which uses joint interferometers, at least containing a station part with a transceiver device connected to a linear part of the mentioned detector, and the linear part is a branched optical circuit based on splitters and a fiber-optic cable, which, through connecting couplings and a transport cable, connect the transceiver device and the sensitive elements of the security fiber-optic detector, containing closed and open circuits that generate signals reflections in which the same sections of optical fiber of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the physical effect exerted, the same for both circuits, with the closed circuit being a Sagnac interferometer, and the open circuit being a Michelson interferometer . Optionally, the Sagnac interferometer splitters and the Michelson interferometer reflector splitters are placed in one coupling. Optionally, the Sagnac interferometer splitters and the Michelson interferometer reflector splitters are placed in different couplings. Optionally, the transceiver device is a reflectometer with a combined input and output. Optionally, the branched optical circuit contains an optical delay line made by connecting the required length of reserve cores of a fiber optic cable or a reel of optical fiber into an optical circuit. Optionally, splitters and reflectors of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, optical delay lines are installed at the end of the closed loop or in both arms of the open loop. Optionally, to eliminate the time overlap of reflection signals from the closed and open circuits, an optical delay line is installed in one of the circuits. Optionally, the optical fibers of the sensitive part of the device are simultaneously delay lines for the probing pulse and are made of no less than a given length, while for controlled areas whose dimensions are less than the required length, optical delay lines are sequentially installed in the optical chain of the sensitive elements. Optionally, the detector is configured to determine the location of an impact on the structure exceeding permissible values, at least with an accuracy of the size of the controlled area and with additional permissible accuracy within the controlled area using software, using the ratio of the reflection signals of a coordinate-dependent closed loop (interferometer Sagnac) and a coordinate-independent open loop (Michelson interferometer).

[67] Thus, as another linear part, the linear part of the fiber-optic security detector 500 is claimed, which uses joint interferometers, which is a branched optical circuit based on splitters and a fiber-optic cable, which are connected between is a transceiver device and sensitive elements of a fiber-optic security detector, containing closed and open circuits that generate reflection signals, in which the same sections of optical fiber cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the physical impact provided , the same for both circuits, with the closed circuit being a Sagnac interferometer and the open circuit being a Michelson interferometer. Optionally, the Sagnac interferometer splitters and the Michelson interferometer reflector splitters are placed in one coupling. Optionally, the Sagnac interferometer splitters and the Michelson interferometer reflector splitters are placed in different couplings. Optionally, the branched optical circuit contains an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, splitters and separators of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, optical delay lines are installed at the end of the closed loop or in both arms of the open loop. Optionally, to eliminate the time overlap of reflection signals from the closed and open circuits, an optical delay line is installed in one of the circuits. Optionally, the optical fibers of the sensitive part of the device are simultaneously delay lines for the probing pulse and are made of no less than a given length, while for controlled areas whose dimensions are less than the required length, optical delay lines are sequentially installed in the optical chain of the sensitive elements.

[68] Thus, as another connecting coupling, the connecting coupling of the security fiber optic detector 500, which uses joint interferometers, is declared, which is a connecting coupling in which the optical circuit of the security fiber optic detector is located, containing closed and open circuits that form reflection signals, in which the same sections of optical fiber of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the applied physical effect, identical for both circuits, with the closed circuit being a Sagnac interferometer, and the open circuit being Michelson interferometer. Optionally, the branched optical circuit contains an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, splitters and separators of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, optical delay lines are installed at the end of the closed loop or in both arms of the open loop. Optionally, to eliminate the time overlap of reflection signals from the closed and open circuits, an optical delay line is installed in one of the circuits.

[69] Thus, as another optical circuit, the optical circuit of the fiber-optic security detector 500 is declared, which uses joint interferometers, which are joint interferometers for the fiber-optic security detector, implementing an optical circuit containing closed and open circuits that generate signals reflections in which the same sections of optical fiber of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the physical effect exerted, identical for both circuits, with the closed circuit being a Sagnac interferometer, and the open circuit being an interferometer Michelson. Optionally, the Sagnac interferometer splitters and the Michelson interferometer reflector splitters are placed in one coupling. Optionally, the Sagnac interferometer splitters and the Michelson interferometer reflector splitters are placed in different couplings. Optionally, the optical circuit contains an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit or made in the form of a coil of optical fiber. Optionally, splitters and separators of the optical circuit of the Michelson interferometer are made on the basis of circulators or splitters. Optionally, optical delay lines are installed at the end of the closed loop or in both arms of the open loop. Optionally, to eliminate the time overlap of reflection signals from the closed and open circuits, an optical delay line is installed in one of the circuits.

[70] Thus, as another signaling method, a signaling method is claimed using a fiber-optic security detector 500 with a linear part with joint interferometers, in accordance with which: the placement of sensitive elements of the linear part of the fiber-optic security detector, which is a branched optical circuit, is provided , which by means of splitters, connecting couplings and fiber-optic cable is placed on the fencing elements (on the canopy, and/or the canvas, and/or on the anti-undermining fence), a laser pulse is formed from the output of the transceiver device to the input of the mentioned linear part and the returned pulse is received, which is a reflection signal, to the input of the transceiver along the same path, but in the opposite direction, and the linear part contains an optical circuit of joint interferometers for a fiber-optic security detector, containing closed and open circuits that generate reflection signals, which have the same segments Optical fibers of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the applied physical effect, identical for both circuits, with the closed circuit being a Sagnac interferometer, and the open circuit being a Michelson interferometer, while the change in the value of the sum of signals is recorded reflection corresponding to the magnitude and nature of the elastic deformation of the sensitive elements. Optionally, the Sagnac interferometer splitters and the Michelson interferometer reflector splitters are placed in one coupling. Optionally, the Sagnac interferometer splitters and the Michelson interferometer reflector splitters are placed in different couplings. Optionally, a transceiver device is provided which is a reflectometer with a combined input and output. Optionally, a branched optical circuit is made containing an optical delay line, made by connecting into an optical circuit the required length of reserve cores of a fiber-optic cable or made in the form of a coil of optical fiber. Optionally, splitters and separators of the optical circuit of a Michelson interferometer are made on the basis of circulators or splitters. Optionally, optical delay lines are installed at the end of the closed loop or in both arms of the open loop. Optionally, to eliminate the time overlap of reflection signals from the closed and open circuits, an optical delay line is installed in one of the circuits. Optionally, optical fibers of the sensitive part of the device are provided, which at the same time serve as delay lines for the probing pulse and are not less than a given length, while for controlled areas whose dimensions are less than the required length, optical delay lines are sequentially installed in the optical chain of the sensitive elements. Optionally, provide a detector configured to determine the location of an impact on a structure exceeding permissible values, at a minimum, with an accuracy up to the size of the controlled area and with an additional acceptable accuracy within the controlled area using software using the ratio of coordinate-dependent closed loop reflection signals (Sagnac interferometer) and coordinate-independent open loop (Michelson interferometer).

[71] Each of those described with reference to FIGS. 1-5 fiber-optic security detectors are designed with the ability to use, if necessary, optical delay lines - optical fiber coils, or made by connecting the required length of reserve cores of a fiber-optic cable into an optical chain. Such optical delay lines, as a rule, without limitation, are used either in the transport part of a fiber-optic security detector or in its sensitive element.

[72] Thus, as an optical delay line for a fiber-optic security detector, an optical delay line is declared, made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit. Optionally, the optical delay line is intended for use as part of an optical circuit of a Mach-Zehnder interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Michelson interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Sagnac interferometer for said detector. Optionally, the optical delay line is intended for use as part of the optical circuitry of the sensing elements of said detector. Optionally, the optical delay line is intended for use as part of the optical circuit of the transport part of the said detector.

[73] Thus, as another coupling, a coupling for a fiber-optic security detector is claimed, containing an optical delay line for a fiber-optic security detector, made by connecting the required length of the reserve cores of the fiber-optic cable into an optical circuit. Optionally, the optical delay line is intended for use as part of an optical circuit of a Mach-Zehnder interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Michelson interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Sagnac interferometer for said detector. Optionally, the optical delay line is intended for use as part of the optical circuitry of the sensing elements of said detector. Optionally, the optical delay line is intended for use as part of the optical circuit of the transport part of the said detector.

[74] Thus, as another linear part, a linear part for a fiber-optic security detector is claimed, containing an optical delay line for a fiber-optic security detector, made by connecting into an optical circuit the required length of the reserve cores of the fiber-optic cable. Optionally, the optical delay line is intended for use as part of an optical circuit of a Mach-Zehnder interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Michelson interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Sagnac interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical sensing circuit for said detector. Optionally, the optical delay line is intended for use as part of the optical circuit of the transport part of the said detector.

[75] Thus, as another fiber-optic security detector, a fiber-optic security detector is claimed, containing an optical delay line for the fiber-optic security detector, made by connecting the required length of reserve cores of the fiber-optic cable into an optical circuit. Optionally, the optical delay line is intended for use as part of an optical circuit of a Mach-Zehnder interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Michelson interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Sagnac interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical sensing circuit for said detector. Optionally, the optical delay line is intended for use as part of the optical circuit of the transport part of the said detector.

[76] Thus, as another signaling method, a signaling method using a fiber-optic security detector with a linear part with at least one interferometer is claimed, in accordance with which: the placement of sensitive elements of the linear part of the fiber-optic security detector, representing is a branched optical circuit, which, by means of couplings containing splitters and optical delay lines, and a fiber-optic cable, is placed on the fencing elements (on the canopy, and/or on the canvas, and/or on the anti-undermining barrier), generating a laser pulse from the output transceiver device to the input of said linear part and receive a returned pulse, which is a reflection signal, to the input of the transceiver device along the same path, but in the opposite direction, wherein the linear part contains an optical circuit of an open and/or closed interferometer for a fiber-optic security detector, containing an open and/or closed circuit that generates a reflection signal, in which the same sections of optical fibers of the cable are sensitive elements of interferometers in which a phase shift of the probing pulse is created in accordance with the applied physical impact, while a change in the value of the reflection signal corresponding to the value is recorded and the nature of the elastic deformation of the sensitive elements, wherein said optical delay line is an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical circuit. Optionally, the open-loop interferometer is a Michelson interferometer. Optionally, the closed interferometer is a Mach-Zehnder interferometer or a Sagnac interferometer. Optionally, the optical delay line is intended for use as part of an optical circuit of a Mach-Zehnder interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Michelson interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Sagnac interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical sensing circuit for said detector. Optionally, the optical delay line is intended for use as part of the optical circuit of the transport part of the said detector.

[77] Described with reference to FIGS. 1-5 fiber optic security detectors and their aspects can be used to organize a protected boundary or perimeter. Most typically, such a perimeter contains: a protected area (protected space or protected object), access to which is limited, and unauthorized access is subject to identification, including through a fiber-optic security detector, the linear part of which is installed on any fence, including number, configured to detect a tunnel (with an additional anti-undermining barrier, as will be described in detail below with reference to Fig. 7 and Fig. 8); and, optionally, any movable structures, for example, but not limited to, gates, wickets, hatches. Most typically, said linear parts, or at least their sensitive parts, described with reference to FIGS. 1-5, are placed on fencing elements. Most typically, said linear portions, or at least their sensitive portions, are described with reference to FIGS. 1-5, can be laid in the ground. Most typically, dynamic fiber optic detectors or any of their elements, or end-of-fiber sensors or any of their elements are placed on the mentioned moving structures.

