CN210400422U - Time division/wavelength division multiplexing fiber grating distributed sensing system - Google Patents
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Abstract
The embodiment of the utility model discloses a time division/wavelength division multiplexing's fiber grating distributed sensing system, this time division/wavelength division multiplexing's fiber grating distributed sensing system includes light source subsystem, directional coupler, the grating network that awaits measuring, demodulation subsystem and central control subsystem; the directional coupler comprises a first port, a second port and a third port; the light source subsystem is connected with a first port of the directional coupler, a second port of the directional coupler is connected with a grating network to be tested, and the demodulation subsystem is connected with a third port of the directional coupler; the central control subsystem is connected with the light source subsystem and the demodulation subsystem; the light source subsystem comprises at least one distributed feedback laser tube; the grating network to be detected is a time division/wavelength division multiplexing sensing network and comprises at least one optical fiber, at least two gratings are integrated on the optical fiber, and the reflectivity of the gratings is less than-20 dB so as to meet the increasing detection requirement of the existing fiber grating distributed sensing system.
Description
Technical Field
The embodiment of the utility model provides a relate to the optical fiber sensing technology, especially relate to a time/wavelength division multiplexing's fiber grating distributed sensing system.
Background
In recent years, the demand for large capacity in a plurality of engineering fields is increased, and a sensing network system for realizing distributed, multi-parameter and multifunctional sensing becomes a research hotspot in the current sensing field. The Fiber Bragg Grating (FBG) sensing technology is a typical quasi-distributed fiber sensing technology, and has a wide application value in the fields of aerospace, railways, petrochemical industry, electric power, medical treatment, ships, civil engineering and the like. With the rapid development of high-speed railways, railway construction and operation units all put forward the urgent need of large-range, low-cost and high-benefit environment monitoring systems with engineering application values. The fiber grating sensing technology has the characteristics of good linear response, high precision, high sensitivity, wide measurement range, miniaturization, easiness in large-scale networking, capability of writing tens of thousands of fiber gratings on one optical fiber and the like, and is very suitable for various high-speed railway engineering application scenes such as large-scale boundary protection, rail state monitoring, concrete hydration heat temperature monitoring, railway roadbed settlement, contact network temperature monitoring and the like and other large-scale engineering fields such as aerospace, petrochemical industry, electric power, medical treatment, ships, civil engineering and the like.
Currently, the common multiplexing modes of fiber gratings can be divided into Wavelength Division Multiplexing (WDM), Time Division Multiplexing (TDM), and Frequency Division Multiplexing (FDM). Wavelength division multiplexing is the most common multiplexing technique and has been commercialized, however, the single-path multiplexing capacity is generally not more than several tens of multiplexing capacity due to the limitation of the bandwidth of the light source. Time division multiplexing has the advantage of high multiplexing, long distances, but is limited by the light source power, grating reflectivity, and cross-talk between gratings. The frequency division multiplexing technology has the advantages of high demodulation difficulty, high anti-interference performance and poor stability. Therefore, the existing fiber grating distributed sensing system cannot meet the increasing detection requirement.
SUMMERY OF THE UTILITY MODEL
The utility model provides a time/wavelength division multiplexing's fiber grating distributed sensing system to satisfy present fiber grating distributed sensing system's ever-increasing detection demand.
The embodiment of the utility model provides a time division/wavelength division multiplexing's fiber grating distributed sensing system, including light source subsystem, directional coupler, the grating network that awaits measuring, demodulation subsystem and central control subsystem;
the directional coupler comprises a first port, a second port and a third port;
the light source subsystem is connected with a first port of the directional coupler, a second port of the directional coupler is connected with the grating network to be tested, and the demodulation subsystem is connected with a third port of the directional coupler; the central control subsystem is connected with the light source subsystem and the demodulation subsystem;
the light source subsystem comprises at least one distributed feedback laser tube;
the grating network to be tested is a time division/wavelength division multiplexing sensor network and comprises at least one optical fiber, at least two gratings are integrated on the optical fiber, and the reflectivity of the gratings is less than-20 dB;
under the working state, the central control subsystem controls the light source subsystem to output detection signal light, the detection signal light enters the to-be-detected grating network through the directional coupler, the grating is reflected to form reflected light in the to-be-detected grating network, the reflected light enters the demodulation subsystem through the directional coupler, the demodulation subsystem collects and processes the reflected light to form an electric signal, and the central control subsystem processes the electric signal to form a monitoring result and outputs the monitoring result.
The embodiment of the utility model provides a through setting up time division/wavelength division multiplexing's fiber grating distributed sensing system, including light source subsystem, directional coupler, the grating network that awaits measuring, demodulation subsystem and central control subsystem; the directional coupler comprises a first port, a second port and a third port; the light source subsystem is connected with a first port of the directional coupler, a second port of the directional coupler is connected with the grating network to be tested, and the demodulation subsystem is connected with a third port of the directional coupler; the central control subsystem is connected with the light source subsystem and the demodulation subsystem; the light source subsystem comprises at least one distributed feedback laser tube; the grating network to be detected is a time division/wavelength division multiplexing sensing network and comprises at least one optical fiber, at least two gratings are integrated on the optical fiber, the reflectivity of the gratings is less than-20 dB, the problem that the existing fiber grating distributed sensing system cannot meet the increasing detection requirement is solved, and the effect of meeting the increasing detection requirement of the existing fiber grating distributed sensing system is achieved.
Drawings
Fig. 1 is a block diagram of a time division/wavelength division multiplexing fiber grating distributed sensing system according to an embodiment of the present invention;
fig. 2-5 are frequency spectrum distortion reflection spectrums caused by shadow effect in the time division multiplexing mode of the time division/wavelength division multiplexing fiber grating distributed sensing system according to the embodiment of the present invention;
fig. 6 is a schematic structural diagram of another fiber grating distributed sensing system according to an embodiment of the present invention;
fig. 7 is a test curve of a time division/wavelength division multiplexing fiber grating distributed sensing system at a certain wavelength according to an embodiment of the present invention;
fig. 8 is a monitoring result diagram of the time division/wavelength division multiplexing fiber grating distributed sensing system monitoring a certain grating provided by the embodiment of the present invention.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.
