CN113776643B - Optical fiber fence intrusion signal simulation equipment based on Michelson interferometer - Google Patents

Abstract

The invention discloses optical fiber fence intrusion signal simulation equipment based on a Michelson interferometer, which is characterized by comprising a narrow linewidth laser, a Michelson optical fiber interferometer based on a 3 multiplied by 3 optical fiber coupler, a first wavelength division multiplexer WDM-1, a second wavelength division multiplexer WDM-2, a piezoelectric ceramic PZT for winding an optical fiber and a demodulation circuit board provided with a first photoelectric detector PD1 and a second photoelectric detector PD2, which are sequentially connected. The device adopts the optical fiber interferometer to detect and demodulate the intrusion behavior vibration signal on the sensing optical cable and adopts the PZT to simulate and output the vibration signal, thereby realizing better data source coverage of the distributed optical fiber vibration sensor mode identification training.

Description

Optical fiber fence intrusion signal simulation equipment based on Michelson interferometer

Technical Field

The invention relates to an optical fiber sensing technology, in particular to auxiliary equipment for intrusion signal mode recognition training of a distributed optical fiber vibration sensor, and particularly relates to optical fiber fence intrusion signal simulation equipment based on a Michelson interferometer.

Background

The distributed optical fiber vibration sensor device can be used in the fields of optical fiber fences, optical cable physical safety monitoring and the like, and the difficulty of safety inspection can be greatly reduced. The most interesting performance of the optical fiber fence equipment is mainly focused on the false alarm rate of early warning and monitoring, and the false alarm rate of perimeter security equipment is reduced by adopting a scene mode identification technology at present. The performance improvement and verification method of the pattern recognition software generally performs field verification by collecting intrusion signals and environmental noise signals through an external field, or performs pattern recognition training on stored collected signals; the mode of adopting outfield mode recognition training often is difficult to guarantee for a long time in time, and the mode of adopting the collection signal of storage to carry out mode recognition training has the problem that information quantity is limited again, and mode recognition training coverage is not good for the fiber fence mode recognition training condition can not be effectively ensured.

Disclosure of Invention

The invention aims to provide an optical fiber fence intrusion signal simulation device based on a Michelson interferometer, aiming at the defects of the existing mode recognition training condition guarantee technology of the optical fiber fence. The device can realize the fidelity copying of the intrusion signal on the external field sensing optical cable, and is connected with any position of the sensing optical cable to be tested to simulate and output the intrusion signal for pattern recognition training.

The technical scheme for realizing the aim of the invention is as follows:

an optical fiber fence intrusion signal simulation device based on a Michelson interferometer comprises a narrow linewidth laser, a Michelson optical fiber interferometer based on a 3X 3 optical fiber coupler, a first wavelength division multiplexer WDM-1, a second wavelength division multiplexer WDM-2, a piezoelectric ceramic PZT for winding optical fibers and a demodulation circuit board provided with a first photoelectric detector PD1 and a second photoelectric detector PD2, wherein the narrow linewidth laser outputs high-coherence laser to be connected with a 1 port of the 3X 3 optical fiber coupler and split into three beams, the three beams are respectively output by 4, 5 and 6 ports of the 3X 3 optical fiber coupler, the 4 port of the 3X 3 optical fiber coupler is connected with a transmission port of the first wavelength division multiplexer WDM-1, a reflecting end of the first wavelength division multiplexer WDM-1 is connected with a first optical interface X1, a public end of the first wavelength division multiplexer WDM-1 is connected with a second optical interface X2, the second optical interface X2 is connected with a third optical interface X3 through an external sensing optical cable or an optical fiber jumper, the third optical interface X3 is connected with an optical input end of a piezoelectric ceramic PZT wound with an optical fiber, an optical output end of the piezoelectric ceramic PZT wound with the optical fiber is connected with a public end of a second wavelength division multiplexer WDM-2, a reflecting end of the second wavelength division multiplexer WDM-2 is connected with a fourth optical interface X4, a transmitting end of the second wavelength division multiplexer WDM-2 is connected with a first Faraday magnetic rotating reflector FRM-1 to reflect a narrow linewidth laser primary path back to a 3X 3 optical fiber coupler as a detection optical signal, a narrow linewidth laser entering the second Faraday magnetic rotating reflector FRM-2 connected with a port of the 3X 3 optical fiber coupler 6 is output by a port of the 3X 3 optical fiber coupler and reflected back to the 3X 3 optical fiber coupler is used as a reference optical signal, in addition, the 2 port and the 3 port of the 3×3 fiber coupler are respectively connected with the first photoelectric detector PD1 and the second photoelectric detector PD2 on the demodulation plate, the output end of the demodulation plate is connected with the piezoelectric ceramic PZT of the winding fiber, and a voltage control signal is output through the demodulation plate and enters the piezoelectric ceramic PZT of the winding fiber.