[78] As will be shown below with reference to FIG. 6, for assembling and/or installing any linear part of any fiber optic security detector described with reference to any of FIG. 1-5, a container device can be used to assemble a linear part for a fiber optic security detector. Thus, it is proposed to install the linear part of a fiber-optic security detector in a factory and mount the finished linear part of the product during the manufacturing process on an intermediate carrier - a container, preferably, but not limited to, made in the form of a box consisting of a base and a lid. Preferably, but not limited to, a rotating drum is installed within the base of the box. Preferably, without limitation, there is a gap between the walls of the box base and the walls of the drum for mounting optical circuit elements on the walls of the drum. Preferably, without limitation, the transport part of the optical circuit and the sensitive elements are wound onto the drum, optionally the initial part of the required length is brought out onto the side wall of the drum and fixed on it for the purpose of carrying out control measurements and installation of couplings. Preferably, without limitation, couplings are secured to the side walls of the drum with the necessary supply of cable for installation inside the coupling. Installation and adjustment of the product is carried out sequentially in accordance with the order of assembly of the optical circuit, preferably, but not limited to, from the point of connection with the reflectometer and further along the circuit. In a highly branched circuit, the linear part is preferably, but not limited to, divided into component parts and mounted in different container devices. In the transport position, the rotation of the drum is not necessarily blocked by clamps. Installation of the linear part on site is preferably, but not limited to, carried out from a vehicle equipped with a manipulator crane. Preferably, the installation of the linear part at the site is carried out in the reverse order, unwinding the required quantity of elements of the optical circuit of the product from the drum and securing them to the fence or laying them in the ground in accordance with the specified requirements. Preferably, without limitation, technological supplies of the transport part and sensitive elements of the cable are rolled into coils and secured to the fence. A feature of the container device is the ability to access the main elements of the optical circuit during product manufacture and further maintenance. Preferably, without limitation, the box cover provides maximum depth of access to the elements of the optical circuit of the product and free release of the cable and couplings from the drum. Preferably, without limitation, all elements of the optical circuit of the device are fixed to the side walls of the drum and rotate with it. Preferably, without limitation, the fiber-optic cable is wound onto a drum, and at the junction with the couplings, the cable is cut off with a technological margin and brought out to the outside of the drum through the slots, while the cut end of the cable and the beginning of the next sections of the cable are marked and mounted in the coupling in in accordance with the optical diagram and are laid on the side wall of the drum, secured together with the coupling, the continuation of the next sections of the cable is inserted into the inside of the drum and continues to be wound onto the drum until it branches off to the next coupling. Preferably, without limitation, the container device allows the production of a complete product for perimeters with a range from 500 m to 5000 m or more under normal (factory) conditions with full quality control together with application software and transfer the product to the consumer for independent use. Preferably, without limitation, the equipment of the container device can be reused multiple times.

[79] As shown in FIG. 6, a container device 600 for assembling a linear part for a fiber optic security detector is preferably, but not limited to, a container 601 with a lid 602 containing a base 603 with a rotation axis on which a rotating drum 604 is fixed, on which a fiber optic cable is wound. 605 of the linear part of the fiber optic security detector, wherein the drum 604 contains means for attaching the coupling 606 of said linear part to its side walls. Preferably, but not limited to, the base 603 is configured to provide mounting of the drum 604 with an axis of rotation and to allow rotation of the drum 604 within the base 603, while the height of the base 603 allows maximum exposure of the visible upper part of the drum 603 with installed optical circuit elements. Preferably, without limitation, between the ends of the drum 604 and the walls of the base 603 on the axis of rotation, limiters 607 are provided, for example, but not limited to, in the form of disks or strips, limiting the movement of the drum 604 along the axis of rotation. Preferably, but not limited to, reel 604 is configured to maintain an acceptable bend radius for the fiber optic cable. Preferably, but not limited to, the side walls of the reel 604 are provided with slots to allow the fiber optic cable to be brought out to the outside of the wall of the reel 604 and retracted. Preferably, but not limited to, the side walls of the drum 604 are configured to allow free rotation of the drum 604 on the axis of rotation. Preferably, but not limited to, the side walls of the drum 604 are configured to provide mounting of the fiber optic cable and couplings on the outer wall of the drum 604 to a height not exceeding the clearance between the side wall of the base 603 and the corresponding wall of the drum 604. Preferably, but not limited to, a containerized the device 600 is designed to be reusable, for which, for example, it is possible to remove the drum to wind the linear part of another detector onto it.

[80] Thus, as a container device 600 for assembling a linear part for a fiber-optic security detector, a container device for assembling a linear part for a fiber-optic security detector is claimed, which is a container with a lid containing a base with an axis of rotation on which it is fixed a rotating drum on which the fiber-optic cable of the linear part of the security fiber-optic detector is wound, the drum containing means for attaching the coupling of said linear part to its side walls. Optionally, the base is designed to ensure installation of the drum with an axis of rotation and ensure rotation of the drum inside the base, while the height of the base allows the visible upper part of the drum with installed elements of the optical circuit to be maximally open. Optionally, between the ends of the drum and the walls of the base on the axis of rotation there are limiters that limit the movement of the drum along the axis of rotation. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured in such a way as to provide fastening of the fiber optic cable and couplings to the outer wall of the drum with a height not exceeding the gap between the side wall of the base and the corresponding wall of the drum. Optionally, the container device is designed to be reusable, for which it is possible to remove the drum for winding the linear part of another detector onto it.

[81] Thus, as another container device 600 for assembling a linear part for a fiber optic security detector, a container device for assembling a linear part for a fiber optic security detector is claimed, which is a container with a lid containing a base with an axis of rotation on which it is fixed a rotating drum on which the fiber-optic cable of the linear part of the security fiber-optic detector is wound, and the drum contains a means for attaching on its side walls the connecting coupling of the said linear part, and the said connecting coupling contains splitters of the Michelson interferometer and splitters of the Mach interferometer placed in it Zendera. Optionally, the base is designed to ensure installation of the drum with an axis of rotation and ensure rotation of the drum inside the base, while the height of the base allows the visible upper part of the drum with installed elements of the optical circuit to be maximally open. Optionally, between the ends of the drum and the walls of the base on the axis of rotation there are limiters that limit the movement of the drum along the axis of rotation. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured in such a way as to provide fastening of the fiber optic cable and couplings to the outer wall of the drum with a height not exceeding the gap between the side wall of the base and the corresponding wall of the drum. Optionally, the container device is designed to be reusable, for which it is possible to remove the drum for winding the linear part of another detector onto it.

[82] Thus, as another container device 600 for assembling a linear part for a fiber optic security detector, a container device for assembling a linear part for a fiber optic security detector is claimed, which is a container with a lid containing a base with an axis of rotation on which it is fixed a rotating drum on which a fiber-optic cable of the linear part of the security fiber-optic detector is wound, wherein the drum contains means for attaching the coupling of said linear part to its side walls, and said coupling contains Michelson interferometer splitters placed in it. Optionally, the base is designed to ensure installation of the drum with an axis of rotation and ensure rotation of the drum inside the base, while the height of the base allows the visible upper part of the drum with installed elements of the optical circuit to be maximally open. Optionally, between the ends of the drum and the walls of the base on the axis of rotation there are limiters that limit the movement of the drum along the axis of rotation. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured in such a way as to provide fastening of the fiber optic cable and couplings to the outer wall of the drum with a height not exceeding the gap between the side wall of the base and the corresponding wall of the drum. Optionally, the container device is designed to be reusable, for which it is possible to remove the drum to wind the linear part of another detector onto it.

[83] Thus, as another container device 600 for assembling a linear part for a fiber optic security detector, a container device for assembling a linear part for a fiber optic security detector is claimed, which is a container with a lid containing a base with an axis of rotation on which it is fixed a rotating drum on which a fiber-optic cable of the linear part of the security fiber-optic detector is wound, wherein the drum contains means for attaching the connecting coupling of said linear part to its side walls, and said connecting coupling contains splitters of the Mach-Zehnder interferometer placed in it. Optionally, the base is designed to ensure installation of the drum with an axis of rotation and ensure rotation of the drum inside the base, while the height of the base allows the visible upper part of the drum with installed elements of the optical circuit to be maximally open. Optionally, between the ends of the drum and the walls of the base on the axis of rotation there are limiters that limit the movement of the drum along the axis of rotation. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured in such a way as to provide fastening of the fiber optic cable and couplings to the outer wall of the drum with a height not exceeding the gap between the side wall of the base and the corresponding wall of the drum. Optionally, the container device is designed to be reusable, for which it is possible to remove the drum for winding the linear part of another detector onto it.

[84] Thus, as another container device 600 for assembling a linear part for a fiber optic security detector, a container device for assembling a linear part for a fiber optic security detector is claimed, which is a container with a lid containing a base with an axis of rotation on which it is fixed a rotating drum on which the fiber-optic cable of the linear part of the security fiber-optic detector is wound, and the drum contains a means for securing on its side walls the connecting coupling of the said linear part, and the said connecting coupling contains splitters of the Sagnac interferometer and splitters of the Mach interferometer placed in it. Zendera. Optionally, the base is designed to ensure installation of the drum with an axis of rotation and ensure rotation of the drum inside the base, while the height of the base allows the visible upper part of the drum with installed elements of the optical circuit to be maximally open. Optionally, between the ends of the drum and the walls of the base on the axis of rotation there are limiters that limit the movement of the drum along the axis of rotation. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured in such a way as to provide fastening of the fiber optic cable and couplings to the outer wall of the drum with a height not exceeding the gap between the side wall of the base and the corresponding wall of the drum. Optionally, the container device is designed to be reusable, for which it is possible to remove the drum for winding the linear part of another detector onto it.

[85] Thus, as another container device 600 for assembling a linear part for a fiber optic security detector, a container device for assembling a linear part for a fiber optic security detector is claimed, which is a container with a lid containing a base with an axis of rotation on which it is fixed a rotating drum on which the fiber-optic cable of the linear part of the security fiber-optic detector is wound, wherein the drum contains means for attaching the connecting coupling of said linear part to its side walls, and said connecting coupling contains splitters of a Michelson interferometer and splitters of a Sagnac interferometer placed in it. Optionally, the base is designed to ensure installation of the drum with an axis of rotation and ensure rotation of the drum inside the base, while the height of the base allows the visible upper part of the drum with installed elements of the optical circuit to be maximally open. Optionally, between the ends of the drum and the walls of the base on the axis of rotation there are limiters that limit the movement of the drum along the axis of rotation. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured in such a way as to provide fastening of the fiber optic cable and couplings to the outer wall of the drum with a height not exceeding the gap between the side wall of the base and the corresponding wall of the drum. Optionally, the container device is designed to be reusable, for which it is possible to remove the drum for winding the linear part of another detector onto it.

[86] In view of the use of optical delay lines described herein, as another container device for assembling a linear part for a fiber optic security detector 600, a container device for assembling a linear part for a fiber optic security detector is claimed, which is a container with a lid, containing a base with an axis of rotation on which a rotating drum is fixed, on which a fiber-optic cable of the linear part of the security fiber-optic detector is wound, wherein the drum contains means for attaching a coupling of said linear part to its side walls, wherein said coupling contains an optical line delay for a fiber-optic security detector, made by connecting the required length of reserve cores of a fiber-optic cable into an optical chain. Optionally, the optical delay line is intended for use as part of an optical circuit of a Mach-Zehnder interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Michelson interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Sagnac interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical sensing circuit for said detector. Optionally, the optical delay line is intended for use as part of the optical circuit of the transport part of the said detector.

[87] Thus, as the drum of the container device 600 for assembling the linear part for the security fiber optic detector, the drum of the container device for assembling the linear part for the security fiber optic detector is claimed, which is a drum configured to rotate on an axis, on which it is wound a fiber-optic cable for the linear part of a fiber-optic security detector, wherein the drum contains means for securing the coupling of said linear part to its side walls. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured to allow the fiber optic cable and couplings to be secured to the outer wall of the drum at a height not exceeding the gap between the side wall of the base of the container device and the corresponding wall of the drum. Optionally, the drum is configured to be removed from the container device for winding a linear part of another detector onto it or replaced with another drum with a linear part of another detector.

[88] Thus, as another drum of the container device 600 for assembling a linear part for a fiber-optic security detector, a drum of a container device for assembling a linear part for a fiber-optic security detector is claimed, which is a drum configured to rotate on an axis, on which it is wound a fiber-optic cable of the linear part of the security fiber-optic detector, wherein the drum contains means for fastening couplings of said linear part on its side walls, and said couplings contain Michelson interferometer splitters and Mach-Zehnder interferometer splitters placed in it. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured to allow the fiber optic cable and couplings to be secured to the outer wall of the drum at a height not exceeding the gap between the side wall of the base of the container device and the corresponding wall of the drum. Optionally, the drum is configured to be removed from the container device for winding a linear part of another detector onto it or replaced with another drum with a linear part of another detector.

