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    • 专利摘要:
    System and method of distributed characterization of refractive index variations of an optical fiber. Method and system for characterizing the local variations of the refractive index between different states of an optical fiber by comparing the amplitude profiles of a plurality of backscattered optical signals generated by rayleigh scattering by a plurality of optical signals pulsed when propagating by said optical fiber ; said pulsed optical signals comprising a instantaneous frequency profile variable in time and constant between pulses. The invention provides a characterization of high spatial resolution, sensitivity and speed, requiring a single pulse to characterize a state of the optical fiber instead of resorting to frequency sweeps in multiple pulses. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2622354A1
    申请号:ES201531736
    申请日:2015-11-30
    公开日:2017-07-06
    发明作者:Andrés GARCÍA RUIZ;Juan PASTOR GRAELLS;Sonia Martín López;Miguel González Herráez;Aitor VILLAFRANCA VELASCO;Hugo Fidalgo MARTINS
    申请人:Fiber Optics Consulting Services And Technologies SL (focus SL);Fiber Optics Consulting Services And Tech S L (focus S L);Consejo Superior de Investigaciones Cientificas CSIC;Universidad de Alcala de Henares UAH;
    IPC主号:
    专利说明:

    OBJECT OF THE INVENTION
    The present invention applies to the field of telecommunications and, in particular, to the industrial area of measurement and distributed characterization of optical fibers.
    BACKGROUND OF THE INVENTION
    The measurement of local variations of the refractive index of an optical fiber provides useful information for the distributed characterization of changes in the state in the fiber, as well as for distributed sensing schemes such as reflectometry in the phase-sensitive domain of time ( OTDR, from English 'Optical Time Domain Reflectometry'). Phase sensitive OTDR schemes, such as the one described in US 5,194,847 A, are based on the analysis of the scattered signal (from 'scattered') generated by Rayleigh dispersion (from 'Rayleigh scattering') when propagated a light pulsed by a fiber under test. When a fiber disturbance occurs, the dispersion profile and / or fiber refractive index profile changes. This affects the relative phases of the fields reflected by each dispersion center and, therefore, the phase profile and the intensity of the measured dispersed signal is modified. This information makes it possible to compare two states of the fiber and, therefore, to detect changes in temperature, deformations or vibrations along it, such as those generated by acoustic waves or intruders crossing a perimeter.
    Each fiber state can be characterized after the analysis of the scattered signal generated by propagating a single pulse of pulsed light. This allows the detection of changes of state in the fiber quite fast, with a temporary resolution of the order of the frequency of sending pulses to the optical fiber. Said pulse sending frequency is in turn limited by the length of the fiber, typically being of the order of -1ms for 100km of fiber. However, traditional phase sensitive OTDR schemes
    they do not allow quantifying the change detected, that is, they can detect that a change in temperature occurs, but they do not measure the extent of said change.
    Although traditional phase-sensitive OTDR systems are based exclusively on the use of pulsed light at a single frequency, there are recent techniques that allow you to send pulses of pulsed light with different frequencies. This is the case of the device for measuring variations in temperature, refractive index and birefringence described in US 2014/0185037 A1, which incorporates a frequency shifting unit that allows discrete sweep of pulsed light pulses. in a frequency range and with a previously defined step. This allows quantification with high resolution of changes in the fiber, reaching a resolution in the measurement of temperature changes of up to 0.01 ° C. The resolution of the measurement is associated with the passage of discrete frequency scanning, while the measurement range, that is, the length of fiber characterized, is associated with the frequency range of the discrete frequency scanning. Therefore, a high resolution measurement over a long measurement range requires a sweep of numerous frequencies, with the consequent increase in measurement time. Consequently, any change that occurs in the fiber during the time necessary to perform the scan will imply a noise added to the final measurement. In addition, high resolution measurements typically need to average the scattered signal corresponding to each pulse frequency, which also increases the measurement time. Thus, these schemes need a measurement time considerably longer than the schemes that use pulses with a single frequency and, therefore, are more adapted to quasi-static measurements, typically of the order of -1 minute. Additionally, the incorporation of a frequency shift unit also increases the complexity of the system.
    Traditional phase sensitive OTDR systems rely on the recovery of exclusively the dispersed signal strength. However, recent schemes also consider the phase of the dispersed signal, allowing quantify the amplitude of the changes in the fiber. This is the case, for example, of the acoustic wave detection device described in US 2014/0255023 A 1, which incorporates coherent detection units to characterize the phase and amplitude of the dispersed signal. However, the known methods of recovering the phase of the dispersed signal, such as I / Q separation (phase and quadrature separation), provide a limited temporal resolution. These methods are based on the division of the signal of interest into several components and the introduction of an optical path difference (T) between said divided components before recombining again. The temporal resolution of the recovered phase variation profile is determined by the optical path difference introduced between the divided components of the signal. Consequently, this technique is only suitable for a predetermined pulse shape and spatial resolution. In addition, any variation in the induced optical path difference is added to the recovered phase, thus introducing an error. For this reason, the optical path difference must be controlled with an accuracy less than the wavelength of the optical frequency used (typically around 1 micrometer). These phase recovery methods are therefore sensitive to environmental changes.
    To this problem is added that the interferometric phase and amplitude measurement methods developed for the measurement of arbitrary signal profiles require the use of a local oscillator with very precise synchronization. This implies greater design and control complexity, as well as added noise as a result of the local oscillator phase noise. Thus, the phase sensitive OTDR systems described that take into account the phase of the dispersed signal have a higher level of complexity and a higher level of noise associated with errors in the measurement of fiber refractive index variations.
    Systems based on the analysis in the time domain of the Brillouin dispersion (from 'Brillouin Optical Time Domain Analysis -BOTDA') are also known in the state of the art for the distributed characterization of a fiber refractive index variation optics, typically associated with distributed temperature measurement. This is the case, for example, of the system described in WO 1998/027406 A1. The main advantage of these methods over phase sensitive OTDRs is the possibility of making absolute temperature measurements along the fiber. On the other hand, in this case, a discrete sweep is carried out at frequencies that typically requires an average of about 100-1000 signals dispersed by each of the frequencies of the sweep, which represents a significant increase in the sampling time of temperatures . In addition, the resolution in temperatures is of the order of the degree Celsius, which may be insufficient in some demanding scenarios.
    Recently, BOTDA techniques have been developed that allow distributed characterization of deformations in an optical fiber without discrete frequency sweeps. Is the
    5 case of the dynamic deformation measuring device described in US 2013/0308682 A 1. However, these systems allow the characterization of a specific and limited range of deformations. In addition, the average of the fiber dispersed signal is still necessary, which limits the temporal resolution of the system.