Fig. 1 is a block diagram of a time division/wavelength division multiplexing fiber grating distributed sensing system according to an embodiment of the present invention. Referring to fig. 1, the time division/wavelength division multiplexing fiber grating distributed sensing system includes a light source subsystem 1, a directional coupler 2, a grating network to be measured 3, a demodulation subsystem 4 and a central control subsystem 5. The directional coupler 2 includes a first port, a second port and a third port; the light source subsystem 1 is connected with a first port of the directional coupler 2, a second port of the directional coupler 2 is connected with the grating network 3 to be tested, and the demodulation subsystem 4 is connected with a third port of the directional coupler 2; the central control subsystem 5 is connected with the light source subsystem 1 and the demodulation subsystem 4; the light source subsystem 1 includes at least one distributed feedback laser tube (not shown in fig. 1); the grating network 3 to be measured is a time division/wavelength division multiplexing sensor network, and comprises at least one optical fiber (not shown in fig. 1), at least two gratings are integrated on the optical fiber, and the reflectivity of the gratings is less than-20 dB.
Under the working state, the central control subsystem 5 controls the light source subsystem 1 to output detection signal light, the detection signal light enters the to-be-detected grating network 3 through the directional coupler 2 and is reflected at a grating in the to-be-detected grating network 3 to form reflected light, the reflected light enters the demodulation subsystem 4 through the directional coupler 2, the demodulation subsystem 4 processes and collects the reflected light to form an electric signal, and the central control subsystem 5 processes the electric signal to form a monitoring result and outputs the monitoring result.
The working modes of the fiber grating distributed sensing system comprise a time division multiplexing mode, a wavelength division multiplexing mode and a time division-wavelength division multiplexing mode. The time division/wavelength division multiplexing sensor network refers to a sensor network that can operate in at least one of a time division multiplexing mode, a wavelength division multiplexing mode, and a time division-wavelength division multiplexing mode.
The distributed feedback laser tube has a temperature tuning function, and can generate detection signal light with various wavelengths through the temperature tuning function, so that the distributed feedback laser tube works in a time division multiplexing mode.
In the technical scheme, the grating is used as a sensing unit, the ultra-weak reflection fiber Bragg grating (UW-FBG) with the same sensing characteristic can be adopted, the reflectivity R is smaller than-20 dB (< 1%), and the wavelength of each sensor changes within a certain range along with the monitoring variable.
The essence of the technical scheme is that the ultra-weak fiber grating is used as a sensor, a sensing network structure in a time division/wavelength division multiplexing mode is used, and a wavelength tunable optical time domain reflectometer is used as a demodulation device, so that a large-capacity distributed sensing system is realized. The system has the advantages of simple structure, low cost, easiness in adjustment, flexibility in control, good repeatability, high efficiency, easiness in industrial production and the like, and is very suitable for various high-speed railway engineering application scenes such as large-scale boundary protection, rail state monitoring, concrete hydration heat temperature monitoring, railway roadbed settlement, contact network temperature monitoring and the like and other large-scale engineering fields such as aerospace, petrochemical industry, electric power, medical treatment, ships, civil engineering and the like.
On the basis of the above technical solution, optionally, the light source subsystem 1 includes two or more distributed feedback laser tubes; the central wavelengths of the detection signal lights which can be output by the distributed feedback laser tubes are different. This arrangement can further increase the number of multiplexes in the wavelength division multiplexing mode.
In the time division multiplexing mode, it is required that at least two gratings in the same optical fiber have the same center wavelength, and the interval d between any two adjacent gratings having the same center wavelength is greater than the minimum interval d of the gratingsmin。
And the minimum spacing d of the gratingsminThe method is determined by the event blind area, the pulse width of the detection light signal and the sampling resolution. Minimum spacing d of gratings in time division multiplex modeminThe calculation comprises the following steps:
i. calculating the width of the stretched pulse:
the width of the optical pulse of the detection signal is w, and the width of the bandwidth f of the receiverBWThe returned pulse signal is stretched:
trp=w+tr+tf
wherein, trFor rise time response, tfFor falling time response, tr=tf=0.35/fBWTo avoid the effect of dead zone, the minimum distance d between two reflection events (i.e. the distance between any two adjacent gratings with the same center wavelength in the same fiber) is at least greater than C/ntrpWhere C is the light propagation velocity and n is the refractive index of the optical fiber.
Calculating the minimum probe pulse width:
but d is also affected by the sampling resolution. In order to ensure the accuracy of the reflected light pulse signal test, at least 4 sampling points in one reflected light pulse are sampled. If the sampling period is tsThen the detection signal light pulse time width satisfies:
w>4ts-tr-tf
calculating the minimum interval:
in addition, there are at least two sampling points between events for resolving events, so the minimum distance d between two reflected events must be greater than the minimum separation dmin:
Since the multiplexing degree of the time division multiplexing is mainly affected by reflection loss, fiber attenuation, shadowing effect, and inter-stage multiple reflection crosstalk, the following exemplary steps of calculating the multiplexing degree in the time division multiplexing are given as follows:
i. calculating transmission loss:
in the time division multiplexing mode, the attenuation of the probe optical signal is caused by reflection loss and optical fiber attenuation. The influence degree of the transmission loss on the detection signal light is calculated by the light source output power, the grating reflectivity, the link loss and the grating interval.
Calculating the shadow effect:
in the time division multiplexing mode, the shadow effect causes the distortion of the signal, the grating at the far end of the sensor network will be subjected to the spectrum distortion caused by the accumulated insertion loss related to the wavelength, and the spectrum P of the grating sensor at the far end should be verified by the grating spectrum, the grating reflectivity, the transmission distance and the detection signal spectrumj(lambda) limiting the number of gratings to a range where the spectrum does not change significantly, ensuring that the center wavelength of the grating at its farthest end can be identified without significant flattening and sagging of the spectrum.