[89] Thus, as another drum of the container device 600 for assembling a linear part for a fiber-optic security detector, a drum of a container device for assembling a linear part for a fiber-optic security detector is claimed, which is a drum configured to rotate on an axis, on which it is wound a fiber-optic cable of the linear part of the security fiber-optic detector, wherein the drum contains means for fastening on its side walls a connecting coupling of said linear part, and said connecting coupling contains splitters of a Michelson interferometer placed in it. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured to allow the fiber optic cable and couplings to be secured to the outer wall of the drum at a height not exceeding the gap between the side wall of the base of the container device and the corresponding wall of the drum. Optionally, the drum is configured to be removed from the container device for winding a linear part of another detector onto it or replaced with another drum with a linear part of another detector.

[90] Thus, as another drum of the container device 600 for assembling a linear part for a fiber-optic security detector, a drum of a container device for assembling a linear part for a fiber-optic security detector is claimed, which is a drum configured to rotate on an axis, on which it is wound a fiber-optic cable of the linear part of the security fiber-optic detector, wherein the drum contains means for attaching the coupling of said linear part to its side walls, and said coupling contains splitters of the Mach-Zehnder interferometer placed in it. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured to allow the fiber optic cable and couplings to be secured to the outer wall of the drum at a height not exceeding the gap between the side wall of the base of the container device and the corresponding wall of the drum. Optionally, the drum is configured to be removed from the container device for winding the linear part of another detector onto it.

[91] Thus, as another drum of the container device 600 for assembling a linear part for a security fiber optic detector, a drum of a container device for assembling a linear part for a security fiber optic detector is claimed, which is a drum configured to rotate on an axis, on which it is wound a fiber-optic cable of the linear part of the security fiber-optic detector, wherein the drum contains means for fastening couplings of said linear part on its side walls, and said couplings contain Sagnac interferometer splitters and Mach-Zehnder interferometer splitters placed in it. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured to allow the fiber optic cable and couplings to be secured to the outer wall of the drum at a height not exceeding the gap between the side wall of the base of the container device and the corresponding wall of the drum. Optionally, the drum is configured to be removed from the container device for winding a linear part of another detector onto it or replaced with another drum with a linear part of another detector.

[92] Thus, as another drum of the container device 600 for assembling a linear part for a fiber-optic security detector, a drum of a container device for assembling a linear part for a fiber-optic security detector is claimed, which is a drum configured to rotate on an axis, on which it is wound a fiber-optic cable of the linear part of the security fiber-optic detector, wherein the drum contains means for fastening on its side walls a coupling of said linear part, and said coupling contains splitters of a Michelson interferometer and a Sagnac interferometer placed in it. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the side walls of the drum are designed in such a way as to ensure free rotation of the drum on the axis of rotation. Optionally, the side walls of the drum are configured to allow the fiber optic cable and couplings to be secured to the outer wall of the drum at a height not exceeding the gap between the side wall of the base of the container device and the corresponding wall of the drum. Optionally, the drum is configured to be removed from the container device for winding a linear part of another detector onto it or replaced with another drum with a linear part of another detector.

[93] In view of the optical delay lines described herein, as another drum of a container device for assembling a linear part for a fiber optic intrusion detector 600, a drum of a container device for assembling a linear part for a security fiber optic detector is claimed, which is configured to rotation on the axis of the drum on which the fiber-optic cable of the linear part of the fiber-optic security detector is wound, wherein the drum contains means for attaching the coupling of said linear part to its side walls, wherein said coupling contains an optical delay line for the fiber-optic security detector , made by connecting the required length of reserve cores of a fiber-optic cable into an optical chain. Optionally, the optical delay line is intended for use as part of an optical circuit of a Mach-Zehnder interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Michelson interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical circuit of a Sagnac interferometer for said detector. Optionally, the optical delay line is intended for use as part of an optical sensing circuit for said detector. Optionally, the optical delay line is intended for use as part of the optical circuit of the transport part of the said detector.

[94] Thus, as a method for installing a linear part for a fiber-optic security detector, a method for installing a linear part for a fiber-optic security detector is claimed, in which the installation is carried out using a container device 600 for assembling a linear part for a fiber-optic security detector, representing is a container with a lid containing a base with an axis of rotation on which a rotating drum is fixed, on which a fiber-optic cable of the linear part of the security fiber-optic detector is wound, and the drum contains a means for attaching the coupling of said linear part to its side walls, for which in the reverse order, unwind the elements of the optical circuit in the required quantity and secure them along the perimeter of the controlled area. Optionally, between the ends of the drum and the walls of the base on the axis of rotation there are limiters that limit the movement of the drum along the axis of rotation. Optionally, the drum is configured to provide an acceptable bend radius for the fiber optic cable. Optionally, slots are made on the side walls of the drum to lead the fiber-optic cable to the outside of the drum wall and bring it back. Optionally, the container device is designed to be reusable, for which it is possible to remove the drum for winding the linear part of another detector onto it. Optionally, said coupling comprises Michelson interferometer splitters and Mach-Zehnder interferometer splitters housed therein. Optionally, said coupling comprises Michelson interferometer splitters housed therein. Optionally, said coupling includes Mach-Zehnder interferometer splitters housed therein. Optionally, said coupling contains Sagnac interferometer splitters and Mach-Zehnder interferometer splitters housed therein. Optionally, said coupling comprises Michelson interferometer splitters and Sagnac interferometer splitters housed therein.

[95] The previously described linear parts are preferably mounted on the fences of the protected line. As shown in FIG. 7 and 8, preferably, but not limited to, such barriers 700, 800 are various mesh or other barriers, most typically consisting of a structure of support posts 701, 801 secured to some kind of foundation (for example, but not limited to concrete or piles) 702 , 802 between which mesh fabric 703 is stretched or threads of barbed wire 803 are stretched. Preferably, without limitation, said fences, including, but not limited to, mesh fences and barbed wire, are fences that comply with GOST R 57278-2016 “Protective fences. Classification. General provisions”, and thus relate to reinforced razor tape (RBR), reinforced twisted razor tape, spiral safety barrier, flat safety barrier, engineering means of physical protection, barbed wire, anti-ram barriers, other fences, any classes, not limited to protective , main, additional, warning, stationary or quickly deployable (portable and/or transportable), solid, sectional, blind, visible, with a rigid blind cloth; with rigid lattice fabric; with a flexible fabric made of wire, and/or mesh, and/or ACL spiral; with a combined canvas, representing any combination of the above canvases; with a point (pile, screw support, tubular driven support) and/or strip foundation; made from, but not limited to, concrete and/or reinforced concrete, and/or brick, and/or metal, and/or wood, and/or polymer material, and/or any combination thereof. Preferably, but not limited to, a top 704, 804 with additional strands of barbed wire is also stretched between the support posts 701, 801. Preferably, without limitation, the fence 700, 800 is additionally provided with a mesh 705, 805 stretched into the ground, preferably an anti-undermining portion of the mesh. Preferably, without limitation, the sensitive elements 706 of the linear part of the fiber optic security detector are placed on the mesh 703 along a curved sinusoidal path in one or more lines, thus providing additional connectivity of the elements of the mesh 703, which eliminates the possibility of unauthorized violation of the protected perimeter by partially eliminating mesh fencing. Preferably, without limitation, the sensitive elements 806 of the linear part of the fiber optic security detector are placed on a linear fence formed by threads of barbed wire 803 also along a sinusoidal trajectory in one or more lines, thus ensuring connectivity between the threads of barbed wire, which eliminates the possibility of unauthorized violation protected perimeter by partially removing barbed wire. Preferably, without limitation, the sensitive elements 706, 806 of the linear part of the fiber optic security detector are placed on the top 704, 804 of the fence formed by additional threads of barbed wire also along a sinusoidal path in one or more lines, thus ensuring connectivity between the threads of barbed wire, which eliminates the possibility of unauthorized violation of the protected perimeter by partially removing the barbed wire or overcoming the perimeter from above. Preferably, without limitation, the sensitive elements 706, 806 of the linear part of the fiber-optic security detector are placed on the anti-undermining mesh 705, 805 of the fence, which eliminates the possibility of unauthorized violation of the protected perimeter by digging under the fence. Preferably, without limitation, in the absence of an anti-undermining mesh, the sensitive elements 706, 806 of the linear part of the fiber-optic security detector are placed between the foundations 702, 802 of the pillars at the depth of the greatest probability of physical impact on the sensitive element, which eliminates the possibility of unauthorized violation of the protected perimeter by digging under the fence. Said mesh fencing and/or linear fencing formed by strands of barbed wire are also referred to hereinafter as a “non-continuous obstacle”. Moreover, such a non-continuous obstacle, as a rule, is predominantly non-rigid, that is, individual elements of such a fence can be damaged or destroyed by an intruder without significant effort. By way of example, and not limitation, the barrier between the posts is not a chain link fence or barbed wire fence, but is preferably a solid barrier, such as a picket fence or a solid fence, in which case the fence includes said cap, on where the sensitive element is located.

[96] Thus, as a fencing option, a fence with a linear part of a fiber-optic security detector is declared, which is a mesh fabric stretched between pillars installed on foundations, and the mesh fabric contains a sensitive element of a fiber-optic security detector, placed along the mesh fabric along a curved line a trajectory that provides additional connectivity of the elements of the mesh fabric. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Mach-Zehnder interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Sagnac interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Sagnac interferometer. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the sensing element is a sensing element of a fiber-optic security detector with an optical circuit containing a Mach-Zehnder interferometer and a Sagnac interferometer.

[97] Thus, as another fencing option, a fence with a linear part of a fiber-optic security detector is claimed, which is a linear fence formed by threads of barbed wire stretched between pillars installed on the foundations, and the linear fence contains a sensitive element of a fiber-optic security detector placed along a linear fence along a curved trajectory, ensuring the connection of the barbed wire threads. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Mach-Zehnder interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Sagnac interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Sagnac interferometer. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the sensing element is a sensing element of a fiber-optic security detector with an optical circuit containing a Mach-Zehnder interferometer and a Sagnac interferometer.

[98] Thus, as another fencing option, a fence with a linear part of a fiber-optic security detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on foundations, containing a top stretched between them, formed by threads of barbed wire, and the top contains a sensitive an element of a fiber-optic security detector, placed along the top along a curved path, ensuring the connection of the barbed wire threads. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Mach-Zehnder interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Sagnac interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Sagnac interferometer. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the sensing element is a sensing element of a fiber-optic security detector with an optical circuit containing a Mach-Zehnder interferometer and a Sagnac interferometer. Optionally, the obstacle is a mesh fabric. Optionally, the obstacle is a linear fence formed by strands of barbed wire. Optionally, the obstacle is predominantly a continuous obstacle.

[99] Thus, as an option for a fence with a means for detecting undermining, a fence with a means for detecting undermining with a linear part of a security fiber-optic detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on the foundations, containing a mesh stretched between them in the ground , on which the sensitive element of the linear part of the fiber-optic security detector is located. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Mach-Zehnder interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Sagnac interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Sagnac interferometer. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the sensing element is a sensing element of a fiber-optic security detector with an optical circuit containing a Mach-Zehnder interferometer and a Sagnac interferometer. Optionally, the obstacle is a mesh fabric. Optionally, the obstacle is a linear fence formed by strands of barbed wire. Optionally, the obstacle is predominantly a continuous obstacle.

[100] Thus, as another option for a fence with a means for detecting undermining, a fence with a means for detecting undermining with a linear part of a security fiber-optic detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on foundations, between which in the ground at a depth the greatest probability of physical impact is the sensitive element of the linear part of the fiber-optic security detector. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Mach-Zehnder interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Sagnac interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Sagnac interferometer. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the sensing element is a sensing element of a fiber-optic security detector with an optical circuit containing a Mach-Zehnder interferometer and a Sagnac interferometer. Optionally, the obstacle is a mesh fabric. Optionally, the obstacle is a linear fence formed by strands of barbed wire. Optionally, the obstacle is predominantly a continuous obstacle.