    10 Finally, there are systems based on optical reflectometry in the frequency domain (OFDR) that allow the retrieval of fiber information with high spatial resolution. Such is the case, for example, of the device for obtaining spatial information of a fiber described in US 6,160,826 A 1. The OFDR technology has a spatial resolution inversely
    15 proportional to the frequency scanning range of the laser, while the fiber length to be monitored is inversely proportional to the minimum frequency variation over which good linearity is guaranteed. Given the difficulty of maintaining good linearity for small frequency variations over a wide frequency scan range, a higher spatial resolution implies a lower fiber optic characterization.
    20 scope. In addition, given the need to beat the received signal from the fiber with a local oscillator, the coherence length of the light source used must be greater than the order of fiber size. In this case, spatial resolutions of tens of micrometers have been achieved, but the sensing range is limited to a few hundred meters.
    25 Therefore, there is still a need in the state of the art for a distributed fiber optic characterization technique capable of measuring variations of the refractive index over a long measuring range and with high temporal resolution. Additionally, spatial resolution flexibility is required, flexibility in the range of amplitude of the
    30 variations of the refractive index, low complexity, high sensitivity and reduced impact of environmental changes.
    DESCRIPTION OF THE INVENTION
    The present invention solves the aforementioned problems by disclosing a system and a distributed measurement method of local variations of the refractive index of optical fibers, the local variations of the refractive index being measured between two states of the optical fiber by comparing two profiles of Rayleigh scattering amplitude generated by pulses of light of instantaneous frequency variable in time and constant between pulses. That is, pulses with chirp, chirp being said constant between pulses.
    In a first aspect of the invention, a distributed characterization system of the local refractive index variations of an optical fiber is presented comprising:
    - Emission means that generate at least two pulsed optical signals with the same instantaneous frequency profile, said instantaneous frequency profile being variable along the same pulse. Preferably, the variable instantaneous frequency profile comprises a linear increment ramp. Also preferably, each pulsed optical signal comprises at least one pulse of mostly rectangular amplitude profile. The emission means are further adapted to sequentially transmit at least two optical signals pulsed through a first end of the optical fiber, so that each pulsed optical signal characterizes a state of said fiber.
    - Receiving means that receive the backscattered optical signals generated by Rayleigh dispersion when the optical signals pulsed by the optical fiber are propagated. The receiving means are connected to the same end of the fiber as the emission means, for example, through an optical circulator.
    - Detection means that measure at least the amplitude profile of the backscattered optical signals. In a first preferred option, a single intensity photodetector measures the amplitude profile of the backscattered optical signal, while the amplitude and instantaneous frequency profile of the pulsed optical signal are fixed parameters stored in a system memory, and therefore not measured directly. In a second preferred option, a single coherent detector measures the amplitude profile of
    the backscattered optical signal and the amplitude and instantaneous frequency profile of the pulsed optical signal. Light guidance means, such as combiners, switches and / or optical delays are incorporated into the system to feed the pulsed optical signal and the backscattered optical signal into a coherent detector input without temporal overlap between both signals. In a third preferred option, a coherent detector measures the amplitude and instantaneous frequency profile of the pulsed optical signal and an intensity photodetector measures the amplitude profile of the backscattered optical signal. -Computer media that calculate the local variations of refractive index between different states of the optical fiber based on the amplitude profiles of the backscattered optical signal corresponding to each state of the fiber and the instantaneous frequency profile of the optical signals pulsed
    Preferably, the emission means of the system further comprise frequency stabilization means that reduce the frequency drifts of the pulsed optical signal and minimize the error of the measurement of local variations in the index of
    fiber refraction.
    Preferably, the broadcasting means of the system additionally comprise tuning means that dynamically modify the pulse length and the slope of the instantaneous frequency profile of the pulsed optical signals, allowing the spatial resolution, sensitivity to local refractive index variations to be varied. of the fiber, and the system error.
    Preferably, the system further comprises distributed amplification means, such as Raman amplification, which amplifies the pulsed optical signal within the optical fiber. Since the maximum measurement distance is limited by the power of the propagated pulses, this configuration allows to characterize longer fiber lengths.
    Preferably, the computing means are adapted to enter in the calculation of the local variations of refractive index of the fiber under test calibration information provided by the local refractive index variations of a calibration optical fiber. This option allows to distinguish between local variations of fiber refractive index and variations and / or noise in the amplitude and instantaneous frequency profiles of the pulsed optical signal, thus reducing measurement errors.
    Preferably, the emission means of the system further comprise polarization control means for controlling the polarization state of the pulsed optical signals. According to a first preferred option, the polarization control means determine the polarization state of the light (ie, choose if the light is depolarized, linearly polarized and on which axis, etc.) to optimize the system according to the measurement intended and the characteristics of the fiber under test, reducing errors. According to a second preferred option, the polarization control means generates pulses with orthogonal polarizations to perform birefringence measurements or local variations of fiber refractive index in different polarization axes. According to a third preferred option, the polarization control means simultaneously generate two pulses of orthogonal polarizations, said pulses being inconsistent with each other, also allowing birefringence measurements or local variations of refractive index of the fiber in different polarization axes. . The system may comprise specific optical components to maintain the polarization state of the light, such as polarization maintaining optical circulators. Note that no element of polarization discrimination in reception is necessary. The birefringence measurement is carried out through the comparison of two auxiliary measures for two orthogonal polarization axes, each auxiliary measurement being performed by correlation of intensity profiles of the reflected signals as described for any other measurement of local variations of system refractive index.
    Preferably, the computing means perform additional measures of distributed characterization of the optical fiber based on the backscattered light generated by Rayleigh dispersion by propagating high coherence pulses in a fiber under test, such as, for example, the distributed monitoring of vibrations along the fiber for a phase sensitive smell. The computing means can also be configured to correct said additional measures using the local variation information of refractive index measured by the system itself. Additional measures may be associated with any state distributed sensing technique.
    of the art that requires the measurement of backscattered light amplitude profiles, and may or may not require instantaneous frequency information of the signals involved. Such additional measures use the amplitude profiles (and, if necessary, instantaneous frequency) of the backscattered light already acquired to measure the local variations of fiber refractive index, and therefore do not imply the measurement of any additional signal or parameter parameters. , being able to run in parallel and without interfering with the measurements of local variations of fiber refractive index.
    In a second aspect of the invention, a distributed measurement method of local variations of the refractive index of an optical fiber is presented, comprising: Generating and transmitting high coherence pulsed optical signals with a preferably rectangular amplitude profile and the same profile of instantaneous frequency variable in time through a fiber under test. The instantaneous frequency profile preferably presents a linear variation throughout the pulse. Note that each pulsed optical signal can be formed by a single pulse or comprise a plurality of pulses.
    Also, note that the measurements made by the method of the invention are relative measurements between at least two states of the fiber, therefore requiring a minimum of two consecutive pulsed optical signals, but may extend to any larger number of pulsed optical signals.
    - Receive the backscattered optical signals generated by Rayleigh dispersion in the optical fiber. The transmission and reception are carried out at the same end of the fiber.