Exemplarily, fig. 2-5 show a spectrum distortion reflection spectrum caused by a shadow effect in a time division multiplexing manner of a time division/wavelength division multiplexing fiber grating distributed sensing system according to an embodiment of the present invention, wherein the reflectivity of the fiber grating used in fig. 2 is-10 dB, the reflectivity of the fiber grating used in fig. 3 is-20 dB, the reflectivity of the fiber grating used in fig. 4 is-30 dB, and the reflectivity of the fiber grating used in fig. 5 is-40 dB. In fig. 2 to 5, j represents the number of multiplexed gratings. The curves in fig. 2-5 may reflect the influence of the shadowing effect on the spectrum at different reflectivities.
Referring to fig. 2-5, since the central reflectivity is higher, the optical power of the central wavelength is more lost than that of the edge wavelength, so that the central spectrum is gradually flat or even sags, and the identification error of the central wavelength is caused in the sensing field. As can be seen from fig. 2, when R is-10 dB, the reflection spectrum of the 2 nd grating (j is 2) is clearly flat, and the center wavelength cannot be correctly identified by the 10 th grating (j is 10). When R is reduced to-20 dB, as in fig. 3, this situation improves and multiplexing to 50 gratings (j 50) is significantly gentler. As shown in fig. 4, when R is-30 dB, a clear flattening is seen after multiplexing 500 gratings (j is 500). When R is-40 dB, fig. 5 shows that the spectrum does not change much after the number of gratings reaches 1000 (j is 500).
Therefore, in the time division multiplexing mode, the influence caused by the shadow effect is avoided as much as possible, the gratings with lower reflectivity can be adopted as much as possible, the number of the gratings is limited in the range of no obvious change of the spectrum, the central wavelength of the grating at the farthest end can be ensured to be identified, the spectrum is not obvious smooth and sunken, and at the moment, the maximum value j of j ismaxNumber N of gratings equal to zero boundary point of reflection spectrum distortionshadow. For example, according to FIG. 5, j may be takenmax=Nshadow=500。
Calculating inter-stage multiple reflection crosstalk
In the time division multiplexing mode, multiple reflections between gratings may cause inevitable crosstalk error in the serial grating array, and the input power of the light source, the reflectivity of the gratings, and the gratings should be selectedThe number and the grating interval are used for solving the grating crosstalk C borne by each grating sensorj(λ) to ensure that it is within an acceptable range.
Defining a signal-to-noise ratio of the detection signal
In order to further determine the multiplexing degree of the time division multiplexing mode, the signal-to-noise ratio of the detection signal is defined as follows:
SNR=Pj(λ)/Cj(λ)
when SNR>At 10dB, the effect of signal crosstalk is negligible, so the number of gratings N at SNR of 10dB can be definedopTo optimize the number of multiplexes. If a situation is encountered that requires more multiplexing capability, the number of gratings can be increased to the node where the SNR drops to 0 dB: at this point the sensor signal can be identified despite the fact that the signal interferes with multiple reflections. The number of gratings N at SNR of 0dB can be definedidIs the identifiable multiplex number, i.e. the minimum multiplex number. Therefore, the number N of the gratings influenced by the signal-to-noise ratio of the detected signal light can be set according to the actual monitoring requirementzyIs NopOr Nid。
The number of gratings having the same center wavelength in the same optical fiber (i.e., the multiplexing degree N of the TDM system)TDM) Number of gratings N as zero-boundary point of reflected spectrum distortionshadowThe number N of gratings influenced by the signal-to-noise ratio of the detected signal lightzyAnd the maximum number of gratings N affected by the return powerrpThe minimum of the three.
Further, in the time division multiplexing mode, the used UW-FBGs have the same center wavelength and the wavelength variation range is Δ λ. The tuning range of the distributed feedback laser tube is delta lambda, detection signal light generated by the light source subsystem 1 enters a sensor network, the demodulation subsystem monitors the time delay of a reflected pulse signal from a sensor, the sensor in a link is identified through UW-FBG reflected pulses with different time delays, and an interested physical parameter is measured through detecting the deviation of the central wavelength of the FBG sensor. Thus, optionally, the monitoring result includes a grating position L corresponding to the reflected light collected by the demodulation subsystem 4 at time t, L being based onThus obtaining the product.
In the wavelength division multiplexing mode, the central wavelengths of at least two gratings in the optical fiber are different. If the wavelength of the grating varies by Δ λ. And the distributed feedback laser tube is tuned in the range of the bandwidth B of the light source, and if the monitoring result comprises a grating position L corresponding to the reflected light collected by the demodulation subsystem 4, the L is obtained based on wavelength addressing. Specifically, the attribute information (such as the number or model of the grating) of the grating forming the reflected light can be determined by the wavelength of the reflected light, and the grating position L can be obtained based on the attribute information of the grating.
The multiplexing degree of the wavelength division multiplexing mode is mainly influenced by the bandwidth of a light source and the wavelength variation range of the grating, and the multiplexing number N of the gratingWDMComprises the following steps:
NWDM=B/Δλ
in the time division-wavelength division multiplexing mode, there are various methods for setting gratings in the same optical fiber. Two grating setting methods are given below by way of example, but not to limit the present application.
The method comprises the steps that a same optical fiber comprises at least two repeating units, and the repeating units are sequentially arranged; the repeating unit comprises at least two gratings, and the central wavelengths of the gratings in the same repeating unit are different; the interval d between two gratings with the same center wavelength in any two adjacent repeating units1The requirements are met,
where C is the light propagation velocity, n is the refractive index of the optical fiber, w is the detection pulse width, trFor rise time response, tfFor falling time response, tsIs the sampling period.