[101] Thus, as a method of fixing the linear part of a fiber-optic security detector on a fence, a method of fixing the linear part of a fiber-optic security detector on a fence is claimed, in which the sensitive element of the linear part of a fiber-optic security detector is fixed to an obstacle as part of the fence along a curved line a trajectory that ensures vibration sensitivity and connectivity of obstacle elements to each other. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Mach-Zehnder interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Sagnac interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Sagnac interferometer. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the sensing element is a sensing element of a fiber-optic security detector with an optical circuit containing a Mach-Zehnder interferometer and a Sagnac interferometer. Optionally, the obstacle is a mesh fabric. Optionally, the obstacle is a linear fence formed by strands of barbed wire.

[102] Thus, as another fence, a fence with a linear part of a fiber-optic security detector is claimed, which is a fence formed by a non-continuous obstacle stretched between pillars installed on foundations, and the continuous obstacle contains a sensitive element of a fiber-optic security detector placed along the non-continuous obstacle along a curved path, providing vibration sensitivity and additional connectivity of the elements of a non-continuous obstacle, and the fiber-optic security detector is the detector described earlier with reference to FIG. 1.

[103] Thus, as another fence, a fence with a linear part of a fiber-optic security detector is claimed, which is a fence formed by a non-continuous obstacle stretched between pillars installed on foundations, and the continuous obstacle contains a sensitive element of a fiber-optic security detector placed along the non-continuous obstacle along a curved path, providing vibration sensitivity and additional connectivity of the elements of a non-continuous obstacle, and the fiber-optic security detector is the detector described earlier with reference to FIG. 2.

[104] Thus, as another fence, a fence with a linear part of a fiber-optic security detector is claimed, which is a fence formed by a non-continuous obstacle stretched between pillars installed on foundations, and the continuous obstacle contains a sensitive element of a fiber-optic security detector placed along the non-continuous obstacle along a curved path, providing vibration sensitivity and additional connectivity of the elements of a non-continuous obstacle, and the fiber-optic security detector is the detector described earlier with reference to FIG. 3.

[105] Thus, as another fence, a fence with a linear part of a fiber-optic security detector is claimed, which is a fence formed by a non-continuous obstacle stretched between pillars installed on foundations, and the continuous obstacle contains a sensitive element of a fiber-optic security detector placed along the non-continuous obstacle along a curved path, providing vibration sensitivity and additional connectivity of the elements of a non-continuous obstacle, and the fiber-optic security detector is the detector described earlier with reference to FIG. 4.

[106] Thus, as another fence, a fence with a linear part of a fiber-optic security detector is claimed, which is a fence formed by a non-continuous obstacle stretched between pillars installed on foundations, and the continuous obstacle contains a sensitive element of a fiber-optic security detector placed along the non-continuous obstacle along a curved path, providing vibration sensitivity and additional connectivity of the elements of a non-continuous obstacle, and the fiber-optic security detector is the detector described earlier with reference to FIG. 5.

[107] Thus, as another fence with a means of detecting undermining, a fence with a means of detecting undermining with a linear part of a security fiber-optic detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on the foundations, between which in the ground at the depth of greatest probability physical impact, the sensitive element of the linear part of the fiber-optic security detector is stretched, and the fiber-optic security detector is the detector described earlier with reference to FIG. 1. Optionally, the mentioned sensitive element is fixed on a mesh stretched between the pillars in the ground.

[108] Thus, as another fence with a means of detecting undermining, a fence with a means of detecting undermining with a linear part of a security fiber-optic detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on foundations, between which in the ground at the depth of greatest probability physical impact, the sensitive element of the linear part of the fiber-optic security detector is stretched, and the fiber-optic security detector is the detector described earlier with reference to FIG. 2. Optionally, the mentioned sensitive element is fixed on a mesh stretched between the pillars in the ground.

[109] Thus, as another fence with a means of detecting undermining, a fence with a means of detecting undermining with a linear part of a security fiber-optic detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on the foundations, between which in the ground at the depth of greatest probability physical impact, the sensitive element of the linear part of the fiber-optic security detector is stretched, and the fiber-optic security detector is the detector described earlier with reference to FIG. 3. Optionally, the mentioned sensitive element is fixed on a mesh stretched between the pillars in the ground.

[110] Thus, as another fence with a means of detecting undermining, a fence with a means of detecting undermining with a linear part of a security fiber-optic detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on foundations, between which in the ground at the depth of greatest probability physical impact, the sensitive element of the linear part of the fiber-optic security detector is stretched, and the fiber-optic security detector is the detector described earlier with reference to FIG. 4. Optionally, the said sensitive element is fixed to a mesh stretched between the pillars in the ground.

[111] Thus, as another fence with a means of detecting undermining, a fence with a means of detecting undermining with a linear part of a security fiber-optic detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on foundations, between which in the ground at the depth of greatest probability physical impact, the sensitive element of the linear part of the fiber-optic security detector is stretched, and the fiber-optic security detector is the detector described earlier with reference to FIG. 5. Optionally, the mentioned sensitive element is fixed on a mesh stretched between the pillars in the ground.

[112] Thus, as another fencing option, a fence with a linear part of a fiber-optic security detector is claimed, which is a fence formed by a continuous obstacle stretched between pillars installed on foundations, and the continuous obstacle contains a sensitive element of a fiber-optic security detector located along non-continuous obstacle along a curved path ensuring connectivity of the elements of the non-continuous obstacle, wherein said detector contains a hardware delay line, which is an optical delay line made by connecting the required length of reserve cores of a fiber-optic cable into an optical chain. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Mach-Zehnder interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Sagnac interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Sagnac interferometer. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the sensing element is a sensing element of a fiber-optic security detector with an optical circuit containing a Mach-Zehnder interferometer and a Sagnac interferometer. Optionally, the obstacle is a mesh fabric. Optionally, the obstacle is a linear fence formed by strands of barbed wire.

[113] Thus, as another option for a fence with a means for detecting undermining, a fence with a means for detecting undermining with a linear part of a security fiber-optic detector is claimed, which is a fence formed by an obstacle stretched between pillars installed on foundations, between which in the ground at a depth the highest probability of physical impact, the sensitive element of the linear part of the fiber-optic security detector is stretched, and as part of the optical circuit of the fiber-optic security detector, a hardware delay line is used, made by connecting the required length of reserve cores of the fiber-optic cable into an optical circuit. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Mach-Zehnder interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Sagnac interferometer. Optionally, the sensing element is the sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Sagnac interferometer. Optionally, the sensing element is a sensing element of a fiber optic security detector with an optical circuit containing a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the sensing element is a sensing element of a fiber-optic security detector with an optical circuit containing a Mach-Zehnder interferometer and a Sagnac interferometer. Optionally, the obstacle is a mesh fabric. Optionally, the obstacle is a linear fence formed by strands of barbed wire. Optionally, said sensitive element is fixed to a mesh stretched between the pillars in the ground.

[114] Some linear portion described with reference to FIG. 1-5 fiber-optic security detectors, as well as other devices that use sensitive elements or transport parts in the form of fiber-optic and other cables, can be laid in the ground. The main requirement for laying any cable in the ground is to ensure tight contact of the fiber optic cable with the ground and reduce the waiting time for the natural compaction of the soil around the cable, depending on weather conditions. Preferably, without limitation, sensitive elements of the linear part of the fiber optic security detector, as well as transport parts, can be placed in the ground. In this case, when laying in the ground, a mechanized laying method can be used. Preferably, without limitation, such a mechanized laying method is carried out using a cable laying machine with a V-shaped plow (V-plow), described, for example, in the article by Sadykov F.R., et al. “Modern drainage systems”, magazine Polymer Pipes No. 4 ( 50), November 2015, hereby incorporated herein by reference. Preferably, but not limited to, said cable layer is a Komatsu D65P V-plow Bulldozer or the like. Preferably, without limitation, an unwinding device is attached to the V-shaped plow of the drainage machine, or to the body of the drainage machine, for example, without limitation, in a manner similar to the installation of the unwinding device for the TM10.00 GST15 KVG-280 cable layer (as indicated at URL: http ://web.archive.org/web/20200120005256/http://tm10.ru/catalog/kabel/kvg280/, included in this description by reference), on which a rotating drum with a fiber optic cable is installed, for example, not limited to the drum described previously with reference to FIG. 6. Preferably, without limitation, before laying begins, the cable is inserted into the input channel of the flexible linear products of the cable laying machine into the lower zone of the V-shaped plow and attached to the ground, after which the cable laying machine begins to move along a given cable laying path. Preferably, without limitation, water is additionally supplied to the cable entry channel to ensure better contact of the cable with the ground. Preferably, without limitation, upon completion of laying, said plow is raised, thereby releasing the cable. Preferably, but not limited to, subsequent compaction is carried out by a cable layer using the cable layer's own weight. Preferably, without limitation, water is additionally supplied to the cable entry channel to ensure better contact of the cable with the ground. By way of example, and not limitation, a V-plow is a stand-alone device, such as a trailer or attachment for installation on a non-specialized mechanized implement.

[115] Thus, as another drum, a drum for mechanized laying of a fiber-optic cable in the ground is claimed, containing a fiber-optic cable configured to be installed on the unwinding device of a cable laying machine with a V-shaped plow.

[116] Thus, as a mechanized cable laying plow, a V-shaped plow is claimed for use with a mechanized cable laying machine, configured to attach an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of the fiber-optic cable into the ground.

[117] Thus, a mechanized cable layer with an input channel for flexible linear products and a V-shaped plow configured to attach an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of a fiber-optic cable in priming.

[118] Thus, as a method for mechanized laying of a fiber-optic cable in the ground, a method for mechanized laying of a fiber-optic cable in the ground is claimed, in which a mechanized cable-laying machine with an input channel for flexible linear products and V- a shaped plow configured to attach an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of the fiber-optic cable in the ground.

[119] Thus, as another method for mechanized laying of fiber optic cable in the ground, a method for mechanized laying of fiber optic cable in the ground is claimed, in which a V-shaped plow similar to a V-shaped plow is used to lay the fiber optic cable in the ground a mechanized cable-laying machine configured to attach an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of the fiber-optic cable in the ground.

[120] Thus, as another method for mechanized laying of a fiber-optic cable in the ground, a method for mechanized laying of a fiber-optic cable in the ground is claimed, in which, before laying begins, the cable is inserted into the input channel of flexible linear products of the cable layer with the input channel of flexible linear products and with a V-shaped plow into the lower zone of the V-shaped plow and attached to the ground, after which they are moved by a cable laying machine along a given cable laying path. Optionally, during installation, water is additionally supplied into the cable entry channel to ensure better contact of the cable with the ground. Optionally, subsequent compaction is carried out by a cable layer using the cable layer's own weight.

[121] Thus, as another fiber-optic security detector, a fiber-optic security detector is claimed, the linear part of which is laid in the ground in a mechanized manner, in which a mechanized cable-laying machine with an input channel for flexible linear products and A V-shaped plow, configured to attach an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of the fiber-optic cable in the ground. Optionally, the fiber-optic security detector contains a hardware delay line, made by connecting the required length of reserve cores of the fiber-optic cable into an optical circuit. Optionally, the fiber-optic security detector contains an optical circuit of a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains an optical circuit of a Michelson interferometer. Optionally, the fiber-optic security detector contains the optical circuit of a Sagnac interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Sagnac interferometer and a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Michelson interferometer and a Sagnac interferometer.

[122] Thus, as another linear part, the linear part of the fiber optic security detector is claimed, characterized by the fact that it is laid in the ground in a mechanized manner, in which a mechanized cable layer with an input channel for flexible linear products and A V-shaped plow, configured to attach an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of the fiber-optic cable in the ground. Optionally, the fiber-optic security detector contains a hardware delay line, made by connecting the required length of reserve cores of the fiber-optic cable into an optical circuit. Optionally, the fiber-optic security detector contains an optical circuit of a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains an optical circuit of a Michelson interferometer. Optionally, the fiber-optic security detector contains the optical circuit of a Sagnac interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Sagnac interferometer and a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Michelson interferometer and a Sagnac interferometer.