    - Measure the amplitude profiles of the backscattered optical signals using a coherent intensity photodetector or detector, whose output is input to a scanning medium, such as an oscilloscope.
    - Depending on the preferred option chosen, the method may comprise either measuring the amplitude and instantaneous frequency profiles of the pulsed optical signal by means of a coherent detector, or using the amplitude and instantaneous frequency profiles of the known pulsed optical signal.
    - Calculate the local variations in fiber refractive index between different states of the fiber, using at least information on the amplitude profiles of the backscattered optical signals corresponding to each state of the fiber and the instantaneous frequency profile common to the signals pulsed optics. Although the method can be implemented by obtaining the amplitude profile of the backscattered optical signal corresponding to each state of the fiber with a single pulse, the method preferably comprises obtaining the amplitude profile of the backscattered optical signal corresponding to each state of the fiber averaging multiple pulses, to improve the signal to noise ratio.
    Preferably, the step of calculating the local variations of fiber refractive index comprises:
    - Calculate a local correlation between the amplitude profiles of the backscattered optical signals corresponding to different states of the fiber, thus obtaining a local displacement profile between said profiles.
    - Calculate the local variations of fiber refractive index by multiplying the local displacement profile by a factor derived from the instantaneous frequency profile. More preferably, said factor depends on the slope and center frequency of the instantaneous frequency profile of the pulses and the average value of the refractive index of the fiber.
    Preferably, the method further comprises storing multiple amplitude profiles of the backscattered optical signals and optimizing a selection of profiles to be compared based on the speed of the local variations of the refractive index and the acquisition speed of the amplitude profiles.
    Finally, in a third aspect of the invention, a computer program is presented comprising the computer program code necessary to implement the method of the second aspect of the invention, when a specific integrated circuit is executed in a digital signal processor of the application, a microprocessor, a microcontroller or any other form of programmable hardware. Note that any preferred option and particular implementation of the device of the invention can be applied to the method and computer program of the invention, and vice versa.
    With the system, method and computer program of the invention, a measure of local variations of refractive index of the fiber of high spatial resolution, high sensitivity and high speed is provided. The resolution and sensitivity are also controllable by changing the pulse length and the slope of the instantaneous frequency profile of the pulsed optical signal. The measuring range, that is to say the characteristic fiber optic distances, is limited only by the intensity of the pulsed optical signal, allowing the incorporation of distributed amplification systems. The optical fiber under test is characterized continuously, allowing the measurement of local variations of refractive index with respect to an initial state of the fiber over time and the results can be provided in real time. Additionally, any known measurement can be made in the state of the art based on backscattering of pulsed optical signals, said measurement being also corrected using the refractive index variation information obtained. These and other advantages will be apparent in light of the detailed description of the invention.
    DESCRIPTION OF THE DRAWINGS
    To complement the description that is being made and in order to help a better understanding of the features of the invention, according to a preferred example of practical implementation thereof, a set of drawings is attached as an integral part of said description. where, for illustrative and non-limiting purposes, the following has been represented:
    Figure 1 shows a diagram showing the main components of a preferred embodiment of the system of the invention, as well as the optical fiber on which said system is applied.
    Figure 2 shows a diagram showing the amplitude and instantaneous frequency profiles of an example pulsed signal used by a particular implementation of the invention.
    Figures 3a and 3b exemplify the convolution between a pulse of the pulsed optical signal and two sections of the optical fiber by means of a diagram of the optical fiber and graphics.
    Figure 4 shows a series of graphs showing the principle of system operation, illustrating a local displacement of the amplitude profile of the backscattered optical signal corresponding to a local variation of the refractive index.
    Figure 5 shows a diagram in greater detail a particular implementation of the tunable coherent laser continuous source incorporating frequency stabilization.
    Figure 6 presents a diagram showing an alternative embodiment of the system of the invention incorporating distributed amplification to increase the characterization distance.
    Figure 7 exemplifies a more alternative embodiment of the system of the invention that includes a fiber section whose local variations of refractive index are known.
    Figure 8 presents an even more alternative embodiment of the system of the invention incorporating means for controlling the polarization state of the pulsed optical signal.
    Figure 9 shows an even more alternative embodiment of the system of the invention of the invention incorporating computing means that allow any measurement known in the state of the art to be performed with a phase-sensitive OTDR.
    Figure 10 represents a particular application of the embodiment in Figure 9, which allows measuring disturbances, such as vibrations, by compensating the noise introduced by the frequency drifts of the pulsed optical signal and / or local variations of refractive index of the fiber.
    Figure 11 represents a particular implementation of the invention using pulses of variable optical intensity for distributed measurement of nonlinear refractive index.
    Figure 12 represents a particular embodiment of the system of the invention with a single coherent detector for measuring both the pulsed signal and the backscattered optical signal.
    Figure 13 represents a particular embodiment of the system of the invention with a coherent detector for measuring the pulsed optical signal and an intensity photodetector for measuring the backscattered optical signal.
    PREFERRED EMBODIMENT OF THE INVENTION
    In this text, the term "comprises" and its derivations (such as "understanding", etc.) should not be understood in an exclusive sense, that is, these terms should not be construed as excluding the possibility that what is described and defined can include more elements, stages, etc.
    In view of this description and figures, the person skilled in the art may understand that the invention has been described according to some preferred embodiments thereof, but that multiple variations can be introduced in said preferred embodiments, without departing from the object of the invention such and as claimed. Likewise, descriptions of functions and elements perfectly known in the state of the art may have been omitted for clarity and conciseness.
    Figure 1 shows the main components of a first particular implementation of the system (1) of the invention, which implements the steps of a particular embodiment of the method of the invention. There is also an optical fiber (2) that exemplifies a possible operating scenario. The system (1) comprises emission means (3) that generate high coherence pulsed optical signals (9), each pulsed optical signal (9) comprising one or more pulses (91) with a rectangular amplitude profile and a frequency profile instantaneous linear (92) slope and center frequency Vo known.
    The emission means (3) comprise a coherent tunable laser continuous source (31), external modulation means (32) that convert the continuous light into pulsed light, and power control means (33) that adapt the optical output power to the desired measurement range, avoiding nonlinearities. The tunable coherent laser continuous source (31) can be constituted by a laser controlled by a current and temperature controller, which determines its central frequency vo, and to which a radiofrequency voltage is also applied, which allows continuous and repetitive sweeps in frequency around vo, with controllable slopes. By synchronizing the external modulation means (32) with the coherent tunable laser continuous source (31), a specific part of the signal emitted by said source can be chosen. By adjusting the slope of the instantaneous frequency of pulses of pulsed optical signals (9), the sensitivity to local variations of the refractive index of the optical fiber (2) can be adjusted, and by adjusting the length of the pulses the resolution can be adjusted system space. Power control means
    (33) may comprise an optical amplifier, such as an erbium-doped amplifier; followed by an optical filter centered on the central wavelength of the pulse spectrum, such as a wavelength division multiplexer (WDM) from the 'Wavelength Multisplier Division') or a Bragg network based filter (FBG, from English 'Fiber Bragg Grating') working on reflection, followed by a variable optical attenuator. The transmission band of the filter allows the passage of the spectrum of the pulses by filtering the noise introduced by the amplifier and the variable optical attenuator allows adjusting the optical output power. Note that other alternative emission means known in the state of the art can be applied for the generation of the pulsed optical signal of the present invention within the claimed scope.
