Patent Description:
Optical fibers are sensitive to surrounding mechanical perturbations which affect light propagation in the fiber, e.g. induce fiber length variations, potentially resulting in variations of phase, intensity, and polarization of fiber-light propagating in the optical fiber. This effect can be exploited e.g. in standard single mode fibers (SSMF) deployed in telecommunication systems. Distributed Acoustic/Vibration Sensing (DAS/DVS) allows for detection of mechanical perturbation at various locations along an optical fiber using e.g. Rayleigh backscattering. Randomly distributed Rayleigh backscattering spots exist in the fiber as imperfections during its fabrication process. By capturing the optical signal that is reflected from these spots, optical phase changes induced by mechanical events impacting a deployed optical fiber may be detected and analyzed. Various optical systems of distributed sensing may use coherent optical-time-domain reflectometry (OTDR), which may also be referred to as phase-OTDR, in which an interrogator sends e.g. short pulses of coherent light into an optical fiber, and a coherent optical detector uses interferometry to detect optical phase variations of the back-scattered or back-reflected light.

A recent European patent application <CIT> discloses a dual-polarization probing method to monitor back reflections from a span of optical fiber using two mutually orthogonal complementary (e.g. Golay) pairs of binary sequences applied simultaneously in phase and quadrature on two orthogonal polarizations of probing light. The method employs the two polarizations of light at both the optical receiver and the optical transmitter, and thus uses a multi-input, multi-output (MIMO) sensing approach.

<CIT> discloses a method of measurement of the birefringence of an optical fibre and a method to configure the light generation means used in it.

An aspect of the present disclosure relates to an apparatus for sensing via an optical fiber link. The apparatus may comprise a digital source of test sequences, a coherent optical transmitter (COT) to transmit to the optical fiber 'link a light signal carrying different portions of the test sequences on orthogonal polarizations thereof, a coherent optical receiver (COR) capable of separately measuring different polarization components of backscattered light received therein and to output signals indicative thereof, an optical switch operable to selectively optically connect the COT and the COR to an end of an optical fiber link in a first configuration of the optical switch and to optically back-to-back connect the COT and the COR in a second configuration of the optical switch, and an electrical processor connected to receive the signals from the COT and configured estimate a gain imbalance between a first and a second of the orthogonal polarizations in at least one of the COT and the COR based on the signals received from the COR in the second configuration, and to measure a portion of the light signal backscattered by the optical fiber link in the first configuration.

A related aspect of the present disclosure provides a method for sensing via an optical fiber link, the method comprising: operating a coherent optical transmitter (COT) and a coherent optical receiver (COR) in a first configuration, the COT and the COR being optically connected to a same end of an optical fiber link in the first configuration; switching to operate the COT and COR in a second configuration, the COR being optically back-to-back connected to the COT in the second configuration; processing signals from the COR to estimate a polarization gain imbalance in at least one of the COT and the COR in the second configuration; and processing signals from the COR to measure a portion of the light signal backscattered by the optical fiber link in the first configuration; and wherein the COT transmits a light signal carrying different test signals on orthogonal polarizations thereof in each of the configurations; and wherein the COR separately measures different polarization components of received light and outputs signals indicative thereof in both configurations.

Embodiments disclosed herein will be described in greater detail with reference to the accompanying drawings which represent preferred embodiments thereof, in which like elements are indicated with like reference numerals, and wherein:.

In the following description, for purposes of explanation and not limitation, specific details are set forth, such as particular circuits, circuit components, techniques, etc. in order to provide a thorough understanding of the present invention. However, it will be apparent to one skilled in the art that the present invention may be practiced in other embodiments that depart from these specific details. In other instances, detailed descriptions of well-known methods, devices, and circuits may be omitted so as not to obscure the description of the present invention. All statements herein reciting principles, aspects, and embodiments of the invention, as well as specific examples thereof, are intended to encompass both structural and functional equivalents thereof.