[123] Thus, a method for creating a protected boundary using a fiber-optic security detector can be provided, in which a protected perimeter is erected by laying the linear part of the fiber-optic security detector in the ground using a method of mechanized laying of a fiber-optic cable, in which for laying to install a fiber-optic cable into the ground, a mechanized cable-laying machine is used with an input channel for flexible linear products and a V-shaped plow, configured to attach an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of the fiber-optic cable into the ground.

[124] Thus, a method for creating a protected boundary using a fiber-optic security detector can be provided, in which a protected perimeter is erected by laying the linear part of a fiber-optic security detector in the ground using a method of mechanized laying of a fiber-optic cable in the ground, in which To lay the fiber-optic cable in the ground, a V-shaped plow is used, similar to the V-shaped plow of a mechanized cable-laying machine, configured to attach an unwinding device to it for installing a drum with a fiber-optic cable on it for mechanized laying of the fiber-optic cable in the ground.

[125] In some other cases, laying fiber optic cable in the ground using a vertically positioned plow, such as the Vertical Cable Laying Plow TM10.00 GST15 KVG-280, which was described earlier, can be used. With this mechanized method of laying a fiber-optic cable in the ground using a vertically positioned plow, in the ground after the passage of the plow in the lower part there remains an unclosed area of soil associated with the squeezing out of the soil to the sides when the plow passes, and this area of soil at a depth of about 400 mm does not closes even when the tractor passes over the cable line. If there is such a cavity in the place where the cable is laid in straight sections, the contact of the cable with the ground is not tight and the sensitivity of the cable is reduced. In the proposed method of cable laying, the cable laying trajectory should be carried out along a curved path with an alternating change in the direction of the radius 902 of the bend of the trajectory 901 (Fig. 9). In this case, the presence of cable tension during the mechanized laying process leads to the cable being pressed against the inner surface of the cable laying path. The proposed method of laying the sensitive element in the ground immediately provides close contact between the cable and the ground and prevents the cable from hanging in cavities in the ground. The main advantage of the proposed method of mechanized laying of fiber-optic cable in the ground is laying the cable to a given depth with permissible deviations in height and coordinates. Another advantage is the provision of tight contact between the fiber optic cable and the ground. Another advantage is the absence of air voids in the area where the cable runs after mechanical installation is completed. Another advantage is the acceleration of commissioning of the sensitive element of the system, since in this case it is not necessary to wait for natural sedimentation of the soil. The proposed method of mechanized laying of a fiber-optic signaling cable into the ground of a sensitive element of a long-term perimeter security system is carried out using a tractor with a vertical attachment (plow) with a channel for introducing flexible linear products into the lower zone of the plow. An unwinding device is installed on the tractor, on which a drum with a fiber optic cable is attached, for example, but not limited to, described with reference to FIG. 6. Before starting work, the cable is inserted into the input channel and attached to the ground, after which the tractor begins to move along a given route, ensuring the movement of the plow along a curved path. Before laying is completed, the plow is raised and the cable is released. After laying the cable, the tractor compacts the soil with its own weight, ensuring closure of the soil above the cable.

[126] Thus, as another method for mechanized laying of a fiber-optic cable in the ground, a method for mechanized laying of a fiber-optic cable in the ground is claimed, in which, before laying begins, the cable is inserted into the input channel of flexible linear products of the cable layer with the input channel of flexible linear products and with a vertical plow and attached to the ground, after which they move with a cable laying machine along a given curvilinear cable laying path, and along the entire path they alternately change the direction of the bending radius of the said path.

[127] Thus, as another fiber-optic security detector, a fiber-optic security detector is claimed, the linear part of which is laid in the ground in a mechanized manner, in which, before laying begins, the cable is inserted into the input channel of flexible linear products of the cable layer with the input channel of flexible linear products and a vertical plow and attached to the ground, after which they move with a cable laying machine along a given curvilinear cable laying path, and along the entire path they alternately change the direction of the bending radius of the said path. Optionally, the fiber-optic security detector contains a hardware delay line, made by connecting the required length of reserve cores of the fiber-optic cable into an optical circuit. Optionally, the fiber-optic security detector contains an optical circuit of a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains an optical circuit of a Michelson interferometer. Optionally, the fiber-optic security detector contains the optical circuit of a Sagnac interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Michelson interferometer and a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Sagnac interferometer and a Mach-Zehnder interferometer. Optionally, the fiber-optic security detector contains optical circuits of a Michelson interferometer and a Sagnac interferometer.

[128] Thus, a method for creating a protected boundary using a fiber-optic security detector can be provided, in which a protected perimeter is erected by laying the linear part of the fiber-optic security detector in the ground using a method of mechanized laying of a fiber-optic cable, in which, before starting During laying, the cable is inserted into the input channel of flexible linear products of the cable layer with the input channel of flexible linear products and a vertical plow and attached to the ground, after which the cable layer is moved along a given curved path of cable laying, and along the entire path the direction of the bending radius of the said path is alternately changed.

[129] In this case, dynamic fiber optic sensors (DOS), optionally used in conjunction with those previously described with reference to FIG. 1-5 fiber optic security detectors. The DOD is a sensor whose operating principle is based on the use of the properties of the optical circuit of the device to change the phase difference of the components of the signals reflecting the energy of the probing pulse depending on the rate of change in the geometric shape of the optical fiber (oscillations) of the sensitive part of the device, changed by the external vibration effect on the structure on which it is attached sensitive part of the device. A change in the phase difference of the component signals leads to a change in the interference pattern at the output of the optical splitter. The generation and injection of a probing pulse into an optical fiber and the collection of information about the value of signals from artificial reflections of the DOD are carried out using a reflectometer and a fiber-optic cable network branched out on splitters. Information processing is performed by a computing device. The range of placement of the DOD is determined by the energy of the probing pulse transferred to the DOD, and can reach tens of kilometers. DOD can be used in security alarm systems to monitor the impact on moving and fixed parts of structures, barriers, gates and wickets of the perimeters of small and extended areas, the impact on manhole covers of well spaces, and position sensors for culvert gratings. The use of DOD is allowed in explosive environments, in conditions of 100% humidity, in conditions of increased gas contamination and dust, when working in water, including sewage, in conditions of increased radiation, in conditions that exclude the possibility of using electrical devices, in conditions of high-power electromagnetic interference. The use of DOD does not require electrical energy in the linear part of the device. As shown in FIG. 10, preferably, but not limited to, the DOD 1000 includes a housing 1001, inside of which is installed an optical fiber reel 1002 that closes the outputs of the optical splitter 1003, which together constitute the sensitive part of the device. Preferably, without limitation, a transport part 1004 of the external part of the device is connected to the input of the splitter, providing transport of part of the energy of the probing pulse to the sensitive part of the device in the forward direction and providing transport in the opposite direction of the reflection signal modulated by the effect on the structure on which the DOD housing is fixed. Preferably, without limitation, the transport part ensures the delivery of probing pulses in the forward direction to all DODs, dividing the energy of the probing pulse into shares that ensure the formation of reflection signals from each DOD connected to the optical circuit in the optimal range, not exceeding the maximum value of the amplitude of the reflection signals at the analogue input - digital converter of the reflectometer, and delivery of signals reflecting the energy of probing pulses from the DOD in the opposite direction along the same delivery paths of probing pulses. Preferably, without limitation, the division of the energy of the probing pulse is carried out using splitters in any part of the transport part of the optical circuit of the detector, providing multiple and arbitrary connections of the DOD to the branched optical network, taking into account the optimal value of the energy of the probing pulse delivered to each DOD and the response time. Preferably, without limitation, the sensitive part of the DOD is made of optical fibers and a splitter, the outputs of which are connected to each other by an optical fiber coil and form a closed loop for generating a reflection signal. Preferably, without limitation, the presence of a coil in the DOD provides optical amplification of the phase difference between the reflection signals and the interference pattern at the output. Preferably, without limitation, the DOD coil is not rigidly fixed in the device body, ensuring the transmission of vibrations from the body to all fibers of the coil. Preferably, without limitation, the DOD coil is wound in the form of a coil without a frame with a diameter that ensures the passage of the probing pulse without significant attenuation of the probing pulse signal, and the number of turns of the coil provides a sufficient delay in the passage of the probing pulse signal, depending on the dynamic characteristics of the expected impact on the structure and the properties of the structure itself . Preferably, without limitation, reflection signals from all devices are formed at the input of the receiving device as a result of the passage of fractions of the probing pulse along a closed optical ring in the opposite direction through the branched optical network of the detector, on the branches of which DODs are located. Preferably, without limitation, the required amount of branched power to the DOD is significantly less than the initial value of the power at the output of the reflectometer and depends on the characteristics of the emitter, the sensitivity of the reflectometer receiving device and the distance of the DOD from the measuring device, which allows multiple branches to the DOD to be placed on one transport cable. Preferably, without limitation, the amount of branched power for each DOD, according to the operating principle of the device, can differ several times from each other without deteriorating the operation of the device, which allows the use of taps with both a wide branching range and a series of the same type. Preferably, without limitation, the power of the returned signal at the input of the receiving device generally does not exceed the saturation limits of the receiver device used and is not lower than an acceptable level comparable to the noise level. Preferably, without limitation, dynamically the magnitude of the reflected signal power exceeding the saturation limits of the receiving device does not disrupt the operation of the device. At the same time, the construction of a multi-point optical circuit for returning signals from the DOD makes it possible to ensure the most efficient operation of the device with low energy losses of signals returning to the receiving device, providing the maximum number of sensors on the same line of the device with point placement of sensors. In this case, when constructing the system, it is preferable to take into account the duration of the probing pulse, as well as the linear dimensions of the coil and transport cable, which is preferable to prevent competition (overlap) of the returned signals in time. Preferably, but not limited to, control of the competition of the returned signals in time is carried out, if necessary, either by the length of the coil or by optical delay lines, which are those previously described with reference to FIGS. 1-5 optical delay lines, made by connecting reserve cores of a fiber-optic cable into an optical chain, or by correction coils consisting of the same type of optical fiber of the required length.

[130] Preferably, without limitation, the DOD operates as follows. The operation of the DOD is based on a reflectometric measurement method and a method using a Sagnac interferometer. The reflectometer's probing pulse passes through the transport part of the device's fiber optic circuit and splitters, which ensure a reduction in the energy of fractions of the probing pulse to the sensitive part of each DOD. At the input of the splitter of the sensitive part of the DOD, the probing pulse is divided into two parts and then these parts follow the fibers of the coil in the opposite direction along the entire length of the coil. After the pulses pass through the coil, the two separated pulses are added again at the splitter. When adding signals, interference addition of two signals occurs and the magnitude of this signal at the output of the splitter will depend on the phase difference of the added signals, the value of which depends on the initial actual phase difference associated with the specific installation of the optical circuit of the device and its components. When exposed to the DOD, the phase difference changes in accordance with the force of the impact and the speed of vibration of the structure caused by this impact. As a result of vibrations of the structure, the magnitude of the output signal changes, modulated by the vibrations of the structure. Reflection signals arrive at the input of the receiving device sequentially in time, starting with the closest-in-distance DODs; the value of this delay is different for each DOD and characterizes its address. Based on the received data, the computing device determines the nature of the impact on the structure, the time and strength of the impact, and if the set values are exceeded, it generates an alarm.

[131] Thus, as a sensitive element of a dynamic fiber optic sensor, a sensitive element of a dynamic fiber optic sensor is declared, formed by a coil of optical fibers and a splitter, the outputs of which are closed to each other by the said coil and form a closed loop that generates a reflection signal, and the splitter is configured to connect with transport part of the fiber optic security detector. Optionally, the coil is designed in such a way that vibrations of the sensor body are transmitted to all fibers of the coil. Optionally, the coil is not rigidly mounted in the sensor body. Optionally, the coil is wound in the form of a coil without a frame with a diameter that allows the passage of the probing pulse without significant attenuation of the signal of the probing pulse. It is not necessary that the number of turns of the coil provides a sufficient delay in the passage of the probing pulse signal. Optionally, the sensing element provides regulation of the competition of the returned signals in time by the length of the coil, or by an optical delay line. Optionally, the optical delay line is made by connecting the reserve cores of a fiber-optic cable into an optical chain, or is made by a correction coil consisting of the same type of optical fiber of the required length.