    Pulsed optical signals (9) comprising at least a first pulsed optical signal and a second pulsed optical signal, generated are introduced at a first end of the optical fiber (2). Each pulsed optical signal (9), that is to say the first pulsed optical signal and the second pulsed optical signal, respectively generates a backscattered optical signal (10) when propagating within the optical fiber 2 by Rayleigh effect. The backscattered optical signals (10) are received by reception means (5) at the same first end of the optical fiber (2) used for transmission. For this purpose, the reception means (5) comprise a three-port optical circulator (51) such that the pulsed optical signal (9) is received by the transmission means (3) at a first port and transmitted to the fiber optic (2) through a second port. The backscattered optical signal (10) is received at the second port and transmitted to an intensity photodetector (7) through the third port of the optical circulator (51). Said intensity photodetector (7) measures the amplitude profile of the backscattered optical signal (10). Note that any light guidance technique known in the state of the art, which achieves an equivalent distribution of the signals, could be used alternatively. In addition, the reception means (5) can comprise any stage of signal conditioning and / or amplification (52).
    The system also comprises computing means (8) that determine the local variations of the refractive index of the optical fiber (2) based on, at least, the instantaneous frequency profile (92) of the generated pulses (91) and the measured amplitude profiles of the backscattered optical signal (10). At each instant of time, the optical fiber (2) has a state to which a local refractive index profile corresponds. Over time, the optical fiber (2) may change state due to P1 disturbances, generating the corresponding change in the local refractive index profile. By determining and comparing the amplitude profiles of the backscattered optical signal (10) generated during each state by equal pulsed optical signals (9), the computing means determine the local variations of the refractive index between the different states. The sensitivity of said determination depends on the slope of the instantaneous frequency of the pulsed optical signals (9), while the spatial resolution is typically of the same order of magnitude as the length of the pulses (91). The sensing range, that is, the distances characterized by the system, is limited only by the intensity of the backscattered optical signal (10). The measurement noise can be reduced by averaging multiple measurements of the same state of the optical fiber (2) obtained under the same conditions (i.e., pulsed pulsed optical signal (9) equal and without altering the state of the optical fiber) .
    Figure (2) shows in more detail the pulsed optical signals (9) generated by the emission means (3). Each pulsed optical signal (9) comprises one more pulses (91) of length Tp, separated by a duration TT. Each pulse (91) has a rectangular amplitude dial and an instantaneous frequency profile (92) in shape
    of ramp with a constant slope. In this case, the central frequency and the slope that define the instantaneous frequency pertil (92) are known, being typically stored in a memory accessible by computing means (8). It must be ensured that the coherence length of the tunable coherent light source (31) is greater than the pulse length. In addition, the time between the TT pulses must verify equation 1: 2nL / C, s, 'T
    Equation 1 where c is the speed of light in a vacuum, L is the length of the optical fiber (2), and n is the average refractive index of the optical fiber (2) at the center frequency Vo of the light source (31). The dependence of n (z) on the frequency along the spectral content of a pulse (91) is typically considered negligible. This ensures that only the signal generated from a pulse is recovered from the fiber at the same time, thus avoiding the superposition of signals from different regions of the optical fiber (2).
    The propagation, along fiber optic (2) of a pulse P (t, z) of the pulsed optical signal (9) with a rectangular intensity distillate, of Eo amplitude and Tp length, and a
    v (t) = v, + (óv / 2-óv * [t / rpD d.
    Linear instantaneous frequency pertil,, is eClr, with spectral content or.v around a central frequency vo, and slope of instantaneous frequency or.vlTp can be described by equation 2:
    Equation 2
    where t is time, z is the position along the optical fiber (2) (z = O at the fiber input connected to the receiving means (5) and rect (x) = 1 when Osxs1 and zero otherwise, it is considered that t = o when the front part of the pulse enters the optical fiber (2) (in z = O). n (z) is the local refractive index of the optical fiber (2) in za the center frequency Vo of the light source (31) Note that, if Vo is far from the resonant frequencies of the optical fiber (2) and o.v is not excessively large,
    the dependence of n (z) on the frequency v along the spectral content of a pulse of the pulsed optical signal (9) may be considered negligible.
    5 The backscattered optical signal (10) received at z = O in an instant of time t,It can be described by a complex electric field, E (t), which is given by theconvolution between a pulse (91) and the fiber dispersion profile, described by acomplex function, r (z), in a given fiber optic section (2)
    (t-r) · c t · c
    ZE [P; _] 2n 2n.
    1c / 2/1
    i21tt. : 1 (1-2 r1I (:) d: / c) i21t (Óu / 2-¡', u' (1-2 r1I (:) d: lC) f rp 1) (1-2 r1I (:) d: / c)
    E (t) = r (z) · Eo · e '· e' 'dz
    F
    Equation 3
    Note that E (t) results from contributions generated by the passage of a whole pulse of
    15 the pulsed optical signal (9), despite hardly having an integration along a fiber section of length Tp * d (2n). Note also that the considerations of the amplitude profile of E (t) received are set for z = O, corresponding to the junction of the circulator (51) and the fiber (2), while said signal is measured in the intensity photodetector. However, since the means of reception (5)
    20 remain constant between measurements, the development is still valid for the signals measured at the input of the intensity photodetector (7).
    Figures 3a and 3b illustrate in detail that the contributions to E (t) reflected at different points of the optical fiber (2), are generated by different parts of a pulse
    25 (91), which therefore have different instantaneous frequency v. In Figure 3a, E (t) is composed of the sum of the convolutions of r (z) of two sections of
    fiber other than ZE [ZI; Z2], [Z2; ZJ with parts of a pulse of the pulsed optical signal (9)
    with instantaneous frequencies UE [04; 03] '[U3; U]], respectively. In a moment
    later, reflected in figure (3) b, E (t + b.t) is composed of the sum of the
    convolutions of r (z) of two different fiber sections ZE [Z,; Z3), [Z3; Z,) with parts
    of the pulse of the pulsed optical signal (9) with instantaneous frequencies
    VE [V'V) [v 'v)
    4 '2' 2 ', respectively.