In the second method, the same optical fiber comprises at least two groups of gratings which are arranged in sequence; the central wavelengths of the same group of gratings are the same; the central wavelengths of different groups of gratings are different; in the same group of gratings, the interval d between two adjacent gratings2The requirements are met,
where C is the light propagation velocity, n is the refractive index of the optical fiber, w is the detection pulse width, trFor rise time response, tfFor falling time response, tsIs the sampling period.
Multiplexing degree N-N in time division-wavelength division multiplexing modeTDMNWDM. Wherein N isTDMNumber of multiplexes in time division multiplex, NWDMThe multiplexing number is the wavelength division multiplexing mode.
If the monitoring result includes the time tijThe grating position L corresponding to the reflected light collected by the demodulation subsystem 4ijOptionally, LijBased on the wavelength corresponding to the maximum value of powerThus obtaining the product.
Exemplarily, in the time division/wavelength division multiplexing mode, the bandwidth of the system light source is B, the power is P, and the used UW-FBGs are divided into m groups, i-th group (0)<i is less than or equal to M) is formed by n central wavelengths of lambdaiThe UW-FBGs are connected in series on an optical fiber at an interval d, and the fluctuation range is lambdai±Δλ/2。ti0At the moment, the light source is tuned to produce a wavelength λiIs incident on the fiber and then the receiving end is at tijThe light reflected by the ith group of jth fiber grating is received at any moment, the wavelength is scanned, the corresponding wavelength when the ijth ultra-weak fiber grating returns to the maximum power value is the central wavelength corresponding to the grating, and meanwhile, the formula is used for calculating the maximum power value of the ith group of jth fiber gratingThe position of the grating can be inferred.
Fig. 6 is a schematic structural diagram of another fiber grating distributed sensing system according to an embodiment of the present invention. Referring to fig. 6, the light source subsystem 1 further includes a laser temperature tuner 14, an optical waveguide 12, and a power compensation amplifier 13; the laser temperature tuner 14 includes a first temperature controllable region; the distributed feedback laser tube 11, the optical waveguide 12 and the power compensation amplifier 13 are all located in the first temperature controllable region and are sequentially arranged along the propagation direction of the detection signal light. The essence of the arrangement is that key functional components such as n DFB laser chips with different central wavelengths, a temperature controller, an optical waveguide and a semiconductor amplifier are integrated in the light source subsystem 1, and the light source subsystem has the advantages of single-frequency output, single-mode output, wide tunable range, small size, high reliability, permission of using a simple feedback circuit to control wavelength and optical power output, capability of directly modulating and outputting detection signal optical pulses, easiness in coupling with optical fibers and the like.
Further, the light source subsystem 1 may also be configured to include a wavelength locker to further improve the stability of the detection signal light output.
With continued reference to FIG. 6, optionally, the central control subsystem 5 includes a signal generator 51, a laser tube bias assembly 52, a laser tube selection assembly 53, a wavelength tuning module 54, a laser temperature tuner controller 55, a power control module 56, and a power compensation controller 57; the signal generator 51 is connected with each distributed feedback laser tube 11 through a laser tube offset component 52; the wavelength tuning module 54 is connected with a laser temperature tuner controller 55 and a laser tube selection component 53, and the laser temperature tuner controller 55 is also connected with the laser temperature tuner 14; the power control module 56 is connected to the power compensation amplifier 13 through a power compensation controller 57. The arrangement can effectively ensure that the detection signal light with proper central wavelength and power is output from the light source subsystem 1, and further improve the effectiveness and accuracy of detection.
The central wavelength of the optical signal that each distributed feedback laser tube 11 can output is preset to be different. If the central control subsystem 5 determines that the detection signal light with the output wavelength λ is output, because the ith distributed feedback laser tube 11 outputs the detection signal light with the wavelength λ i closest to λ at room temperature, the ith distributed feedback laser tube 11 is gated to work through the laser tube selection component 53, meanwhile, the working voltage of the laser temperature tuner 14 is determined according to λ - λ i, and the temperature of the first temperature controllable region in the laser temperature tuner 14 is tuned through the laser temperature tuner controller 55, so that the detection signal light with the output wavelength λ of the ith distributed feedback laser tube 11 is tuned.
Illustratively, in practice, the DFB laser array may provide a wavelength tuning range above 25nm by selecting an appropriate DFB tube and tuning the temperature of the first temperature controllable region:
λDFB=λDFBk+ΔλDFBk×TDFB(12)
wherein λ isDFBkIs the wavelength base of the kth DFB, Δ λDFBkThe variation parameter of the k-th DFB wavelength along with the physical quantity. The distributed feedback laser array chip is a light source and a key demodulation component of the whole system: temperature T of the first temperature controllable region of the laser temperature tuner 14DFBWhen tuned, the wavelength of the output probe signal light may match the center wavelength of the grating. Thus, by simple optical power detection, variable information on the grating can be obtained.
Optionally, the laser temperature tuner controller 55 may further be configured to have a capability of constant temperature regulation, and the temperature of the first temperature controllable region in the laser temperature tuner 14 may be subjected to constant temperature regulation according to the resistance value data fed back by the temperature measuring resistor of the distributed feedback laser tube 11, so as to achieve the purpose of stably outputting the detection signal light with the wavelength λ.
After the ith distributed feedback laser tube 11 is gated, the signal generator 51 sends a driving signal to the laser tube bias component 52, so as to control the bias current of the ith distributed feedback laser tube 11, and generate the detection signal light with the required duration. Meanwhile, the power control module 56 sends a power tuning signal to the power compensation controller 57, thereby setting the bias current of the power compensation amplifier 13 and controlling the output power of the detection signal light.