[132] Thus, the housing of a dynamic fiber optic sensor (DOS) is a housing of a dynamic fiber optic sensor, configured to accommodate a sensitive element of the sensor formed by a coil of optical fibers and a splitter, the outputs of which are connected to each other by the said coil and form a closed loop, forming a reflection signal, and the splitter is configured to connect to the transport part of the fiber-optic security detector, and the coil is placed in the housing in such a way that vibrations of the sensor body are transmitted to all fibers of the coil. Optionally, the coil is not rigidly mounted in the sensor body. Optionally, the coil is wound in the form of a coil without a frame with a diameter that allows the passage of the probing pulse without significant attenuation of the signal of the probing pulse. Optionally, the number of turns of the coil provides a sufficient delay in the passage of the probing pulse signal. Optionally, the sensing element provides regulation of the competition of the returned signals in time by the length of the coil, or by an optical delay line. Optionally, the optical delay line is made by connecting the reserve cores of a fiber-optic cable into an optical chain, or is made by a correction coil consisting of the same type of optical fiber of the required length.

[133] Thus, a dynamic fiber optic sensor is declared as a dynamic fiber optic sensor (DOS), which is a housing designed to be mounted on a controlled structure, configured to accommodate a sensitive element of the sensor formed by a coil of optical fibers and a splitter, the outputs of which are closed between with the said coil and form a closed loop that generates a reflection signal, wherein the splitter is configured to connect to the transport part of the fiber-optic security detector. Optionally, the coil is placed in the housing in such a way that vibrations of the sensor housing are transmitted to all fibers of the coil. Optionally, the coil is not rigidly mounted in the sensor body. Optionally, the coil is wound in the form of a coil without a frame with a diameter that allows the passage of the probing pulse without significant attenuation of the signal of the probing pulse. Optionally, the number of turns of the coil provides a sufficient delay in the passage of the probing pulse signal. Optionally, the sensing element provides regulation of the competition of the returned signals in time by the length of the coil, or by an optical delay line. Optionally, the optical delay line is made by connecting the reserve cores of a fiber-optic cable into an optical chain, or is made by a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensor provides optical amplification of the phase difference between the reflection signals and the interference pattern at the output.

[134] Thus, as a fence with a movable element with a sensitive element of a dynamic fiber-optic sensor of a security fiber-optic detector placed on it, a fence with a movable element with a sensitive element of a dynamic fiber-optic sensor of a security fiber-optic detector placed on it is claimed, which is a fence, containing a movable element configured to accommodate a housing of a dynamic fiber optic sensor (DOD), wherein the DOD is a sensor containing a housing configured to accommodate the sensitive element of the sensor formed by a coil of optical fibers and a splitter, the outputs of which are closed to each other by the mentioned coil and form a closed loop that generates a reflection signal, and the splitter is configured to connect to the transport part of the fiber-optic security detector. Optionally, the coil is placed in the housing in such a way that vibrations of the sensor housing are transmitted to all fibers of the coil. Optionally, the coil is not rigidly mounted in the sensor body. Optionally, the coil is wound in the form of a coil without a frame with a diameter that allows the passage of the probing pulse without significant attenuation of the signal of the probing pulse. Optionally, the number of turns of the coil provides a sufficient delay in the passage of the probing pulse signal. Optionally, the sensing element provides regulation of the competition of the returned signals in time by the length of the coil, or by an optical delay line. Optionally, the optical delay line is made by connecting the reserve cores of a fiber-optic cable into an optical chain, or is made by a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensor provides optical amplification of the phase difference between the reflection signals and the interference pattern at the output. Optionally, the movable element is a gate. Optionally, the movable element is a gate. Optionally, the movable element is a hatch.

[135] Thus, as a protected boundary with a fence with a movable element with a sensitive element of a dynamic fiber-optic sensor of a security fiber-optic detector placed on it, a protected boundary is declared containing a fence with a movable element with a sensitive element of a dynamic fiber-optic sensor of a security fiber-optic detector placed on it -optical, which is a fence containing a movable element configured to accommodate the housing of a dynamic fiber optic sensor (DOD), wherein the DOD is a sensor containing a housing configured to accommodate the sensitive element of the sensor formed by a coil of optical fibers and a splitter , the outputs of which are connected to each other by the mentioned coil and form a closed loop that generates a reflection signal, and the splitter is configured to connect to the transport part of the fiber-optic security detector. Optionally, the coil is placed in the housing in such a way that vibrations of the sensor housing are transmitted to all fibers of the coil. Optionally, the coil is not rigidly mounted in the sensor body. Optionally, the coil is wound in the form of a coil without a frame with a diameter that allows the passage of the probing pulse without significant attenuation of the signal of the probing pulse. Optionally, the number of turns of the coil provides a sufficient delay in the passage of the probing pulse signal. Optionally, the sensing element provides regulation of the competition of the returned signals in time by the length of the coil, or by an optical delay line. Optionally, the optical delay line is made by connecting the reserve cores of a fiber-optic cable into an optical chain, or is made by a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensor provides optical amplification of the phase difference between the reflection signals and the interference pattern at the output. Optionally, the movable element is a gate. Optionally, the movable element is a gate. Optionally, the movable element is a hatch.

[136] Thus, as a signaling method using a sensitive element of a dynamic fiber-optic sensor of a security fiber-optic detector located on a movable element of a fence, a signaling method is claimed using a sensitive element of a dynamic fiber-optic sensor (DOD) of a security fiber-optic detector placed on a movable element of a fence , in which the DOD housing is placed on a movable element of the fence structure, wherein the DOD is a sensor containing a housing configured to accommodate a sensitive element of the sensor formed by a coil of optical fibers and a splitter, the outputs of which are connected to each other by the said coil and form a closed loop , generating a reflection signal, wherein the splitter is configured to connect to the transport part of the security fiber-optic detector, the probing pulse of the reflectometer of the security fiber-optic detector is supplied through the transport part and the splitters of the detector to the sensitive element of the DOD, the probing pulse at the input to the DOD is divided into two parts using a splitter of the sensitive element to direct them along the fibers of the coil in the opposite direction, after passing parts of the pulse, they are added on the said splitter, after which they are fed to the input of the reflectometer receiving device and, by means of a computing device, the change in the phase difference of the signals on the said splitter is recorded. Optionally, the coil is placed in the housing such that vibrations of the sensor housing are transmitted to all fibers of the coil. Optionally, the coil is not rigidly mounted in the sensor body. Optionally, the coil is wound in the form of a coil without a frame with a diameter that allows the passage of the probing pulse without significant attenuation of the signal of the probing pulse. Optionally, a number of coil turns is provided to provide a sufficient delay in the passage of the probing pulse signal. Optionally, they provide regulation of the competition of the returned signals in time by the length of the coil, or by an optical delay line. Optionally, the optical delay line is made by connecting the reserve cores of a fiber-optic cable into an optical chain, or is made by a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensor provides optical amplification of the phase difference between the reflection signals and the interference pattern at the output.

[137] In this case, on the moving and fixed parts of the structures of the protected boundaries described in this document, end-of-fiber sensors (COD) can be placed, optionally used in conjunction with those described earlier with reference to FIG. 1-5 fiber optic security detectors. The CODE is a sensor whose operating principle is based on the use of the design and properties of the optical fiber to change the transmission capacity of laser radiation depending on the geometric shape and size of the optical fiber, changed by a pusher within the elastic deformation of the shape of the optical fiber of the sensitive part at one frequency of laser radiation and maintaining capacity under the same deformations at a different frequency. Preferably, without limitation, the collection of information about the positions of the working parts of the sensor is carried out using a computing device for processing information, a reflectometer and a fiber-optic cable network branched out on splitters. Preferably, without limitation, the range of placement of the CODE is determined by the level of attenuation of the signal of the probing pulse assigned to the CODE, which is not lower than the required value. Preferably, without limitation, the COD can be used in systems remote over long distances, where there are no sources of electrical energy, in security alarm systems, to control the position of gates and wickets on the perimeter of small and extended areas, the position of manhole covers in well spaces, position sensors for culvert gratings , signaling the condition of walls for damage and breaches, and the like, including use in explosive environments, in conditions of 100% humidity, increased gas contamination and dust, when working in water, including sewage, in conditions of increased radiation, in conditions excluding possibility of using electrical devices in conditions of high power electromagnetic interference. Preferably, without limitation, the proposed CODE uses two sources of laser radiation of different frequencies - working and diagnostic. Preferably, but not limited to, the use of diagnostic laser radiation is periodic. At the same time, there is the task of constantly monitoring the serviceability of the code. Preferably, but not limited to, this problem is achieved by providing a CODE configured to operate with a switchable range reflectometer. Preferably, without limitation, the KOD 2000 contains a housing 2001 with a pusher 2002, which ensures a change in the position of the rings 2003 of the optical fibers of the sensitive part, a sensitive part that is installed in the KOD housing and connected through a splitter 2004 to the transport part 2005 of the security fiber optic detector, which provides the connection of the KOD to an extensive optical network and transport of laser pulses in the forward and reverse directions. Preferably, without limitation, the sensitive part of the sensor is made of a splitter 2004, the outputs of which are connected to each other by an optical fiber of a certain shape and together form a closed loop for generating a reflection signal and a return signal. Preferably, without limitation, the change in the geometric position of the fibers in the sensitive part of the COD in the elastic range of deformations due to a change in the position of the working element is such that it leads to a change in the possibility of passing reflection signals in the operating frequency range of the laser radiation of the reflectometer and transmits reflection signals in both positions of the working element in the diagnostic frequency range of laser radiation, providing information with a signal about the health of the optical circuit of the sensor. Preferably, without limitation, in the claimed solution, the sensitive part of the sensor is a closed loop in the form of several rings with a bending radius in the elastic range of deformations, allowing free passage of the reflection signal of the probing pulse at the operating frequency, and in the second position of the working element, the bending radius of the rings changes in the elastic range range of deformations to a form in which the signal of the probing pulse is absorbed in parts in the optical fiber shell of the sensitive part of the code in places with the smallest radii to the required minimum value of the reflection signal, while ensuring the possibility of monitoring the serviceability of the sensor at the diagnostic frequency of laser radiation, that is, a laser pulse of a different frequency continues to pass through the rings. Preferably, without limitation, as shown in FIG. 11, in the claimed solution, the change in the spatial shape of the optical fiber of the sensitive part of the CODE is carried out through rods (holders) 2006 with grips 2007 located on different sides of the rings 2003 of the sensitive element, and one of the holders 2006 is connected to the movable part of the working body of the CODE (pusher 2002), and others - with the base of the building 2001 CODE. Preferably, but not limited to, the grips 2007 are in the form of a standard heat-shrink tubing (weld protection kit) used to secure optical fiber splices, the length of the standard heat-shrink tubing being preferably cut down. Preferably, without limitation, a metal rod 2006, preferably curved, preferably L-shaped, is inserted into said tube 2007, and the rod 2006 is secured by screws 2008 attached to the base of the housing and to the pusher 2002. Preferably, without limitation, as a sensitive The CODE element uses optical fiber of the G652 standard of all modifications (it is allowed to use fiber from the fiber-optic cable used in the security detector). In this case, preferably, without limitation, the geometric dimensions of the rings 2003 and the magnitude of their bends vary in the following ranges: the grip width of the heat-shrinkable tubes is 5±2 mm, the diameter of the turns in the unstressed state in the shape of a circle is 20±2 mm. In this case, the technological length of the optical fibers of the leads should preferably be at least 1000 mm and provide the possibility of welding work, their repetition should preferably be at least 4 times, the number of turns should be from 8 to 12. In this case, the minimum distance of the opposite sides of the rings at maximum compression is preferable is at least 4±2mm, the maximum removal of the opposite sides during tension should preferably ensure a minimum bending radius of the rings in the fastening area of at least 4±1mm, and the maximum stroke of the moving part is no more than 12±2mm, which, together with the elastic properties of the metal rods, ensures safe manufacturing the sensor, switching on and further adjustment, including the ability to continuously monitor the health of the sensor and perform its main function. By way of example, and not limitation, the CODE has two main sensing positions, as shown in FIG. 12 - in the first, the bending radius of the fiber is more than the minimum critical value, and, preferably, without limitation, the probing pulse and the reflected signal move freely in the fiber core in both directions, and especially at a diagnostic frequency with a shorter wavelength. In the second main position of the sensitive part of the sensor, the fiber bending radius is less than the critical value at which the probing pulse at the operating wavelength, reaching the fiber bending point, penetrates the fiber cladding and is absorbed in it, as a result of which a reflection signal is not formed, but preferably not being limited, a pulse at a diagnostic frequency with a shorter wavelength continues to pass through the rings creating reflection signals and confirming the proper operation of the sensor. Preferably, without limitation, in such a COD design, the absorption of the energy of the probing pulse during compression of the coil occurs twice in each turn of the ellipsoidal deformation shape of the optical fiber 2001, which makes it possible to significantly increase the minimum value of the bending radius of the ellipse at which the energy of the probing pulse is sufficiently completely absorbed. Preferably, without limitation, the reflection signals are formed at the input of the receiver device as a result of the passage of the probing pulse in the forward and reverse directions through a branched optical network, on the branches of which the CODE is located. Preferably, without limitation, the branched optical network serves as a transport and power divider for the probing pulse directed to the CODE. Preferably, without limitation, the required amount of branched power to the COD is, as a rule, significantly less than the initial value of the power at the output of the reflectometer and depends on the characteristics of the emitter, the sensitivity of the reflectometer receiving device and the distance of the COD from the measuring device, which allows many branches to be placed on one transport cable to CODE. Preferably, without limitation, the amount of branched power for each code according to the principle of operation of the device can differ several times, without deteriorating the operation of the device, which allows the use of taps with a wide branching range. Preferably, without limitation, the power of the returned signal at the input of the receiving device generally does not exceed the saturation limits of the applicable receiving device and is not below an acceptable level comparable to the noise level. Preferably, but not limited to, the power of the reflected signal exceeding the saturation limits of the receiving device does not impair the operation of the device. Preferably, without limitation, the main result of collecting information from the CODE is the ratio of the power of the returned signal in one of the sensor positions to the power of the returned signal in another position. Preferably, without limitation, the ratio of the power of the returned signal in different COD states can reach tens or more times and be considered by the measurement system as discrete signals “there is a signal” or “there is no signal.” Preferably, without limitation, when diagnosing a code at a higher radiation frequency, the returned signal is considered by the system as discrete "good" or "fault" signals. Preferably, without limitation, the CODE contains a housing with a lever mechanism that ensures the movement of optical fibers of the sensitive part of the CODE, a piece of fiber-optic transport cable for connecting to an extensive optical network and transporting laser pulses in the forward and reverse directions, and a sensitive part, changes in the position of which lead to changes in its transmission and reflectivity, moreover, the geometric dimensions of the rings of the sensitive part and the extreme working positions of the pusher of the working body KOD must ensure the passage of probing pulse signals in one of the positions of the working body at the operating frequency, blocking of the probing pulse signals in another position of the working body and the passage of signals at the control frequency probing pulse in any state of the working body. Preferably, without limitation, the CODE is an optical-mechanical structure in which, due to a change in the position of the working body of the sensor, the power of the returned signals changes, for example, the design of the closest analogue described in patent RU 172554, included in this description by reference, with the exception other design of grips and holders, as described in this document. Using rods with heat-shrinkable tubes as grips instead of double heat-shrinkable tubes greatly simplifies the sensor manufacturing process, and also provides flexible adjustment of the sensor's operating mode due to the fact that the rods can be adjusted using screws. Preferably, without limitation, the position of the working body is changed by acting on the elements of the working body. Preferably, without limitation, the ability of the sensor to change the value of the return pulse is produced by changing the bend radius and orientation of the optical fiber of the sensitive part of the sensor to less than the value at which the integrity and elastic properties of the optical fiber are maintained, and the optical beam of the probing pulse at the bending points penetrates the fiber cladding and is absorbed in it. Preferably, without limitation, the construction of a multi-point optical circuit for returning signals from sensors allows for the most efficient circuit with low energy losses of return signals to the receiving device, providing the maximum number of sensors on one line of the device. In this case, when constructing the system, preferably, without limitation, the duration of the probing pulse, the linear dimensions of the sensitive elements and the transport cable are taken into account. Preferably, without limitation, in order to prevent competition (overlap) of the returned signals in time, optical delay lines are used, which are the previously described with reference to FIGS. 1-5 optical delay lines, made by connecting reserve cores of a fiber-optic cable into an optical chain, or correction coils consisting of the same type of optical fiber of the required length.