Note that as used herein, the terms "first", "second" and so forth are not intended to imply sequential ordering, but rather are intended to distinguish one element from another, unless explicitly stated. Similarly, sequential ordering of method steps does not imply a requirement of sequential order of their execution, unless explicitly stated. The term "connected" may encompass direct connections or indirect connections through intermediate elements, unless explicitly stated otherwise. The term "electrically connected" and its derivatives encompasses both DC (direct-current) and AC (alternating current) connections, unless explicitly stated otherwise. The term "polarization channel" is used herein to refer to parts of an optical transmission system, such as e.g. a dual-polarization (DP) optical transmitter or a DP optical receiver, that operates predominantly on a selected polarization component of a light signal. Different polarization components of a light signal may also be referred to as polarization tributaries, e.g. with reference to a system where they may be separately processed. The terms "polarization channel gain" and "polarization gain" are used herein interchangeably to refer to a scaling factor relating the optical intensity of the selected polarization component at an input of the polarization channel to an output of the polarization channel. The term "polarization gain imbalance" is used herein to refer to a situation when two polarization channels of a DP optical system, e.g. a DP optical transmitter or a DP optical receiver, has different polarization channel gains.

Furthermore, the following abbreviations and acronyms may be used in the present document:.

Embodiments described below relate to an apparatus, and a corresponding method, for distributed optical sensing of disturbances along an optical fiber, such as but not exclusively along an optical fiber link of an optical communication system. The apparatus and method employ a MIMO sensing technique, in which two polarizations of probe light are used at both the transmitter and the receiver, and are adopted for polarization gain equalization and/or digital compensation of dual-polarization linear signal distortions in the apparatus.

An aspect of the present disclosure provides an apparatus comprising: a digital source of test signals; a coherent optical transmitter (COT) to transmit a light signal carrying different portions of the test signals on orthogonal polarizations thereof; a coherent optical receiver (COR) capable of separately measuring different polarization components of light received therein and to output signals indicative thereof; an optical switch operable to selectively optically connect the COT and the COR to an end of an optical fiber link in a first configuration of the optical switch and to optically back-to-back connect the COT and the COR bypassing the optical fiber link in a second configuration of the optical switch; and an electrical processor connected to receive the signals from the COT and configured estimate a gain imbalance between a first and a second of the orthogonal polarizations in at least one of the COT and the COR based on the signals received from the COR in the second configuration, and to measure a portion of the light signal backscattered by the optical fiber link in the first configuration.

In some implementations at least one of the COR and the COT may comprise variable gain optical amplifiers (VGAs). In some of such implementations, the apparatus may further comprise a control circuit configured to tune the VGAs to a tuned state in which the gain imbalance is at least reduced. In some of those implementations, the apparatus may be configured to establish, having the switch in the second configuration and the VGAs in the tuned state, a back-to-back communication channel from the digital source to the processor, and the processor is configured to estimate and store a first dual-polarization (DP) response function for the back-to-back communication channel. The processor may be configured to estimate a DP optical backscattering response for the optical fiber link using the stored first response function, based on DP signals received from the COR when the apparatus operates in a fiber monitoring mode wherein the switch is in the second configuration and the VGAs are in the tuned state.

In some implementations the processor may be configured to modify the test signals prior to transmitting to perform at least one of: digitally pre-compensate for the gain imbalance in the COT, and to digitally pre-compensate a back-to-back channel response.

In some implementations the processor may be configured to perform at least one of: modifying the test signals prior to transmitting to digitally pre-compensate for the gain imbalance in the COT, or modifying the signals from the COR to post-compensate for the gain imbalance at the COR.

In any of the above implementations, the apparatus may be configured to estimate, based on the signals from the COR in the first and second configurations, a first set of 2x2 Jones channel matrices for the back-to-back communication channel, and a second set of 2x2 Jones channel matrices for back-scattering in the optical fiber link.

In any of the above implementations, the test signals may comprise two complementary data sequences, or two pairs of complementary data sequences, for transmitting over respective ones of the orthogonal polarization components, and the processor may be configured to correlate the signals received from the COR with the pairs of complementary data sequences.