    5 Si.6.t is small enough for [Z ; Z2], [Z3; Z4] «[Z2; Z3] (that is, if the
    Pulse displacement is small in relation to its length), contributions to
    [Z · Z) [Z · Z)
    E (t) and E (t + .6.t) generated in , 2 '3' 4 are negligible, resulting in E (t) and
    E (t + .6.t) of reflections of the same fiber section [Z2; Z3] generated by two
    VE [V '' ') VE [V' ") ~ [v'v) + 8v
    pulses with a frequencies 3''1 and 4 '' - '2 3' 1 respectively, is
    10 to say, two equal pulses with a shift in ov frequency between them. Said frequency shift is proportional to a.6.t and the slope (dv / dt = .6.vlrp) of the instantaneous frequency copper (92) of the pulses (91).
    Note, finally, as can be deduced from equation (2), that a small
    15 local variation of refractive index of the optical fiber (2), ón (z), being ón (z) «n (z), can be approximately compensated with a corresponding variation of vo, Iv = -vo * In (z) / n (z). That is, approximately the same E (t) is obtained with a local refractive index n (z) and central frequency pulse vo, than with a local refractive index n (z) + ón (z) and central frequency pulse vo + iv.
    20 Figure (4), illustrates in detail the principle of measurement of the local variations of the index of refraction of the fiber that is derived from the above description. A variation of the local refractive index of the optical fiber (2), n (z) _ n (z) + ón (z), results in a temporary shift of the backscattered optical signal profile (10), E (t) ~ E (t + L t),
    25 which is equivalent to a variation of the pulse center frequency of the pulsed optical signal (9), vo-vo + ov. In particular, a first amplitude profile 10a of a first backscattered optical signal (10) that serves as a reference, a second amplitude profile (10b) corresponding to a first increment ón1 (Z) that generates a temporal displacement .6 is shown. t1, and a third amplitude profile (10c)
    30 corresponding to a second increase ón2 (Z) that generates a new temporal shift fit2 with respect to the second amplitude profile.
    For the calculation of the local variation of the refractive index between two states of the optical fiber (2), the measurements of two amplitude profiles of the backscattered optical signal (10) corresponding to the two states of the fiber, The (t) , E2 (t), provided by the intensity photodetector (7), and the center frequency Vo and instantaneous frequency slope dv / dt = fivlTp of the pulses the pulsed optical signal
    (9) are transmitted to the computing means (8), which first calculate the local displacement profile, 1 (1), between El (t) and E2 (t) through the maximum of their local correlation:
    1 (1) = max (correlation [The (t-Toorr, t + Toorr), E2 (t-Toorr, t + Tcorr)]) equation 4
    Note that the measurement error can be reduced using an adjustment function, such as a Gaussian one, to find the weighted maximum of the local correlation. The Toorr value is of the order of Tp, and can be optimized to reduce the measurement error and vary the spatial resolution.
    Next, the local variation of the refractive index between the two states of the optical fiber (2), ón (t) = ón (2nz / c), is calculated by applying the following relationship:
    ~ n (t) = ~ n (2nz / c) = - (n / vo) '(dv / dt)' 11 (1) equation 5
    Preferably, the instantaneous frequency profile (92) of the pulse is chosen such that the expected local variations of the refractive index generate small ov frequency variations in relation to the spectral content I1v of the pulses (91) (typically ~ v / l1v < O.1). In addition, the system preferably minimizes the frequency drifts Vr occurring between pulses (91) so that they are small in relation to the spectral content l1v, since said drift Vr is added to the calculated ov. An optimization of errors in the calculation of ón (z) is achieved with said drift minimization. In any case, note that for a rapid time of acquisition of amplitude profiles of the backscattered optical signals (10), typically of the order of TT-O.5ms, the local variations of the refractive index and the drift of
    Vr frequency between pulses (91) are typically reduced.
    The calculation resolution of the local displacement profile, ti (t) is related to the bandwidth of the intensity photodetector (7) and the scanning means associated with said photodetector. Typically, the sampling of the amplitude profile E (t) should be at least 50-100 times greater than 11Tp. Assuming a pulse of the pulsed optical signal (9) with good linearity of the instantaneous frequency profile and low noise, the resolution of calculation of local variations of the refractive index is limited only by the calculation resolution of ti (/) and the slope dv / dt, therefore providing great flexibility.
    As a typical operating example of the present invention, a pulse (91) of 100ns, with a spectral content ~ v = 1GHz centered at 193THz, with an intensity photodetector (7) and respective scanning means with a bandwidth of
    - 10GHz, allows to measure variations in fiber refractive index (5n-1O · _10 · 6. This would be equivalent, for example, to temperature changes in the fiber of -1-100mK and frequency shifts 6v-1-100MHz. at the speed of measurement of local variations of the refractive index of the fiber 5n, the present invention needs a single pulsed optical signal pulse to characterize a state of the fiber, allowing a quasi-continuous measurement: for example, for a fiber of 50km, the time between the TT pulses (and therefore between measurements of local variations of the fiber refractive index (5n), given by equation. 1, can have a typical value of -0.5ms.
    The calculation of the local variations of the refractive index 5n (z) can also comprise the storage of the measured amplitude profiles. For certain measurement parameters (i.e., spectral content f) .v, slope dv / dt and fixed detection bandwidth) a range of local variations of the fiber refractive index corresponds between amplitude profiles corresponding to variations of frequency sufficiently greater than the minimum resolution of the measurement and sufficiently smaller than the spectral content ~ v, such that the measurement is optimal. If after the comparison between two amplitude profiles it turns out that the refractive index variations are not optimal, the estimation (not optimal) of the refractive index variations obtained can be used to choose another pair of amplitude profiles to be compared. more favorable. Thus, the selection of the pairs of profiles compared according to the speed of the local variations of the refractive index and the acquisition speed can be optimized manually or automatically, and the errors and the necessary computational cost can be reduced. Likewise, cumulative measurements of local variations of the fiber refractive index corresponding to arbitrary value frequency variations (Total (t »>. Or, v) may be made, as long as the variation between two consecutive profiles i, j, is small (óv¡.j (t) «. or, v).
    Note that the calculation of the local variations of the refractive index can be performed with other profiles of amplitude and instantaneous frequency different from those described in this particular implementation, provided that different instants of the same pulse comprise different frequency components and said distribution is constant between pulses. In particular, the person skilled in the art will understand that the pulses can present deviations in their amplitude and instantaneous frequency profile with respect to the ideal design forms due to limitations of the emission means (3). For example, the frequency ramp may have non-linear increments, or the pulse shape may not be perfectly rectangular.
    Note also that, in the particular implementation described, the amplitude and instantaneous frequency profiles of the pulsed optical signal (9) are not measured directly. Said profiles are previously stored in the computing means (8) or in a system memory. Note that multiple amplitude and instantaneous frequency profile data from multiple configurations of the broadcast media (3) can be saved and selected. In addition, variations in such data stored with other factors, such as environmental factors, can be stored in memory and applied accordingly. The calculations made by the computing means (8) are the same regardless of whether the amplitude and instantaneous frequency profiles of the pulsed optical signal (9) are measured or simply recovered from memory.