With continued reference to fig. 6, optionally, the light source subsystem 1 further includes a power monitoring photodetector 15, a wavelength monitoring photodetector 16, a first beam splitter 17, a second beam splitter 18, an etalon 101, and an etalon temperature tuner 102; the central control subsystem 5 also includes an etalon temperature tuner controller 58; the first spectroscope 17 and the second spectroscope 18 are sequentially positioned on an optical path of the detection signal light between the power compensation amplifier 13 and the grating network 3 to be detected; the optical detector 15 for power monitoring is located on the optical path of the first sub-beam formed by the reflection of the detection signal light by the first beam splitter 17, and the optical detector 15 for power monitoring is connected to the power compensation controller 57; the wavelength monitoring photodetector 16 is located on an optical path of the second sub beam formed by the reflection of the detection signal light by the second beam splitter 18, and the wavelength monitoring photodetector 16 is connected to the wavelength tuning module 54; the etalon temperature tuner 102 includes a second temperature controllable region; the etalon 101 is located in the second temperature controllable region and is located on the optical path of the second sub-beam between the wavelength monitoring photodetector 16 and the second beam splitter 18; the etalon temperature tuner 102 is connected to the wavelength tuning module 54 via the etalon temperature tuner controller 58.
After the detection signal light is generated, a small amount of signal light is introduced into the optical detector for power monitoring 15 through the first spectroscope 17; the optical detector 15 for power monitoring performs photoelectric conversion and then feeds back the optical power information of the detection signal to the power compensation controller 57; the power compensation controller 57 performs automatic power control based on the feedback information. The detection signal light is introduced into the optical detector 16 for wavelength monitoring after a small amount of signal light is reflected into the etalon 101 by the second spectroscope 18; the wavelength tuning module 54 tunes the temperature of the second temperature controllable region of the temperature tuner 102 for the etalon through the temperature tuner controller 58 for the etalon, thereby tuning the wavelength calibrated by the etalon 101; the wavelength monitoring photodetector 16 feeds back the detection signal optical wavelength information to the wavelength tuning module 54 after photoelectric conversion; the wavelength tuning module 54 performs automatic wavelength control based on the feedback information. The detection signal light tuned by the automatic power and the wavelength is output to the grating network 3 to be detected through the front end connector. Thus, the purpose of stabilizing the detection signal light with constant output power and constant wavelength can be further realized.
With continued reference to fig. 6, optionally, the demodulation subsystem 4 includes a photodetection module 41, a signal conditioning module 42, and a data acquisition module 43; the central control subsystem 5 also comprises a data processing module 59; the photoelectric detection module 41 is connected with the third port of the directional coupler 2 and is used for converting the reflected light into an electric signal; the signal conditioning module 42 is connected with the photoelectric detection module 41 and is used for amplifying, shaping and denoising the electric signal; the data acquisition module 43 is connected with the signal conditioning module 42 and is used for acquiring the processed electric signals; the data processing module 59 is connected to the data acquisition module 43, and is configured to process the acquired electrical signals to form a monitoring result.
With continued reference to fig. 6, in fig. 6, the fiber grating distributed sensing system exemplarily uses a time division-wavelength division multiplexing method, the sensing device in the grating network 3 to be measured is the ultra-weak fiber grating 31, and the reflectivity is R: (m)<-20dB), each sensor having a wavelength variation of Δ λ, the ultra-weak fiber grating 31 being divided in wavelength into m groups, each group having n identical central wavelengths λi(i-1, 2, …, m). The ultra-weak fiber gratings 31 in the grating network 3 to be measured are arranged in a serial manner, and the wavelength variation of the jth (j is 1, 2, …, n) grating in the ith group can be represented as:
wherein,is a parameter of wavelength variation with the monitored physical quantity, VijIs the total variation of the monitored physical quantity of the jth grating.
Combine practical application, the utility model provides a time division/wavelength division multiplexing's fiber grating distributed sensing system has following advantage:
1) the small crosstalk between UW-FBGs can allow a single fiber to connect more than 1000 fiber grating sensors of the same wavelength in series.
2) The time division multiplexing mode can simultaneously measure all the sensors with the same wavelength in real time.
3) The time division-wavelength division multiplexing mode is combined with the layout method of the UW-FBG, and more than ten thousand of grating multiplexing can be easily realized.
4) The UW-FBG has the same structure, so that the structure of the sensing link is simplified, and the large-scale production of the sensing array is possible.
5) Compared with OFDR (optical frequency domain reflection technique), this method is not limited by the coherence of light sources, eliminating the possibility of polarization fading.
The utility model also provides a time/wavelength division multiplexing's fiber grating distributed sensing system's network planning method. This time/wavelength division multiplexing's fiber grating distributed sensing system does the utility model provides an arbitrary fiber grating distributed sensing system.
The following describes a network planning method of the time division/wavelength division multiplexing fiber grating distributed sensing system with reference to fig. 6. Referring to fig. 6, the network planning method includes:
and S11, determining the number of sensing points and the transmission distance required by the grating network 3 to be detected, the detection pulse width w and the grating reflectivity R according to the environment to be detected.
S12, according to the detected pulse widthwDetermining the minimum grating interval d in the time division multiplexing modemin。
S13, determining the maximum grating number N influenced by the return powerrpAnd the dynamic range of the demodulation subsystem 4 is determined according to the magnitude of the return power, and the amplification factor of the detection signal light is selected.
S14, determining the optimal multiplexing number N of the grating according to the signal-to-noise ratio curve of the detection signal lightopAnd the maximum recognizable number of gratings NidSelecting N according to monitoring requirementsopAnd NidAs the number of gratings N affected by the signal-to-noise ratio of the detected signalzy。
Alternatively, if measurement accuracy is required, N is chosenopNumber of gratings N as influenced by the signal-to-noise ratio of the detected signalzyIf a wider range of multiplexing numbers is required, N is selectedidNumber of gratings N as influenced by the signal-to-noise ratio of the detected signalzy。
S15, calculating the frequency spectrum distortion reflection spectrum caused by shadow effect under the time division multiplexing method, and determining the grating number N of the reflection spectrum distortion zero boundary pointshadow。
S16, adding Nrp、Nzy、NshadowThe minimum value in (1) is used as the number N of grating multiplexing under time division multiplexingTDMAnd is based on NTDMAnd dminThe specific position of the grating with the same center wavelength in the optical fiber is planned.