The working wavelength of the narrow linewidth laser is at least 0.8nm different from the working wavelength of the optical fiber vibration sensor built-in laser externally connected with the first optical interface X1 or the fourth optical interface X4, and the frequency interval is above 100 GHz.

The first wavelength division multiplexer WDM-1 and the second wavelength division multiplexer WDM-2 are respectively provided with three optical fiber ports of a public end, a transmission end and a reflection end, wherein the working bandwidths of the transmission ends of the first wavelength division multiplexer WDM-1 and the second wavelength division multiplexer WDM-2 cover the working wavelength of the narrow linewidth laser, and the working bandwidths of the reflection ends cover the working wavelength of the external distributed optical fiber vibration sensor through the first optical interface X1 and the fourth optical interface X4 respectively. Or the working bandwidths of the reflecting ends of the first wavelength division multiplexer WDM-1 and the second wavelength division multiplexer WDM-2 cover the working wavelength of the narrow linewidth laser, and the working bandwidth of the transmitting end cover the working wavelength of the external distributed optical fiber vibration sensor through the first optical interface X1 and the fourth optical interface X4 respectively, at the moment, the 4 port of the 3X 3 optical fiber coupler is connected with the reflecting port of the first wavelength division multiplexer WDM-1, the transmitting end of the first wavelength division multiplexer WDM-1 is connected with the first optical interface X1, the transmitting end of the second wavelength division multiplexer WDM-2 is connected with the fourth optical interface X4, and the reflecting end of the second wavelength division multiplexer WDM-2 is connected with the first Faraday magnetic rotating reflector FRM-1.

The two side ends of the 3X 3 optical fiber coupler are respectively provided with 1, 2 and 3 ports and 4, 5 and 6 ports, wherein the 1, 2 and 3 ports can be interchanged and are all positioned on the same side of the 3X 3 optical fiber coupler, and the 4, 5 and 6 ports can be interchanged and are all positioned on the other side of the 3X 3 optical fiber coupler.

The optical fiber fence invasion signal simulation device provides 4 optical interfaces X1, X2, X3 and X4, wherein the optical interfaces X2 and X3 are used for accessing a sensing optical cable to copy an optical fiber fence invasion signal or accessing an optical fiber jumper to directly pass through an optical fiber sensing signal, and the optical interfaces X1 and X4 are used for accessing the optical fiber fence invasion signal simulation device into an optical link to be tested of the optical fiber fence to perform optical fiber fence invasion signal simulation output so as to perform mode identification training.

The equipment has two working modes, namely an intrusion signal copying mode and an intrusion signal simulation output mode, wherein the working process of the intrusion signal copying working mode is as follows:

the first step: respectively connecting two ends of a sensing optical cable to be detected into a second optical interface X2 and a third optical interface X3, and setting the equipment into an intrusion signal copying working mode;

and a second step of: artificially reproducing the intrusion behavior of the sensing optical cable, adopting climbing an optical fiber fence/enclosing wall, treading an optical cable intrusion protection area, performing mechanical construction near the buried optical cable to be detected and the like, and recording and storing amplitude, waveform and duration time information of a vibration signal of the intrusion behavior of the sensing optical cable after phase demodulation in real time by a demodulation board;

and a third step of: removing a sensing optical cable to be detected, connecting a second optical interface X2 and a third optical interface X3 by adopting an optical fiber jumper wire, driving a piezoelectric ceramic PZT wound around an optical fiber by a demodulation plate, realizing the output of mechanical waves with the same amplitude, waveform and duration of an intrusion behavior vibration signal through multiple calibration, and storing the waveform output setting, numbering and additional description;

the working process of the intrusion signal simulation output mode is as follows:

the first step: connecting the second optical interface X2 and the third optical interface X3 by adopting an optical fiber jumper, and connecting the first optical interface X1 and the fourth optical interface X4 in series to any point in the middle of the distributed optical fiber vibration sensor mode identification training optical cable;

and a second step of: calling the setting corresponding to the required intrusion behavior, outputting an intrusion behavior simulation signal, and developing the mode identification training of the distributed optical fiber vibration sensor;

and a third step of: and replacing the setting corresponding to the invasion action required by calling or replacing the position of the optical fiber vibration sensing invasion signal copying and simulating equipment on the mode recognition training optical cable, and continuing to develop the mode recognition training of the distributed optical fiber vibration sensor.