    Figure 5 shows an implementation of the emission means (3) of the invention, in which the tunable coherent laser continuous source (31) comprises frequency stabilization means, thus reducing the frequency drifts and the measurement error of local variations of refractive index. The frequency stabilization means set the center frequency Vo of a semiconductor laser
    (311) to an absorption line of a gas cell (313), using a divider (312) that divides the signal emitted by (311) and introduces a part into the gas cell (313). A lock-in amplifier (from 'Iock-in amplifier) (314) acts as a feedback system and introduces current injections into the laser controller (311), which compensates for laser frequency drifts.
    Figure 6 shows an alternative embodiment of the system of the invention, in which the sensing range is increased by distributed amplification, such as Raman amplification. The sensing range is limited only by the intensity of the backscattered optical signal (10) and can therefore be extended using this proposal. In this particular case, the system comprises a bidirectional distributed amplifier (11). The first output of the distributed amplifier (11) is introduced at the first end of the optical fiber (2) with the pulsed optical signal (9) by means of a combiner (12), and the second output of the distributed amplifier (11) is introduced by the second end of the fiber optic (2). Note that any other distributed amplification technique known in the state of the art can be used, such as the combination of Raman and Brillouin amplification. Distances typically exceeding 100 km can be reached with this configuration.
    Figure 7 shows a more alternative embodiment of the system of the invention, which uses a first section (21) of the optical fiber (2) whose local variations of refractive index are known. Note that such local variations may be null in particular implementations. The local variations of refractive index of the fiber optic section (21) are introduced or stored in the computing means (8), being used as a calibration reference. The computing means (8) use the measurements of the first section (21) to correct the measurements of a second section (22) whose refractive index variations are unknown. A distinction is thus made between local variations in the index of refraction of the optical fiber (2) and variations and / or noise in the amplitude and instantaneous frequency profiles of the pulses of the pulsed optical signal (9), reducing measurement errors. Note that, even in alternative implementations without a first reference section (21), the computing means (8) can also use an estimate of the average variation of the refractive index of the optical fiber (2) to compensate for errors introduced by the noise of the amplitude profiles and instantaneous frequency of the pulses (91), which typically occur at much smaller time scales.
    Figure 8 an even more alternative embodiment of the system of the invention, comprising in the emission means (3), polarization control means (34). Depending on the particular implementation, the polarization control means may comprise a polarizer to generate linearly polarized light, or comprise a polarization switch to generate light in different polarization states. By generating pulses (91) in orthogonal polarization states, it is possible to measure the local refractive index in orthogonal fiber axes and the difference between them (i.e. local birefringence, if the polarization axes of the pulsed optical signal are aligned with the fiber refractive index axes). If the difference in local refractive index between two orthogonal axes of the fiber ón.1 is equivalent to a frequency variation, oV.1;: - vo * ón.1 / n longer than the spectral content /).v of the pulse (91), emission means (3) can be used which also allows a frequency sweep to be performed with a constant step </) .v, until a peak is found in the correlation function between two amplitude profiles acquired in orthogonal axes of polarization, with a central frequency vo 'of the pulses (91). After calculating the local displacement profile, 1 '. 1 (1), as previously described, the refractive index difference profile between the orthogonal axes of the fiber ón.1 (z) is calculated as: ~ n, (t) = ~ n, (2nzlc) = - (n / von (dv / dt) · 1 , (1) + (vo'-vo)] Equation 6
    In another implementation, the polarization control means (34) simultaneously generate two pulses with orthogonal polarizations and inconsistent with each other, thus generating a depolarized pulsed optical signal (9). The calculation of the maximum of the local autocorrelation of the amplitude profile of the backscattered optical signal (10) will have three peaks, one placed at zero, and two symmetrically placed around zero, which allow to calculate the value of the refractive index difference Local 1 (z) between two orthogonal fiber axes (i.e. local birefringence) with a single pulse of pulsed optical signal (9). If necessary, the system may include specific optical components to maintain the state of polarization of light, such as an optical circulator maintaining polarization (512).
    Figure 9 shows an even more alternative embodiment of the system of the invention system of the invention, in which the computing means (8) comprise a first computing module (81) to calculate the local variation of the fiber refractive index optics (2) and a second computing module (82) that performs additional measures of distributed characterization based on backscattered optical signal generated by Rayleigh scattering of high coherence pulsed light. Such additional measures may comprise, for example, distributed monitoring of P2 vibrations along the optical fiber (2). Said distributed monitoring of vibrations uses the amplitude profiles of the backscattered optical signal (10) that are already acquired to measure local variations of refractive index, so it does not imply the measurement of any additional parameter signaling. The first module (81) and the second module (82) can act in parallel without interfering with the measurements of local variations of refractive index. Note also that if the additional measurement requires the recovery of the phase profile of the backscattered optical signal, the system may comprise a coherent detector (6) instead of the intensity photodetector (7).
    Figure 10 shows a possible application of the implementation described in Figure 9, which combines measurement of local variations of refractive index and vibration monitoring P2. This allows, for example, to minimize noise due to thermal drifts of the fiber or at the center frequency of the light source. That is, the system of the invention allows the following measurements to be made:
    • Only measure the temperature.
    • Measure only the vibration.
    • jointly measure temperature and vibration, each measurement being
    Direct and independent.
    • jointly measure temperature and vibration, so that one of the measurements is used to correct the results of the other.
    Assume an initial state with its consequent first amplitude profile 10a of the backscattered optical signal (10). When the fiber undergoes a P2 disturbance, such as a vibration, a fourth amplitude profile 10d is generated, with local variation of amplitude M. Subsequently, it returns to a state equal to the initial one, with a fifth amplitude profile 10e equal to first amplitude profile 10a. If there are no variations in the local refractive index of the fiber or drifts of the central frequency of the light source, the local disturbance P2 can be measured by comparing the amplitude profiles corresponding to the different states of the fiber at the same point.
    On the contrary, if a first disturbance P1 associated with a variation in refractive index and a second disturbance P2 is applied simultaneously to the initial state of the fiber. such as a vibration, the corresponding amplitude profile (that is, the sixth amplitude profile 10f) will record a local change of amplitude M and also a temporal shift 6.4. Note that the first disturbance P1 and the second disturbance P2 have different characteristics. The first disturbance P1 translates into a change in the average refractive index profile of the optical fiber (2) along a length of fiber section of the order of the pulses of the pulsed optical signal (9), n ( z), without changing the fiber dispersion profile, described by a complex function, r (z), in equation (2). The second disturbance P2 translates into a random change of the fiber dispersion profile, r (z), and with variations that can occur in lengths much shorter than the pulse length of the pulsed optical signal (9), without changing the refractive index profile of the optical fiber (2), n (z). At the end of the P2 disturbance, the seventh amplitude profile 10g will reflect a shape equal to that of the first amplitude profile 10a, but a temporal shift 6.t5 associated with the variation of refractive index between both measurements. While in a conventional vibration measurement system, this would imply an error in the characterization of the vibration, the present invention makes it possible to determine the temporal displacements 6.4 and .6 by correlation of the amplitude profiles in the first computation module (81). .t5, and use this information to compare equivalent points during the characterization of
    vibrations
    That is, first, the first module (81) of the computing means (8) determines the variation of the local refractive index of the first disturbance P1 by correlation of the amplitude profiles. Then, in said amplitude profiles, the temporal displacement associated with said refractive index variation is compensated. Finally, the second module uses the compensated amplitude profiles to characterize the second disturbance P2.