S17, determining the variation range Delta lambda of the wavelength with the sensing quantity to be measured, and determining the multiplexing number N in the wavelength division multiplexing mode according to the bandwidth B of the light sourceWDMAnd is based on NWDMAnd planning the distributed feedback laser tube.
Optionally, according to the selected grating characteristics, determining a variation range Δ λ of the wavelength with the sensing quantity to be measured, and reasonably planning the grouping in the wavelength division multiplexing mode according to the bandwidth B of the light source, ideally, the multiplexing number N of the wavelength division multiplexing modeWDM,NWDM=B/Δλ。
The total network multiplexing number N of the fiber bragg grating distributed sensing system obtained by planning by using the network planning method of the fiber bragg grating distributed sensing system of time division/wavelength division multiplexing is NTDMNWDM。
Because the embodiment of the utility model provides a time division/wavelength division multiplexing's fiber grating distributed sensing system's network planning method is applicable to the embodiment of the utility model provides an arbitrary fiber grating distributed sensing system, consequently this network planning method has the same or corresponding beneficial effect of its applicable fiber grating distributed sensing system, and here is no longer repeated.
Optionally, after S16, the method further includes planning the specific position of the grating with different center wavelengths in the optical fiber.
Because the time division multiplexing mode has the minimum reflection interval, but the wavelength division multiplexing mode does not have the minimum reflection interval, if necessary, the minimum reflection interval is less than dminThe grating interval of (2) is only needed to be used by crossing different groups of gratings (with different central wavelengths), but the interval distance of the same group of gratings (with the same central wavelength) is ensured to be larger than dmin. And reasonably planning the distribution of the grating network according to the key points.
The network planning method for the time division/wavelength division multiplexing fiber grating distributed sensing system is specifically explained below by taking the sensing system range as 10km as an example and combining with fig. 6. The network planning method comprises the following steps:
1) as the range of the preset sensing system is 10km, in order to improve the point distribution precision and the measurement precision of the sensor as much as possible, an ultra-weak fiber grating with the reflectivity of-32 dB is adopted, the optical pulse width of a detection signal is 30ns, the input optical power of a light source is 5dBm, the sampling frequency is 50MHz, and the bandwidth of a light source subsystem is 140 MHz;
2) according to the formula, the minimum grating interval d under time division multiplexing can be calculatedminIs 12 m;
3) determining the maximum multiplexing number N influenced by the return power according to the standard of-32 dBrp=1361;
4) Obtaining the SNR curve (SNR curve) of the detected signal light, and selecting the optimal number Nop=1259;
5) Obtaining a spectrum distortion reflection spectrum caused by shadow effect under the R-32 dB time division multiplexing method, and finding NshadowThe center wavelength can be identified without error when the wavelength is 800;
6) due to Nshadow<Nop<NrpSelecting NTDM=800;
7) If the light source bandwidth is 40nm and the grating wavelength interval is 2nm, then MWDM=40/2=20;
In this example, the grating interval under time division multiplexing is 10 km/800-12.5 m, which satisfies the design requirement, the grating pitch adopting the time division-wavelength division multiplexing mode can be reduced to 0.625m, and the multiplexing number of the total network is N-NTDMNWDM=16000。
The embodiment of the utility model provides a still provide a time/wavelength division multiplexing's fiber grating distributed sensing system's monitoring method, this monitoring method is applicable to the embodiment of the utility model provides an arbitrary fiber grating distributed sensing system who provides. The monitoring method comprises the following steps:
s201, inputting an acquisition interval and measurement attributes, wherein the measurement attributes comprise a scanning range, wavelength scanning precision, a detection signal light waveform, output power, an amplification factor of a demodulation subsystem, acquired data volume and acquisition times.
Optionally, according to the planned characteristics of the to-be-measured grating network, an operator selects the acquisition interval and the measurement attribute of the grating network on the operation interface of the central control subsystem.
S202, the central control subsystem generates a control instruction based on the acquisition interval and the measurement attribute.
S203, the central control subsystem controls the output wavelength of the light source subsystem to be lambdaiThe detection signal light of (1).
Optionally, the central control subsystem controls the wavelength tuning module to generate the wavelength λiThe control signal generator generates a waveform driving signal to enable the ith distributed feedback laser tube to output a wavelength lambda after receiving the commandiThe detection signal light of (1);
and S204, the detection signal light enters the grating network to be detected through the directional coupler, and is reflected at the grating in the grating network to be detected to form reflected light, and the reflected light enters the demodulation subsystem through the directional coupler.
And S205, the demodulation subsystem collects and processes the reflected light to form an electric signal, and samples the electric signal.
The photoelectric detection module in the demodulation subsystem converts the optical signal into an electric signal, and the signal conditioning module amplifies, shapes, reduces noise and the like the electric signal to condition the electric signal into the electric signal capable of collecting and extracting information. The central control subsystem sets the sampling frequency of the data acquisition module and controls the data acquisition module to sample the conditioned electric signals.
And S206, the central control subsystem 5 stores the sampling signal and performs first data processing.
And S207, if the stored sampling signal reaches the preset acquisition data volume, determining that one acquisition is finished, and adding one to the acquisition times.
And S208, if the acquisition frequency does not reach the preset acquisition frequency, repeatedly executing S203-S207, and averaging the data after the first data processing to obtain a second data processing result.
And S209, if the acquisition times reach the preset acquisition times and the scanning wavelength does not exceed the set scanning range, recording a second data processing result of the wavelength, adjusting the wavelength of the detection signal light output by the light source subsystem by the central control subsystem, and repeatedly executing S204 to S208.