In any of the above implementations, the apparatus may include a coherent light source optically coupled to the COT for providing coherent light for modulating the data sequences thereon and to the COR for providing a local oscillator signal.

A related aspect of the present disclosure provides a method comprising: operating a coherent optical transmitter (COT) and a coherent optical receiver (COR) in a first configuration, the COT and the COR being optically connected to a same end of an optical fiber link in the first configuration; switching to operate the COT and COR in a second configuration, the COR being optically back-to-back connected to the COT in the second configuration; processing signals from the COR to estimate a polarization gain imbalance in at least one of the COT and the COR in the second configuration; and processing signals from the COR to measure a portion of the light signal backscattered by the optical fiber link in the first configuration; wherein the COT transmits a light signal carrying different test signals on orthogonal polarizations thereof in each of the configurations; and wherein the COR separately measures different polarization components of received light and outputs signals indicative thereof in both configurations.

In some implementations of the method, at least one of the COR and the COT comprises a plurality of variable gain amplifiers (VGAs), and the method comprises tuning at least one of the VGAs to a tuned state to at least reduce the polarization gain imbalance. In some of such implementations, the method may further comprise processing the signals received from the COR in the back-to-back configuration with the VGAs in the tuned state, to at least estimate a back-to-back dual-polarization (DP) response function of the apparatus. In some of such implementations, the method may comprise estimating, for the first configuration with the VGAs in the tuned state, a DP channel response of the optical fiber link using the stored back-to-back DP response function.

In any of the above implementations of the method, the test signals may comprise two complementary data sequences, or two orthogonal pairs of complementary data sequences, and the method may comprise modulating said data sequences, or said pairs, over corresponding ones of the two orthogonal polarizations.

In any of the above implementations, the method may comprising computing a set of Jones matrices based on the signals received from the COT.

Referring now to <FIG>, it illustrates a schematic block diagram of an example fiber sensing apparatus <NUM> ("apparatus <NUM>") for monitoring distributed back-reflections in an optical fiber <NUM>. In some embodiments, the optical fiber <NUM> may be, for example, an optical fiber link of a deployed optical fiber communication system, and apparatus <NUM> may be configured for monitoring optical fiber disturbances along the link by sensing changes in the Raleigh back-scattering within the fiber. In some embodiments, the optical fiber <NUM> may be, for example, a sensing element of a distributed optical sensor, in which case the optical fiber <NUM> may sometimes include a sequence of spaced apart fiber Bragg gratings (FBGs). The term "backscattering" as used herein encompassed back reflections from such FBGs.

Apparatus <NUM> includes a coherent optical transmitter (COT) <NUM>, a coherent optical receiver (COR) <NUM>, a test signal generator (TSG) <NUM>, and a signal processor <NUM>. In some embodiments, the TSG <NUM> and the processor <NUM> may be embodied using a shared digital signal processor. Apparatus <NUM> may include a reconfigurable optical connector (ROC) <NUM>, hereinafter also referred to as an optical switch. The COT <NUM> and the COR <NUM> are configured for dual-polarization transmission and reception, respectively, of a light signal <NUM>, which has a suitably long coherence length. In operation TSG <NUM> may generate test signals <NUM>, different portions of which are separately modulated by the COT <NUM> onto different tributaries of the light signal <NUM>, indicated in <FIG> as "X" and "Y". These X and Y tributaries may correspond to two different, typically substantially orthogonal, polarizations of the light signal <NUM>. In an example embodiment, the X and Y polarizations may correspond to linearly-polarized components of the light signal <NUM>, with their respective polarization axes aligned substantially along e.g. an x-axis and a y-axis of a Cartesian coordinate system. Embodiments in which the X and Y polarizations correspond to e.g. two substantially circular light polarizations, right-hand and left-hand, are also within the scope of the present disclosure. Here "substantially" may mean within performance tolerances of polarization-selective components used in the apparatus.