    Alternatively, a high! J.v can be used compared to the expected drifts in the laser and the expected variations of! J.n. In this way, the temporal displacements of the resulting trace will be very small, while maintaining its sensitivity to vibrations. This configuration can be used to perform vibration measurements by reducing the noise associated with laser drifts and refractive index variations. The higher the spectral content of the transmitted pulses, the greater the noise reduction associated with these factors. Note that in this case it is not necessary to use the first computing module (81).
    Figure 11 exemplifies another possible particular implementation of the system in which the emission means (3) generate pulses (91) of known and variable optical intensity h. In particular, a first pulse 91a is presented which allows measuring a first amplitude profile 1 Da, and a second pulse 91 b of different optical intensity, whose propagation results in the measurement of an eighth amplitude profile 10h. The eighth amplitude profile 10h has a delay! J.t6 caused by the change in intensity of the second pulse 91 b Y by the local nonlinear refractive index of the optical fiber (2). Said index of local nonlinear refraction, n2 (z), is measured by the system through the variations of index of local refractive onk (t) obtained for different optical intensities h of the pulses for the same state of the fiber, using :
    ~ n. (t) = n + 1, • n, (z) Equation 7
    For long distances of fiber, it is necessary to take into account the deformations of the pulses when propagating in the fiber due to the non-linear effects. Note that if the fiber is homogeneous, it is possible to characterize the local nonlinear refractive index for short fiber distances and assume that it remains constant throughout the rest of the fiber.
    Figure 12 presents another implementation of the system and method of the invention in which the pulses of the pulsed optical signal (9) are not known a priori, but rather a coherent detector (6) is used to measure the amplitude profile and the instantaneous frequency profile (92) of the pulsed optical signal (9) and the amplitude profile of the backscattered optical signal (10). The pulsed optical signal (9) emitted by the emission means (3) is divided by a first splitter (4) into two arms. The first arm is inserted into the optical fiber (2), while the second arm is inserted into an optical combiner (14), which also receives the backscattered optical signal (10) and sends both signals to the coherent detector (6). To avoid any overlap between the pulsed optical signal (9) and the backscattered optical signal (10), an optical delay 1 (3) is added between the splitter (4) and the optical circulator (51), which can be implemented, by example, with a single mode fiber. In addition, the limitation in the repetition period of the TT pulses to ensure that there is no superposition of different signals in the coherent detector (6), will now be given by:
    Equation 8
    where D is the delay induced by the optical delay (13). It should be noted that the computing means (8) handle any synchronization and adjustments necessary for the measurement of both signals, alternatively, with the same coherent detector (6).
    Any alternative implementation that allows both signals to be sent to the same coherent detector (6) without overlapping can be used alternatively. For example, the optical combiner (14) can be replaced by an optical switch, allowing both configurations with or without the optical delay (13). In addition, the optical delay (13) can be implemented in other positions of the system reaching a similar effect, such as the path followed by the backscattered optical signal (10) within the system 1. For example, the optical delay (13) can be located between the optical circulator (51) and the optical combiner (14). It must be taken into account that the pulses (91) generated by the emission means (3) must not change during the characterization of the two or more states used to calculate the refractive index variation. Since said pulses (91) do not vary during that time interval, the optical switch can be programmed to transmit the pulsed optical signal (9) to the coherent detector (6) only once during all the time that the pulses (91) remain unchanged. .
    Finally, Figure 13 presents a final implementation of the system of the invention in which the pulses (91) of the pulsed optical signal (9) are not known and a coherent detector (6) and an intensity photodetector (7) are used. to characterize the pulsed optical signal (9) and the backscattered optical signal (10), respectively. The pulsed optical signal emitted by the means (3) is divided by a first splitter (4) into two arms. The first arm is introduced into the optical fiber (2), while the second arm is introduced to a coherent detector (6) that is used to measure the pertil of the amplitude and instantaneous frequency of the pulsed optical signal (9). The backscattered optical signal (10) is input to an intensity photodetector (7) that is used to measure the amplitude profile of the backscattered optical signal (10).
    It should be noted that any feature or implementation presented for the emission means (3) and the computing means (8) (for example polarization control, use of different pulse intensities, additional calculations, etc.) is compatible with any particular implementation of the detection means (a single coherent detector for the pulsed optical signal and the backscattered optical signal, multiple detectors, a single detector combined with previously stored information, etc.).
    Note also that the measurements of local variations in refractive index of the fiber recovered by the invention can be used, for example, to implement
    distributed deformation, vibration, birefringence or temperature sensors. Any other use or applications of the measurement of local variations of fiber refractive index known in the state of the art can also be implemented with the system and method described.
    The work that has led to this invention has received funding from the 'People Program (Marie Curie Actions), European Union's Seventh Framework
    Program (FP7I2007-2013) 'under the REA grant agreement n ° [608099]; and from EURAMET through project 141ND13 JRP-i22.
    权利要求:
    Claims (20)
    [1]
    1. Distributed characterization system (1) of local variations of refractive index of an optical fiber (2) comprising:
    5 • emission means (3) adapted to generate at least two pulsed optical signals (9) and transmit said pulsed optical signals (9) through a first end of the optical fiber (2);
    • reception means (5) adapted to receive at the first end of the optical fiber (2) at least one first backscattered optical signal (10) generated
    10 by Rayleigh dispersion by a first pulsed optical signal of the pulsed optical signals (9) when propagated by the optical fiber (2), and a second backscattered optical signal (10) generated by Rayleigh dispersion by a second pulsed optical signal of the signals pulsed optics (9) when propagated by the optical fiber (2); Y
    • detection means adapted to measure at least a first amplitude profile of the at least a first backscattered optical signal (10) and a second amplitude profile of the at least a second backscattered optical signal (10);
    the system (1) being characterized in that:
    • the transmission means (3) are adapted to generate the optical signals
    20 pulses (9) with the same instantaneous frequency profile (92), said instantaneous frequency profile (92) being variable in time; Y
    • comprises computing means (8) configured to calculate the local variations of the refractive index of the optical fiber (2) based on at least the instantaneous frequency profile (92), the first amplitude profile and the second profile
    25 amplitude
    [2]
    2. System according to claim 1 characterized in that the instantaneous frequency profile (92) comprises at least one linear ramp.