The PZT is controlled by the demodulation circuit board and used for simulating and outputting an optical fiber fence intrusion signal detected by the Mach-Zehnder interferometer, wherein the simulation comprises the simulation of waveform, amplitude and duration information of the intrusion signal.

Compared with the prior art, the technical scheme adopts the narrow linewidth laser as a light source, the optical fiber interferometer is used for measuring the vibration waveform and amplitude of the intrusion signal, and the piezoelectric ceramic is used for simulating and outputting the vibration waveform and amplitude of the intrusion signal, so that the intrusion signal on the outfield sensing optical cable can be duplicated in a fidelity manner, the intrusion signal is connected to any position of the sensing optical cable to be tested and simulated and output for pattern recognition training, the problems that the outfield pattern recognition training is difficult to guarantee for a long time, the mode of using the fixed database for pattern recognition training is limited in information quantity and poor in pattern recognition training coverage are solved, and the distributed optical fiber vibration sensing pattern recognition training guarantee condition is improved.

The device can realize the fidelity copying of the intrusion signal on the external field sensing optical cable, and is connected with any position of the sensing optical cable to be tested to simulate and output the intrusion signal for pattern recognition training.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment.

Detailed Description

The present invention will now be further illustrated, but not limited, by the following figures and examples.

Examples:

referring to fig. 1, an optical fiber fence intrusion signal simulation device based on a michelson interferometer comprises a narrow linewidth laser, a michelson optical fiber interferometer based on a 3X 3 optical fiber coupler, a first wavelength division multiplexer WDM-1, a second wavelength division multiplexer WDM-2, a piezoceramic PZT wound with optical fibers and a demodulation circuit board provided with a first photo detector PD1 and a second photo detector PD2 which are sequentially connected, wherein the narrow linewidth laser outputs high-coherence laser to be connected with a 1 port of the 3X 3 optical fiber coupler and split into three beams, the three beams are respectively output by 4, 5 and 6 ports of the 3X 3 optical fiber coupler, the 4 port of the 3X 3 optical fiber coupler is connected with a transmission port of the first wavelength division multiplexer WDM-1, a reflecting end of the first wavelength division multiplexer WDM-1 is connected with the first optical interface X1, a public end of the first wavelength division multiplexer WDM-1 is connected with the second optical interface X2, the second optical interface X2 is connected with a third optical interface X3 through an external sensing optical cable or an optical fiber jumper, the third optical interface X3 is connected with an optical input end of a piezoelectric ceramic PZT wound with an optical fiber, an optical output end of the piezoelectric ceramic PZT wound with the optical fiber is connected with a public end of a second wavelength division multiplexer WDM-2, a reflecting end of the second wavelength division multiplexer WDM-2 is connected with a fourth optical interface X4, a transmitting end of the second wavelength division multiplexer WDM-2 is connected with a first Faraday magnetic rotating reflector FRM-1 to reflect a narrow linewidth laser primary path back to a 3X 3 optical fiber coupler as a detection optical signal, a narrow linewidth laser entering the second Faraday magnetic rotating reflector FRM-2 connected with a port of the 3X 3 optical fiber coupler 6 is output by a port of the 3X 3 optical fiber coupler and reflected back to the 3X 3 optical fiber coupler is used as a reference optical signal, in addition, the 2 port and the 3 port of the 3×3 fiber coupler are respectively connected with the first photoelectric detector PD1 and the second photoelectric detector PD2 on the demodulation plate, the output end of the demodulation plate is connected with the piezoelectric ceramic PZT of the winding fiber, and a voltage control signal is output through the demodulation plate and enters the piezoelectric ceramic PZT of the winding fiber.

The working wavelength of the narrow linewidth laser of the embodiment is at least 0.8nm different from the working wavelength of the optical fiber vibration sensor built-in laser externally connected with the first optical interface X1 or the fourth optical interface X4, and the frequency interval is above 100 GHz.

The first wavelength division multiplexer WDM-1 and the second wavelength division multiplexer WDM-2 are respectively provided with three optical fiber ports of a public end, a transmission end and a reflection end, wherein the working bandwidths of the transmission ends of the first wavelength division multiplexer WDM-1 and the second wavelength division multiplexer WDM-2 cover the working wavelength of the narrow linewidth laser, and the working bandwidths of the reflection ends cover the working wavelength of the external distributed optical fiber vibration sensor through the first optical interface X1 and the fourth optical interface X4 respectively.