Wherein the central control subsystem adjusting the wavelength of the detection signal light output by the light source subsystem comprises the central control subsystem setting lambdai=λi+ delta lambda (or lambda)i=λi-δλ)。
And S210, if the acquisition times reach the preset acquisition times and the scanning wavelength exceeds the set scanning range, calculating the variation of the measured physical quantity according to the second data processing result of each wavelength and the central wavelength of each grating to form a monitoring result.
And S211, if the monitoring result reaches the alarm limit value, outputting an alarm signal and sensor position information related to the alarm signal.
Since the monitoring method of the time division/wavelength division multiplexing fiber grating distributed sensing system provided by the embodiment of the invention is applicable to any one of the fiber grating distributed sensing systems provided by the embodiment of the invention, the monitoring method has the same or corresponding beneficial effects as the applicable fiber grating distributed sensing system, and details are not repeated here.
A monitoring method of the time division/wavelength division multiplexing fiber grating distributed sensing system is exemplarily given below with reference to fig. 6, and the monitoring method includes:
1) according to the planned characteristics of the grating network 3 to be measured, an operator selects the acquisition data range of the grating network 3 to be 15km and the measurement attribute to be real-time monitoring on the operation interface of the central control subsystem 5, and the acquisition interval is 30 s.
2) The central control subsystem 5 selects the scanning range of the output wavelength of the light source subsystem 1 to be 40nm (1520 nm-1560 nm) of the full wavelength, the wavelength scanning precision is 0.25nm, the optical waveform of the detection signal is a pulse signal, the pulse width is 30ns, the output power is 5dBm, the amplification factor of the demodulation subsystem 4 is 53dB, the single acquisition data is 32000byte (corresponding to the measurement range of 15km), the acquisition frequency is 1000 times and other parameters according to the selected measurement attributes, a control instruction is synthesized, and the central control subsystem 5 starts to carry out acquisition according to the control instruction;
3) the central control subsystem 5 controls the wavelength tuning module 54 to generate an output wavelength λiThe control signal generator generates a waveform driving signal, and the light source subsystem 1 receives the waveform driving signal and outputs a wavelength lambda at t0iThe detection signal light of (1);
4) the detection signal light enters the grating network 3 to be detected through the directional coupler 2, and the returned light signal enters the demodulation subsystem 4 through the directional coupler 2;
5) a photoelectric detection module 41 (such as an avalanche diode photoelectric detector) in the demodulation subsystem 4 converts an optical signal into an electrical signal, the electrical signal is amplified, shaped, subjected to noise reduction and the like through a signal conditioning module 42, conditioned into an electrical signal which can be collected and extracted, and fiber gratings with the same wavelength at different physical positions are identified according to a collection time ti;
6) the central control subsystem 5 sets the sampling frequency of the data acquisition module 43 to be 50MHz, samples the conditioned electric signal, stores the sampling signal, and the data processing module 59 performs data processing on the stored sampling signal;
7) after the stored data reach the set single acquisition data amount of 32000byte, confirming that one acquisition is finished, and adding one to an acquisition counter;
8) when the acquisition counter does not reach the set acquisition times of 1000, repeating the steps 3) to 7), and processing data according to the principle of averaging multiple measurements;
9) when the collection counter reaches the set collection times of 1000 and the scanning wavelength does not exceed the set scanning range (1520 nm-1560 nm), recording the test result of the wavelength, and setting lambda by the central control subsystemi=λi+0.25nm (or. lambda.)i=λi-0.25nm), repeating steps 3) to 9);
10) when the scanning wavelength exceeds the set scanning range (1520 nm-1560 nm), comparing the test results of all the wavelengths, recording the central wavelength of each grating, calculating the variation of the measured physical quantity, and displaying the monitoring result;
11) when the monitoring result reaches the alarm limit value, displaying an alarm signal and giving out sensing information of the position;
12) completing one sensing monitoring, and repeating the steps 2) to 12) after the set acquisition interval of 30 s.
Fig. 7 is a test curve of a time division/wavelength division multiplexing fiber grating distributed sensing system at a certain wavelength provided by an embodiment of the present invention, the grating network to be tested is a fiber grating under 30 same central wavelength time division multiplexing modes, the reflectivity is-30 dB, and the grating interval is 5 m. As shown in fig. 7, the central wavelength of each grating is slightly different due to the different grating environments, and the returned pulse light intensity is different when the probe pulse light of a certain wavelength is input. The central control subsystem records the maximum reflected light intensity at the location of each grating. After the light source subsystem has continuously scanned in wavelength, the central control subsystem can fit the spectrum of each grating in wavelength to find the central wavelength of each grating. And comparing with the initial center wavelength to obtain the variation of the monitored physical quantity.
Fig. 8 is a monitoring result diagram of the time division/wavelength division multiplexing fiber grating distributed sensing system monitoring a certain grating provided by the embodiment of the present invention. From the fitted curve, the center wavelength of the grating was identified as 1533.4 nm.
It is noted that, in the present application, relational terms such as "first" and "second," and the like, are used solely to distinguish one entity from another entity without necessarily requiring or implying any actual such relationship or order between such entities.
It should be noted that the foregoing is only a preferred embodiment of the present invention and the technical principles applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail with reference to the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the scope of the present invention.
Claims (14)
1. A time division/wavelength division multiplexing fiber grating distributed sensing system is characterized by comprising a light source subsystem, a directional coupler, a grating network to be detected, a demodulation subsystem and a central control subsystem;
the directional coupler comprises a first port, a second port and a third port;
the light source subsystem is connected with a first port of the directional coupler, a second port of the directional coupler is connected with the grating network to be tested, and the demodulation subsystem is connected with a third port of the directional coupler; the central control subsystem is connected with the light source subsystem and the demodulation subsystem;
the light source subsystem comprises at least one distributed feedback laser tube;
the grating network to be tested is a time division/wavelength division multiplexing sensor network and comprises at least one optical fiber, at least two gratings are integrated on the optical fiber, and the reflectivity of the gratings is less than-20 dB;
under the working state, the central control subsystem controls the light source subsystem to output detection signal light, the detection signal light enters the to-be-detected grating network through the directional coupler, the grating is reflected to form reflected light in the to-be-detected grating network, the reflected light enters the demodulation subsystem through the directional coupler, the demodulation subsystem collects and processes the reflected light to form an electric signal, and the central control subsystem processes the electric signal to form a monitoring result and outputs the monitoring result.