    System according to any one of the preceding claims, characterized in that the first pulsed optical signals (9) comprise at least one rectangular pulse (91).
    [4]
    Four. System according to any one of the preceding claims, characterized in that it comprises a memory accessible by the computing means (8), the instantaneous frequency profile (92) being stored in said memory.
    [5]
    5. System according to any one of claims 1 to 3 characterized in that the detection means comprise at least one coherent detector (6) adapted to measure the instantaneous frequency profile (92).
    [6]
    6. System according to claim 5 characterized in that the detection means comprise a single coherent detector (6) connected to the transmission means (3) and the reception means (5), the coherent detector (6) being adapted to measure , in addition to the instantaneous frequency profile (92), the first amplitude profile and the second amplitude profile;
    [7]
    7. System according to claim 5 characterized in that the detection means comprise:
    • a coherent detector (6) connected to the emission means (3), the coherent detector (6) being adapted to measure the instantaneous frequency profile (92); Y
    • an intensity photodetector (7) connected to the receiving means (5), the intensity photodetector (7) being adapted to measure the first amplitude profile and the second amplitude profile.
    [8]
    8. System according to any one of the preceding claims characterized in that the emission means (3) additionally comprise frequency stabilization means.
    [9]
    9. System according to any one of the preceding claims characterized in that the system additionally comprises bidirectional distributed amplifier (11) adapted to amplify pulsed optical signals (9), the first amplitude profile and the second amplitude profile in the optical fiber ( 2).
    [10]
    10. System according to any one of the preceding claims
    characterized in that the system additionally comprises tuning means adapted to dynamically modify a pulse length and a slope of the instantaneous frequency profile (92) of the pulsed optical signals (9).
    [11 ]
    eleven . System according to any one of the preceding claims characterized in that the computing means (8) are adapted to calculate the local variations of the refractive index of the optical fiber (2) based on, in addition, local variations of the index of Known refraction of a calibration fiber (21).
    [12]
    12. System according to any one of the preceding claims characterized in that the emission means (3) comprise polarization control means (34) adapted to control a polarization state of at least one of the pulsed optical signals (9).
    [13]
    13. System according to claim 12 characterized in that the emulsion means (3) are adapted to generate at least two pulsed optical signals (9) with orthogonal polarizations and because the computing means (8) are adapted to measure the index variation of local refraction for each of the orthogonal polarizations.
    [14]
    14. System according to claim 12 characterized in that the emission means (3) are adapted to simultaneously generate two pulses (91) inconsistent with each other, said two pulses (91) having orthogonal polarizations; and because the computing means (8) are adapted to measure the variation of local refractive index for each of the orthogonal polarizations.
    [15]
    fifteen. System according to any one of the preceding claims characterized in that the computing means (8) are further adapted to perform additional measures of distributed characterization of the optical fiber (2) from at least the backscattered optical signals (10) , and said additional measurements being carried out in parallel to the calculation of local variations of refractive index.
    [16]
    16. System according to any of claims 1 to 14, characterized in that:
    • The emission means (3) are further adapted to generate the pulsed optical signals (9) with a spectral content greater than expected drifts of an emission laser and a spectral range necessary to measure the local variations of refractive index, and
    • The computing means (8) are configured to perform a distributed measurement of vibrations insensitive to said drifts and said local refractive index variations.
    [17]
    17. System according to any of the preceding claims characterized in that the emission means (3) are adapted to generate pulses (91) of different optical intensities and because the computing means (8) are adapted to calculate a non-linear refractive index local optical fiber (2) from local variations of refractive index of an optical fiber (2) for pulses (91) of different optical intensities.
    [18]
    18. Method of distributed characterization of local variations of the refractive index of an optical fiber (2) comprising:
    • generate at least a first pulsed optical signal (9) of the pulsed optical signals (9) and a second pulsed optical signal of the pulsed optical signals (9);
    • transmitting said pulsed optical signals (9)) through a first end of the optical fiber (2);
    • receiving at the first end of the optical fiber (2) at least a first backscattered optical signal (10) generated by Rayleigh scattering by the first pulsed optical signal (9) of the pulsed optical signals (9) when propagated by the optical fiber ( 2), and a second backscattered optical signal (10) generated by Rayleigh scattering by second pulsed optical signal of the pulsed optical signals (9) when propagated by the optical fiber (2); Y
    • measuring at least a first amplitude profile of the at least a first backscattered optical signal (10) and a second amplitude profile of the at least a second backscattered optical signal (10);
    the method being characterized by comprising:
    • generate the pulsed optical signals (9) with the same instantaneous frequency profile (92), said instantaneous frequency profile (92) being variable in time; Y
    5 • calculate the local variations of the refractive index of the optical fiber (2) based on at least the instantaneous frequency profile (92), the first amplitude profile and the second amplitude profile.
    [19]
    19. Method according to claim 18 characterized in that the step of calculating the local variations of the refractive index in turn comprises:
    • calculate a local displacement profile based on a local correlation between the first amplitude profile and the second amplitude profile; Y
    • multiply the local displacement profile by a factor derived from the instantaneous frequency profile (92).
    [20]
    20. Method according to any one of claims 18 and 19 characterized in that it further comprises storing multiple amplitude profiles of the backscattered optical signals (10) and optimizing a selection of profiles to be compared based on a speed of local variations of the refractive index and a speed of
    20 acquisition of amplitude profiles.
    [21 ]
    twenty-one . Computer program comprising computer program code necessary to perform the steps of the method of any one of claims 18 to 20, when said program is executed in a digital signal processor, a
    25 application-specific integrated circuit, a microprocessor, a microcontroller or a form of programmable hardware.
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP2002219B1|2006-04-03|2014-12-03|BRITISH TELECOMMUNICATIONS public limited company|Evaluating the position of a disturbance|
    GB0820658D0|2008-11-12|2008-12-17|Rogers Alan J|Directionality for distributed event location |EP3680638B1|2019-01-11|2021-11-03|AiQ Dienstleistungen UG |Distributed acoustic sensing and sensor integrity monitoring|
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    ES201531736A|ES2622354B1|2015-11-30|2015-11-30|DISTRIBUTED CHARACTERIZATION SYSTEM AND METHOD OF REFRACTION INDEX VARIATIONS OF AN OPTICAL FIBER|ES201531736A| ES2622354B1|2015-11-30|2015-11-30|DISTRIBUTED CHARACTERIZATION SYSTEM AND METHOD OF REFRACTION INDEX VARIATIONS OF AN OPTICAL FIBER|
    PCT/ES2016/070851| WO2017093588A1|2015-11-30|2016-11-30|System and method for the distributed characterisation of variations in the refractive index of an optical fibre|
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