The two side ends of the 3×3 fiber coupler of this example are respectively provided with 1, 2, 3 ports and 4, 5, 6 ports, wherein the 1, 2, 3 ports are interchangeable and all located on the same side of the 3×3 fiber coupler, and the 4, 5, 6 ports are also interchangeable and all located on the other side of the 3×3 fiber coupler.

The equipment has two working modes, namely an intrusion signal copying mode and an intrusion signal simulation output mode, wherein the working process of the intrusion signal copying working mode is as follows:

the first step: respectively connecting two ends of a sensing optical cable to be detected into a second optical interface X2 and a third optical interface X3, and setting the equipment into an intrusion signal copying working mode;

and a second step of: artificially reproducing the intrusion behavior of the sensing optical cable, adopting climbing an optical fiber fence/enclosing wall, treading an optical cable intrusion protection area, performing mechanical construction near the buried optical cable to be detected and the like, and recording and storing amplitude, waveform and duration time information of a vibration signal of the intrusion behavior of the sensing optical cable after phase demodulation in real time by a demodulation board;

and a third step of: removing a sensing optical cable to be detected, connecting a second optical interface X2 and a third optical interface X3 by adopting an optical fiber jumper wire, driving a piezoelectric ceramic PZT wound around an optical fiber by a demodulation plate, realizing the output of mechanical waves with the same amplitude, waveform and duration of an intrusion behavior vibration signal through multiple calibration, and storing the waveform output setting, numbering and additional description;

the working process of the intrusion signal simulation output mode is as follows:

the first step: connecting the second optical interface X2 and the third optical interface X3 by adopting an optical fiber jumper, and connecting the first optical interface X1 and the fourth optical interface X4 in series to any point in the middle of the distributed optical fiber vibration sensor mode identification training optical cable;

and a second step of: calling the setting corresponding to the required intrusion behavior, outputting an intrusion behavior simulation signal, and developing the mode identification training of the distributed optical fiber vibration sensor;

and a third step of: and replacing the setting corresponding to the invasion action required by calling or replacing the position of the optical fiber vibration sensing invasion signal copying and simulating equipment on the mode recognition training optical cable, and continuing to develop the mode recognition training of the distributed optical fiber vibration sensor.

In this example, PZT is controlled by a demodulation circuit board and is used for analog output of an intrusion signal of an optical fiber fence detected by a michelson interferometer, including analog of waveform, amplitude and duration information of the intrusion signal.

Claims (6)

1. The optical fiber fence intrusion signal simulation device based on the Michelson interferometer is characterized by comprising a narrow linewidth laser, a Michelson optical fiber interferometer based on a 3X 3 optical fiber coupler, a first wavelength division multiplexer WDM-1, a second wavelength division multiplexer WDM-2, a piezoelectric ceramic PZT wound with optical fibers and a demodulation circuit board provided with a first photoelectric detector PD1 and a second photoelectric detector PD2 which are sequentially connected, wherein a 4 port of the 3X 3 optical fiber coupler is connected with a transmission port of the first wavelength division multiplexer WDM-1, a reflecting end of the first wavelength division multiplexer WDM-1 is connected with a first optical interface X1, a public end of the first wavelength division multiplexer WDM-1 is connected with a second optical interface X2, the second optical interface X2 is connected with a third optical interface X3 through an external sensing optical cable or an optical fiber jumper, the third optical interface X3 is connected with the optical input end of the piezoelectric ceramic PZT of the winding optical fiber, the optical output end of the piezoelectric ceramic PZT of the winding optical fiber is connected with the public end of the second wavelength division multiplexer WDM-2, the reflecting end of the second wavelength division multiplexer WDM-2 is connected with the fourth optical interface X4, the transmitting end of the second wavelength division multiplexer WDM-2 is connected with the first Faraday magnetic rotating reflector FRM-1 to reflect the narrow linewidth laser primary path back to the 3X 3 optical fiber coupler as a detection optical signal, the narrow linewidth laser which is output by the port 6 of the 3X 3 optical fiber coupler, enters the second Faraday magnetic rotating reflector FRM-2 connected with the port 6 of the 3X 3 optical fiber coupler and is reflected back to the 3X 3 optical fiber coupler is used as a reference optical signal, the port 2 and the port 3 port of the 3X 3 optical fiber coupler are respectively connected with the first photoelectric detector PD1 and the second photoelectric detector PD2 on the demodulation board, the output end of the demodulation plate is connected with the piezoelectric ceramic PZT of the winding optical fiber, and a voltage control signal is output by the demodulation plate and enters the piezoelectric ceramic PZT of the winding optical fiber.