The ROC <NUM> is switchable between two configurations, to selectively optically connect the COT120 and the COR <NUM> to an end <NUM> of an optical fiber link in a first configuration of the ROC, and to optically back-to-back connect the COT <NUM> and the COR <NUM> in a second configuration of the ROC, as schematically illustrated by a curved arrow <NUM>. When the ROC is in the first configuration, apparatus <NUM> operates in a fiber sensing mode. When the ROC is in the second configuration, apparatus <NUM> operates in a self-calibration mode.

In the fiber sensing mode, the light signal <NUM> generated by the COT <NUM> is launched into the optical fiber <NUM>, and the COR <NUM> receives back-scattered light <NUM>, which is a portion of the coherent optical signal <NUM> reflected back within the optical fiber <NUM>. The in-fiber reflections may be e.g. due to the Raleigh back-scattering within the optical fiber <NUM>, or due to the presence of FBGs in the optical fiber in some embodiments, or a combination thereof. The COR <NUM> performs dual-polarization (DP) coherent reception of the back-scattered light <NUM> to separately measure signals in two different polarizations of the received light. Outputs electrical signals <NUM> of the COT comprise the test signals <NUM> transmitted by the COT <NUM> over the X and Y polarizations, which are modified by the propagation in the optical fiber <NUM>, and, in part, by propagation within apparatus <NUM>. The modifications of the test signals <NUM> carry information about perturbations in the optical fiber, the information being encoded e.g. in the optical phase and/or polarization state of the received back-scattered light <NUM>. The processor <NUM> is configured to process, in the fiber-sensing mode of operation, the received signals <NUM> to monitor changes in the back-scattered light originating at different locations along the optical fiber to detect fiber disturbing events.

In the self-calibration mode, the outputs electrical signals <NUM> of the COT <NUM> carry information about signal distortions and imbalances within apparatus <NUM>, e.g. in the COT <NUM> and the COR <NUM>, which may affect the performance of the apparatus in the fiber sensing mode. The processor <NUM> operates in this mode to evaluate the signal distortions within apparatus <NUM>, which may include estimating gain imbalances between polarization channels within the apparatus, and/or estimating DP linear signal distortions within the apparatus.

One source of distortions that may negatively affect fiber sensing performance is so-called polarization fading. When an optical fiber is probed by polarized light, the sensing sensitivity of the apparatus <NUM> may drop due to polarization transformations in the optical fiber, which may vary in time. The use of polarization diversity, i.e. two different light polarizations, at both the transmitter (COT <NUM>) and the receiver (COR <NUM>) to sense changes in the optical fiber <NUM> ("MIMO sensing") allows to eliminate, at least in theory, deleterious effects of polarization fading, and to increase the sensing sensitivity, that is the ability to sense mechanical or other environmental fiber events of lower energy thanks to a stronger received signal or a lower noise floor; see e.g. <NPL>.

The inventors of the present patent application have discovered that the noise floor observed experimentally with DP MIMO sensing may not be as low as theoretically predicted. The sensing apparatus comprises a mixture of optical, electro-optical, and electrical devices both at the transmitter and the receiver parts, which may be a source of sensing-affecting signal distortions. The test signals <NUM> transmitted over two different polarizations propagate through different parts of the apparatus, i.e. different "polarization channels", and may be differently distorted. One significant source of the distortions may be a gain imbalance between the polarization channels at the COR and/or the COT; the presence of such polarization gain imbalance may significantly complicate achieving fiber sensing that is unaffected by polarization fading.

Accordingly, apparatus <NUM> in the calibration mode of operation may be configured, at least, to estimate the polarization gain imbalance within the apparatus itself, and in some embodiments at least partially compensated for them. In this mode, the COR <NUM> may operate as described above to transmit the test signals <NUM>, or some variations thereof, over the X- and Y- polarizations of the light signal <NUM>, and a portion of the light signal <NUM> is coupled into the COR <NUM> bypassing the optical fiber <NUM> for performing back-to-back measurements.