[138] Preferably, without limitation, the CODE operates as follows. Preferably, without limitation, the operation of the device is based on the following principles: a) receiving a reflection signal from the end of a line connected to the sensor of sufficient power to confidently identify its location and the magnitude of the reflection; b) the ratio of the power of the reflection signal in the state of maximum capacity of the sensor to the power of the reflection signal in the state of minimum capacity of the sensor and line must provide an unambiguous determination of the state of the sensor for any designated values of interference factors affecting the line and sensor, such as, but not limited to, temperature, pressure, humidity, gas contamination, excess moisture, etc. Preferably, without limitation, the KOD pusher is placed on any movable element of any fence to be controlled, and the body is placed on a fixed corresponding element of the fence, for example, without limitation, a pillar, door slope, wall, etc., so that the pusher is placed in the direction of movement of the movable element of the fence. When the moving element of the fence moves, it puts pressure on the pusher, which in turn, through the rods, forces the optical fiber ring of the sensitive part of the sensor to compress, which leads to a change in its geometry to a certain ellipse shape, and therefore the reflection signals stop arriving at the splitter and return to the receiver transceiver device of the fiber-optic security detector, which indicates that the sensor is triggered. At the same time, at some other frequency the signals continue to arrive, which indicates that the sensor is working properly. Failure to receive any signals from the sensor splitter indicates its damage and/or malfunction. As shown in FIG. 12 in another embodiment, preferably, without limitation, the CODE contains a sensitive element of the sensor, made in the form of two sets of optical fiber rings 2003, and each set of rings is made with its own grippers 2007 - two at the edges on each set of rings 2001 and two in the middle on a common holder 2006. Preferably, without limitation, the common holder 2006 is secured by means of screws 2008 to a movable part of the sensor body moved by the sensor working body, and the other two holders 2006 are attached to a stationary part of the housing (not shown in the drawing). Preferably, but not limited to, the distance between the outer jaws should ensure that one ring is fully released to the size of a circle and the second ring is compressed to an elliptical shape and vice versa in the other position of the sensor. Preferably, without limitation, the operating principle of the sensor is similar to the operation of the sensor in the previous embodiment, except that the reflection signals from different sensor rings are in an inverse relationship to each other, which provides continuous diagnostics of the health of the sensor based on the two reflection signals. Preferably, without limitation, the sensor state can be additionally read by two independent reflectometers, taking into account signal inversion. Preferably, without limitation, the distance between the extreme positions of the grips should ensure that the rings are completely released to the size of a circle and both rings are compressed to the size of an ellipse of the required shape. Preferably, without limitation, the operation of the CODE is similar to the operation of the CODE described previously, except that two independent rings are used, which provides continuous diagnostics of the health of the sensor using two reflection signals. Preferably, without limitation, the sensor status can be additionally read by two independent reflectometers. Preferably, without limitation, it is ensured that several codes are built in a sequential chain, which makes it possible to use a small part of the power of the probing pulse and deliver the energy of return signals to the receiving device as efficiently as possible, providing the ability to connect the maximum number of sensors on one line of the device. Preferably, without limitation, the sensitive part of the CODE in the case of a serial connection of the CODE is a closed loop in the form of optical fibers rolled into rings and connected to a fiber optic cable without a splitter, which ensures the formation of a single signal about the state of the sensors using the “OR” logic. Preferably, without limitation, the splitter and fiber optic cables of the sensors are installed in the outer casing of the optical circuit of the device (connecting coupling), while the splitter is closed by the common optical circuit of all sensors, such that in one of the positions of the object the rings of all sensors are in a state allowing free passage of the probing pulse signal through all sensors and, if the state of the object changes so that at least one of the sensors changes the shape of the ring to a state in which the probing pulse signal is absorbed in the optical fiber cladding, the reflection signal at the operating frequency of the laser radiation disappears, but maintained at the diagnostic frequency. Preferably, without limitation, in all embodiments, the probing pulse from the reflectometer passes through the transport part of the fiber optic circuit to the sensitive part of the CODE. Preferably, without limitation, in one of the positions of the COD working body when the bending radii of the fiber of the sensitive part are more critical values, the laser pulse propagates in the fiber with virtually no losses. Preferably, without limitation, with any method of generating a signal in this position of the working element, the reflection signal arrives at the input of the receiving device, signaling the presence of a reflection signal from a certain sensor, that is, with a certain time delay. Preferably, without limitation, when changing the position of the working body of the COD, it is ensured that the bending radius of the fiber in the elastic range is less than the value at which the probing pulse, reaching the point of bending of the fiber, begins to penetrate into the fiber sheath and is absorbed in it, as a result of which the signal does not pass through a closed loop. no loop or reflection is formed. Preferably, without limitation, when a laser pulse passes in diagnostic mode at a higher frequency (shorter wavelength), the bending radii of the fiber are such that they do not interfere with the passage of the pulse, and reflection signals are generated, indicating the health of the sensor circuit.

[139] Thus, as an end-of-fiber optic sensor, an end-of-fiber optic sensor is claimed, containing a housing with a pusher that ensures a change in the position of the rings of optical fibers of the sensitive part and a sensitive part made of a splitter, the outputs of which are closed to each other by an optical fiber rolled into a ring and together form a closed loop, wherein said ring is connected to said pusher and said body by means of rods, which together with the ring are stretched inside a corresponding heat-shrinkable tube. Optionally, the ring of the optical fiber is configured to change its spatial shape to a state in which, at the first frequency of the laser radiation, parts of the probing pulses in the optical fiber are absorbed by its cladding, and the reflection signals continue to be formed at the second frequency of the laser radiation. Optionally, the heat shrink tubing mentioned is a standard weld joint protection kit (SWSP). Optionally, said rods are connected, respectively, to the housing and the pusher through corresponding adjusting screws. Optionally, the change in the spatial shape of the optical fiber of the sensitive part of the COD is carried out through grips located on different sides of the rings of the sensing element, some of the grips are connected to the movable part of the working body of the COD, others - to the base of the COD body. Optionally, the code is configured to adjust the address of the sensor in the fiber optic security detector system. Optionally, the sensor address is adjusted by changing the length of the optical delay line or the length of the transport part to the code. Optionally, the optical delay line is an optical delay line made of reserve cores of a fiber-optic cable connected into an optical circuit, or made in the form of a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensitive part is formed by several optical fibers rolled into different rings, with some rings being in a state that allows the free passage of the probing pulse signal, and other rings in a state in which the probing pulse signal is absorbed in parts in the cladding of the optical fiber of the sensitive part in places with the smallest radii to the required minimum value of the reflection signal, while in the second position of the working body, the positions of the rings are reversed, providing an inverse state of the reflection signals. Optionally, the sensitive part is a closed loop in the form of optical fibers, rolled into rings and connected to a fiber-optic cable without a splitter for sequential connection of several sensors to each other with the formation of a single signal about the state of the sensors using the “OR” logic, and the splitter and fiber-optic cables of the sensors are installed in the outer casing of the optical circuit of the device, while the splitter is closed by the common optical circuit of all sensors in such a way that in one of the positions of the working body, the rings of all sensors are in a state that allows the free passage of the probing pulse signal through all sensors and, if the state of the object changes so, that at least one of the sensors changes the shape of the ring to a state in which the signal of the probing pulse is absorbed in the cladding of the optical fiber, the reflection signal at the operating frequency of the laser radiation disappears, but remains at the diagnostic frequency.