2. The fiber grating distributed sensing system of claim 1, wherein the light source subsystem comprises two or more distributed feedback laser tubes; the central wavelengths of the detection signal lights which can be output by the distributed feedback laser tubes are different.
3. The fiber grating distributed sensing system of claim 1, wherein the fiber grating distributed sensing system operates in a time division multiplexing mode;
in the time division multiplexing mode, the central wavelengths of at least two gratings in the same optical fiber are the same, and the interval d between any two adjacent gratings with the same central wavelength satisfies the requirement,
wherein C is the light propagation speed, n is the refractive index of the optical fiber, w is the optical pulse width of the detection signal, trFor rise time response, tfFor falling time response, tsIs the sampling period.
4. The fiber grating distributed sensing system of claim 3, wherein the number of gratings with the same center wavelength in the same fiber is N, which is the number of gratings with zero boundary point of reflection spectrum distortionshadowThe number N of gratings influenced by the signal-to-noise ratio of the detection signal lightzyAnd the maximum number of gratings N affected by the return powerrpThe minimum of the three.
6. The fiber grating distributed sensing system of claim 1, wherein the fiber grating distributed sensing system operates in a wavelength division multiplexing mode;
in the wavelength division multiplexing mode, the central wavelengths of at least two gratings in the optical fiber are different.
7. The fiber grating distributed sensing system of claim 6,
the monitoring result comprises a grating position L corresponding to the reflected light collected by the demodulation subsystem, and the L is obtained based on wavelength addressing.
8. The fiber grating distributed sensing system of claim 1, wherein the fiber grating distributed sensing system operates in a time division-wavelength division multiplexing mode;
in the time division-wavelength division multiplexing mode, the same optical fiber comprises at least two repeating units, and the repeating units are sequentially arranged; the repeating unit comprises at least two gratings, and the central wavelength of each grating is different in the same repeating unit;
the interval d between two gratings with the same central wavelength in any two adjacent repeating units1The requirements are met,
where C is the light propagation velocity, n is the refractive index of the optical fiber, w is the detection pulse width, trFor rise time response, tfFor falling time response, tsIs the sampling period.
9. The fiber grating distributed sensing system of claim 1, wherein the fiber grating distributed sensing system operates in a time division-wavelength division multiplexing mode;
in the time division-wavelength division multiplexing mode, the same optical fiber comprises at least two groups of gratings which are arranged in sequence; the central wavelengths of the gratings in the same group are the same; the central wavelengths of different groups of the gratings are different;
in the same group of the gratings, the interval d between two adjacent gratings2The requirements are met,
where C is the light propagation velocity, n is the refractive index of the optical fiber, w is the detection pulse width, trFor rise time response, tfFor falling time response, tsIs the sampling period.
10. The fiber grating distributed sensing system of claim 8 or 9, wherein the monitoring result comprises a time tijThe grating position L corresponding to the reflected light collected by the demodulation subsystemij,LijBased on the wavelength corresponding to the maximum value of powerThus obtaining the product.
11. The fiber grating distributed sensing system of claim 1, wherein the light source subsystem further comprises a laser temperature tuner, an optical waveguide, and a power compensation amplifier;
the laser temperature tuner comprises a first temperature controllable region;
the distributed feedback laser tube, the optical waveguide and the power compensation amplifier are all located in the first temperature controllable area and are sequentially arranged along the propagation direction of the detection signal light.
12. The fiber grating distributed sensing system of claim 11, wherein the central control subsystem comprises a laser tube biasing component, a signal generator, a laser tube selection component, a wavelength tuning module, a laser temperature tuner controller, a power control module, and a power compensation controller;
the signal generator is connected with each distributed feedback laser tube through the laser tube offset assembly;
the wavelength tuning module is connected with the laser temperature tuner controller and the laser tube selection component, and the laser temperature tuner controller is also connected with the laser temperature tuner;
the power control module is connected with the power compensation amplifier through the power compensation controller.
13. The fiber grating distributed sensing system of claim 12,
the light source subsystem also comprises a light detector for power monitoring, a light detector for wavelength monitoring, a first spectroscope, a second spectroscope, an etalon and a temperature tuner for the etalon;
the central control subsystem further comprises a temperature tuner controller for the etalon;
the first spectroscope and the second spectroscope are sequentially positioned on an optical path of the detection signal light between the power compensation amplifier and the grating network to be detected;
the optical detector for power monitoring is positioned on an optical path of a first sub-beam formed by the reflection of the detection signal light on the first beam splitter, and is connected with the power compensation controller;
the optical detector for wavelength monitoring is positioned on an optical path of a second sub-beam formed by the reflection of the detection signal light on the second beam splitter, and is connected with the wavelength tuning module;
the temperature tuner for the etalon comprises a second temperature controllable region; the etalon is positioned in the second temperature controllable area and is positioned on an optical path of the second sub-beam between the wavelength monitoring optical detector and the second spectroscope;
the temperature tuner for the etalon is connected with the wavelength tuning module through the temperature tuner controller for the etalon.
14. The fiber grating distributed sensing system of claim 13, wherein the demodulation subsystem comprises a photodetection module, a signal conditioning module, and a data acquisition module;
the central control subsystem also comprises a data processing module;
the photoelectric detection module is connected with a third port of the directional coupler and used for converting the reflected light into an electric signal;
the signal conditioning module is connected with the photoelectric detection module and is used for amplifying, shaping and denoising the electric signal;
the data acquisition module is connected with the signal conditioning module and is used for acquiring the processed electric signals;
the data processing module is connected with the data acquisition module and used for processing the acquired electric signals to form a monitoring result.
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