2. The michelson interferometer-based fiber fence intrusion signal simulation device according to claim 1, wherein the working wavelength of the narrow linewidth laser is at least 0.8nm different from the working wavelength of the optical fiber vibration sensor built-in laser externally connected with the first optical interface X1 or the fourth optical interface X4, and the frequency interval is above 100 GHz.

3. The michelson interferometer-based fiber fence intrusion signal simulation device according to claim 1, wherein the first wavelength division multiplexer WDM-1 and the second wavelength division multiplexer WDM-2 are provided with three optical fiber ports of a common port, a transmission port and a reflection port, wherein the working bandwidths of the transmission ports of the first wavelength division multiplexer WDM-1 and the second wavelength division multiplexer WDM-2 cover the working wavelength of the narrow linewidth laser, and the working bandwidths of the reflection ports cover the working wavelength of the external distributed fiber vibration sensor through the first optical interface X1 and the fourth optical interface X4, respectively; or the working bandwidths of the reflecting ends of the first wavelength division multiplexer WDM-1 and the second wavelength division multiplexer WDM-2 cover the working wavelength of the narrow linewidth laser, and the working bandwidth of the transmitting end cover the working wavelength of the external distributed optical fiber vibration sensor through the first optical interface X1 and the fourth optical interface X4 respectively, at the moment, the 4 port of the 3X 3 optical fiber coupler is connected with the reflecting port of the first wavelength division multiplexer WDM-1, the transmitting end of the first wavelength division multiplexer WDM-1 is connected with the first optical interface X1, the transmitting end of the second wavelength division multiplexer WDM-2 is connected with the fourth optical interface X4, and the reflecting end of the second wavelength division multiplexer WDM-2 is connected with the first Faraday magnetic rotating reflector FRM-1.

4. The michelson interferometer-based fiber rail intrusion signal simulation device according to claim 1, wherein the two side ends of the 3 x3 fiber coupler are provided with 1, 2, 3 ports and 4, 5, 6 ports, respectively, wherein the 1, 2, 3 ports are interchangeable and all located on the same side of the 3 x3 fiber coupler, and the 4, 5, 6 ports are also interchangeable and all located on the other side of the 3 x3 fiber coupler.

5. The method for using the michelson interferometer-based optical fiber fence intrusion signal simulation device, comprising the michelson interferometer-based optical fiber fence intrusion signal simulation device according to any one of claims 1 to 4, wherein the device has two working modes, namely an intrusion signal copying mode and an intrusion signal simulation output mode, respectively, and the working process of the intrusion signal copying working mode is as follows:

the first step: respectively connecting two ends of a sensing optical cable to be detected into a second optical interface X2 and a third optical interface X3, and setting the equipment into an intrusion signal copying working mode;

and a second step of: artificially reproducing the invasion behavior of the sensing optical cable, adopting climbing an optical fiber fence/enclosing wall, treading an optical cable invasion protection area, performing mechanical construction near the buried optical cable to be detected, and recording and storing amplitude, waveform and duration time information of a vibration signal of the invasion behavior of the sensing optical cable after phase demodulation in real time by a demodulation board;

and a third step of: removing a sensing optical cable to be detected, connecting a second optical interface X2 and a third optical interface X3 by adopting an optical fiber jumper wire, driving a piezoelectric ceramic PZT wound around an optical fiber by a demodulation plate, realizing the output of mechanical waves with the same amplitude, waveform and duration of an intrusion behavior vibration signal through multiple calibration, and storing the waveform output setting, numbering and additional description;

the working process of the intrusion signal simulation output mode is as follows:

the first step: connecting the second optical interface X2 and the third optical interface X3 by adopting an optical fiber jumper, and connecting the first optical interface X1 and the fourth optical interface X4 in series to any point in the middle of the distributed optical fiber vibration sensor mode identification training optical cable;

and a second step of: calling the setting corresponding to the required intrusion behavior, outputting an intrusion behavior simulation signal, and developing the mode identification training of the distributed optical fiber vibration sensor;

and a third step of: and replacing the setting corresponding to the invasion action required by calling or replacing the position of the optical fiber vibration sensing invasion signal copying and simulating equipment on the mode recognition training optical cable, and continuing to develop the mode recognition training of the distributed optical fiber vibration sensor.

6. The method for using a michelson interferometer-based fiber rail intrusion signal simulation device according to claim 5, wherein the PZT is controlled by a demodulation circuit board and is used for simulating and outputting the fiber rail intrusion signal detected by the mach-zehnder interferometer, including simulation of waveform, amplitude and duration information of the intrusion signal.