[140] Thus, a fiber optic security detector containing an end fiber optic sensor, the pusher of which is placed on a movable element of the fence, containing a housing with a pusher that ensures a change in the position of the optical fiber rings of the sensitive part, is claimed as a fiber optic security detector with an end fiber optic sensor. and a sensitive part made of a splitter, the outputs of which are closed to each other by an optical fiber rolled into a ring and together form a closed loop, wherein said ring is connected to said pusher and said body by means of rods, which together with the ring are stretched inside the corresponding heat-shrinkable tube. Optionally, the ring of the optical fiber is configured to change its spatial shape to a state in which, at the first frequency of the laser radiation, parts of the probing pulses in the optical fiber are absorbed by its cladding, and the reflection signals continue to be formed at the second frequency of the laser radiation. Optionally, the heat shrink tubing mentioned is a standard weld joint protection kit (SWSP). Optionally, said rods are connected, respectively, to the housing and the pusher through corresponding adjusting screws. Optionally, the change in the spatial shape of the optical fiber of the sensitive part of the COD is carried out through grips located on different sides of the rings of the sensing element, some of the grips are connected to the movable part of the working body of the COD, others - to the base of the COD body. Optionally, the code is configured to adjust the address of the sensor in the fiber optic security detector system. Optionally, the sensor address is adjusted by changing the length of the optical delay line or the length of the transport part to the code. Optionally, the optical delay line is an optical delay line made of reserve cores of a fiber-optic cable connected into an optical circuit, or made in the form of a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensitive part is formed by several optical fibers rolled into different rings, with some rings being in a state that allows the free passage of the probing pulse signal, and other rings in a state in which the probing pulse signal is absorbed in parts in the cladding of the optical fiber of the sensitive part in places with the smallest radii to the required minimum value of the reflection signal, while in the second position of the working body, the positions of the rings are reversed, providing an inverse state of the reflection signals. Optionally, the sensitive part is a closed loop in the form of optical fibers, rolled into rings and connected to a fiber-optic cable without a splitter for sequential connection of several sensors to each other with the formation of a single signal about the state of the sensors using the “OR” logic, and the splitter and fiber-optic cables of the sensors are installed in the outer casing of the optical circuit of the device, while the splitter is closed by the common optical circuit of all sensors in such a way that in one of the positions of the working body, the rings of all sensors are in a state that allows the free passage of the probing pulse signal through all sensors and, if the state of the object changes so, that at least one of the sensors changes the shape of the ring to a state in which the signal of the probing pulse is absorbed in the optical fiber cladding, the reflection signal at the operating frequency of the laser radiation disappears, but remains at the diagnostic frequency.

[141] Thus, as a fence with a movable element with an end fiber optic sensor of a security fiber optic detector placed on it, a fence with a movable element with a sensor pusher placed on it is claimed, which is an end fiber optic sensor containing a housing with a pusher that provides a change in position rings of optical fibers of the sensitive part and a sensitive part made of a splitter, the outputs of which are closed to each other by an optical fiber rolled into a ring and together form a closed loop, wherein said ring is connected to said pusher and said body by means of rods, which, together with the ring, are stretched inside the corresponding heat-shrinkable tubes. Optionally, the ring of the optical fiber is configured to change its spatial shape to a state in which, at the first frequency of the laser radiation, parts of the probing pulses in the optical fiber are absorbed by its cladding, and the reflection signals continue to be formed at the second frequency of the laser radiation. Optionally, the heat shrink tubing mentioned is a standard weld joint protection kit (SWSP). Optionally, said rods are connected, respectively, to the housing and the pusher through corresponding adjusting screws. Optionally, the change in the spatial shape of the optical fiber of the sensitive part of the COD is carried out through grips located on different sides of the rings of the sensing element, some of the grips are connected to the movable part of the working body of the COD, others - to the base of the COD body. Optionally, the code is configured to adjust the address of the sensor in the fiber optic security detector system. Optionally, the sensor address is adjusted by changing the length of the optical delay line or the length of the transport part to the code. Optionally, the optical delay line is an optical delay line made of reserve cores of a fiber-optic cable connected into an optical circuit, or made in the form of a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensitive part is formed by several optical fibers rolled into different rings, with some rings being in a state that allows the free passage of the probing pulse signal, and other rings in a state in which the probing pulse signal is absorbed in parts in the cladding of the optical fiber of the sensitive part in places with the smallest radii to the required minimum value of the reflection signal, while in the second position of the working body, the positions of the rings are reversed, providing an inverse state of the reflection signals. Optionally, the sensitive part is a closed loop in the form of optical fibers, rolled into rings and connected to a fiber-optic cable without a splitter for sequential connection of several sensors to each other with the formation of a single signal about the state of the sensors using the “OR” logic, and the splitter and fiber-optic cables of the sensors are installed in the outer casing of the optical circuit of the device, while the splitter is closed by the common optical circuit of all sensors in such a way that in one of the positions of the working body, the rings of all sensors are in a state that allows the free passage of the probing pulse signal through all sensors and, if the state of the object changes so, that at least one of the sensors changes the shape of the ring to a state in which the signal of the probing pulse is absorbed in the cladding of the optical fiber, the reflection signal at the operating frequency of the laser radiation disappears, but remains at the diagnostic frequency. Optionally, the movable element is one of: a gate, a gate, a hatch, a door.

[142] Thus, as a protected boundary with a fence with a movable element with an end fiber optic sensor of a security fiber optic detector placed on it, a protected boundary is declared containing a fence with a movable element with a sensor pusher placed on it, which is an end fiber optic sensor containing a housing with a pusher that ensures a change in the position of the rings of optical fibers of the sensitive part and a sensitive part made of a splitter, the outputs of which are closed to each other by an optical fiber rolled into a ring and together form a closed loop, wherein said ring is connected to said pusher and said body by means of rods that together with the ring are stretched inside the corresponding heat-shrinkable tube. Optionally, the ring of the optical fiber is configured to change its spatial shape to a state in which, at the first frequency of the laser radiation, parts of the probing pulses in the optical fiber are absorbed by its cladding, and the reflection signals continue to be formed at the second frequency of the laser radiation. Optionally, the heat shrink tubing mentioned is a standard weld joint protection kit (SWSP). Optionally, said rods are connected, respectively, to the housing and the pusher through corresponding adjusting screws. Optionally, the change in the spatial shape of the optical fiber of the sensitive part of the COD is carried out through grips located on different sides of the rings of the sensing element, some of the grips are connected to the movable part of the working body of the COD, others - to the base of the COD body. Optionally, the code is configured to adjust the address of the sensor in the fiber optic security detector system. Optionally, the sensor address is adjusted by changing the length of the optical delay line or the length of the transport part to the code. Optionally, the optical delay line is an optical delay line made of reserve cores of a fiber-optic cable connected into an optical circuit, or made in the form of a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensitive part is formed by several optical fibers rolled into different rings, with some rings being in a state that allows the free passage of the probing pulse signal, and other rings in a state in which the probing pulse signal is absorbed in parts in the cladding of the optical fiber of the sensitive part in places with the smallest radii to the required minimum value of the reflection signal, while in the second position of the working body, the positions of the rings are reversed, providing an inverse state of the reflection signals. Optionally, the sensitive part is a closed loop in the form of optical fibers, rolled into rings and connected to a fiber-optic cable without a splitter for sequential connection of several sensors to each other with the formation of a single signal about the state of the sensors using the “OR” logic, and the splitter and fiber-optic cables of the sensors are installed in the outer casing of the optical circuit of the device, while the splitter is closed by the common optical circuit of all sensors in such a way that in one of the positions of the working body, the rings of all sensors are in a state that allows the free passage of the probing pulse signal through all sensors and, if the state of the object changes so, that at least one of the sensors changes the shape of the ring to a state in which the signal of the probing pulse is absorbed in the cladding of the optical fiber, the reflection signal at the operating frequency of the laser radiation disappears, but remains at the diagnostic frequency. Optionally, the movable element is one of: a gate, a gate, a hatch, a door.

[143] Thus, as a signaling method using an end-of-fiber optic sensor of a fiber-optic security detector, a signaling method is claimed using an end-of-fiber optic sensor of a fiber-optic security detector, in which a probing pulse is supplied from the reflectometer of the fiber-optic security detector to the sensitive part of the sensor, wherein the sensor is an end-of-fiber optical sensor containing a housing with a pusher that ensures a change in the position of the rings of optical fibers of the sensitive part and a sensitive part made of a splitter, the outputs of which are closed to each other by an optical fiber rolled into a ring and together form a closed loop, wherein the said ring is connected to the mentioned pusher and the mentioned body by means of rods, which together with the ring are stretched inside the corresponding heat-shrinkable tube, when the position of the pusher changes, the absence of a signal is recorded. Optionally, the optical fiber ring is configured to change its spatial shape to a state in which, at the first laser radiation frequency, parts of the probing pulses in the optical fiber are absorbed by its cladding, and reflection signals continue to be formed at the second laser radiation frequency. Optionally, the heat shrink tubing mentioned is a standard weld joint protection kit (SWSP). Optionally, said rods are connected to the body and the pusher respectively by means of corresponding adjusting screws. Optionally, the change in the spatial shape of the optical fiber of the sensitive part of the COD is carried out through grips located on different sides of the rings of the sensitive element, and some of the grips are connected to the movable part of the working body of the COD, others - to the base of the COD body. Optionally, the code is configured to adjust the address of the sensor in the fiber optic security detector system. Optionally, the sensor address is adjusted by changing the length of the optical delay line or the length of the transport part to the code. Optionally, the optical delay line is an optical delay line made of reserve cores of a fiber-optic cable connected into an optical circuit, or made in the form of a correction coil consisting of the same type of optical fiber of the required length. Optionally, the sensitive part is formed by several optical fibers coiled into different rings, with some rings being in a state that allows the free passage of the probing pulse signal, and other rings in a state in which the probing pulse signal is absorbed in parts in the cladding of the optical fiber of the sensitive part in places with the smallest radii to the required minimum value of the reflection signal, while in the second position of the working body the positions of the rings are reversed, ensuring an inverse state of the reflection signals. Optionally, the sensitive part is a closed loop in the form of optical fibers, rolled into rings and connected to a fiber-optic cable without a splitter for sequential connection of several sensors to each other with the formation of a single signal about the state of the sensors using the “OR” logic, and the splitter and fiber-optic cables of the sensors are installed in the outer casing of the optical circuit of the device, while the splitter is closed by the common optical circuit of all sensors in such a way that in one of the positions of the working body, the rings of all sensors are in a state that allows the free passage of the probing pulse signal through all sensors and, if the state of the object changes so, that at least one of the sensors changes the shape of the ring to a state in which the signal of the probing pulse is absorbed in the cladding of the optical fiber, the reflection signal at the operating frequency of the laser radiation disappears, but remains at the diagnostic frequency. Optionally, the movable element is one of: wicket, gate, hatch, door

[144] This description of the claimed invention demonstrates only particular embodiments and does not limit other embodiments of the claimed invention, since possible other alternative embodiments of the claimed invention, not beyond the scope of the information set forth in this application, should be obvious to a specialist in the field technicians with normal qualifications for whom the claimed invention is intended.

Claims (3)

1. A method for mechanized laying of a fiber-optic cable in the ground, in which a mechanized cable-laying machine with an input channel for flexible linear products and a V-shaped plow, made with the possibility of attaching an unwinding device to it for installing a drum on it, is used to lay a fiber-optic cable in the ground. with a fiber-optic cable for mechanized laying of a fiber-optic cable in the ground, in which water is supplied to the input channel of flexible linear elements to ensure better contact of the cable with the ground, and upon completion of laying, subsequent compaction is carried out with a cable-laying machine; and/or the cable is laid along a curved path with an alternating change in the direction of the bend radius of the path in such a way as to ensure cable tension during the laying process. 2. The method according to claim 1, characterized in that the drum is made in such a way that there are slots on the side walls of the drum for leading the fiber-optic cable to the outside of the drum wall and bringing it back. 3. The method according to claim 1, characterized in that the drum is made in such a way that the side walls of the drum are made in such a way as to ensure free rotation of the drum on the axis of rotation.