In some embodiments, when apparatus <NUM> operates in the calibration mode, the processor <NUM> is configured to estimate a polarization gain imbalance in at least one of the COT <NUM> and the COR <NUM>, i.e. a gain imbalance experiencing by signals transmitted over the two polarizations, or two polarization tributaries, that are used in at least one of the COT <NUM> and the COR <NUM>. In some embodiments, the processor <NUM> may be configured to estimate, based on the signals <NUM> received from the COR <NUM> in the back-to-back configuration, a polarization gain imbalance in each of the COT <NUM> and the COR <NUM>.

The switching between the fiber sensing mode and the calibration mode, e.g. in response from a signal from a controller, may include switching the ROC <NUM> between the first and second configurations, and directing the processor <NUM> to perform either the fiber-sensing MIMO processing of the received signals <NUM> when the ROC <NUM> in the first state, or the self-calibration MIMO processing of the signals <NUM> when the ROC <NUM> in the second state. Example MIMO processing of the signals <NUM> in these two mode of operations by a digital processor, such as e.g. processor <NUM>, is described below with reference to <FIG> and <FIG>.

<FIG> illustrates an example optical fiber sensing apparatus <NUM> ("apparatus <NUM>") according to an embodiment. Apparatus <NUM> may be an embodiment of apparatus <NUM> and is switchable between a fiber sensing mode and a self-calibration mode, e.g. in response to a signal from a controller <NUM>. Apparatus <NUM> includes a test sequence generator (TSG) <NUM>, a COT <NUM> comprising a DP electro-optic (EO) converter <NUM>, and a COR <NUM> comprising a DP opto-electric (OE) converter <NUM>. The COT <NUM> and the COR <NUM> may be embodiments of the COT <NUM> and the COR <NUM>, respectively, described above with reference to <FIG>.

The COT <NUM> and the COR <NUM> may be switchably connected by a ROC <NUM> either back-to-back for apparatus self-calibration, or to an end <NUM> of an optical fiber <NUM> for sensing. The ROC <NUM>, which is an example embodiment of ROC <NUM>, includes an optical coupler or tap <NUM>, an optical circulator <NUM>, and a 2x1 optical switch <NUM>. The optical circulator <NUM> connects a fiber end port <NUM> of an optical fiber <NUM> being monitored to the COT <NUM>, and directs back-scattered light from the optical fiber <NUM> to an optical switch <NUM>. In another embodiment, the optical 2x1 switch <NUM> may be disposed to connect the second port of the circulator <NUM> to the fiber end <NUM>. The optical 2x1 switch <NUM> is operable to switch between a first state and a second state. As illustrated, in the first state the optical 2x1 switch <NUM> connects the COR <NUM> to the fiber end <NUM> via the circulator <NUM> to direct the back-scattered light into the COR <NUM>. In the second state the optical 2x1 switch <NUM> connects the COR <NUM> back-to-back to the output of the COT <NUM>, bypassing the circulator <NUM> and the fiber end <NUM>. Thus the ROC <NUM> is configured to switch the apparatus <NUM> between the fiber sensing mode and the self-calibration mode.

The TSG <NUM> is an embodiment of the TSG <NUM>, and is configured to generate two distinct test signals 211X and 211Y, or two distinct sequences of test signals, to be transmitted by the COT <NUM> over respective polarizations tributaries of a light signal <NUM>, as described above with reference to <FIG> and COT <NUM>. The COT <NUM> includes a two-channel modulation signal generator <NUM> for converting the test signals 211X and 211Y to modulation signals for the X-polarization and the Y-polarization channels, respectively. The two-channel modulation signal generator <NUM> may be followed by variable gain amplifiers (VGAs) <NUM>, which may be a part of a modulation driver, and the DP EO converter <NUM> for converting the modulation signals into a coherent light signal <NUM> carrying the test signals 211X and 211Y over, respectively, the X-polarization and Y-polarization components of the coherent light signal <NUM>. The VGAs <NUM> may be configured for amplifying the modulation signals for the X and Y polarizations with separately tunable gains. The COT <NUM> and the COR <NUM> may be configured to use a variety of modulation formats, including but not limited to BPSK, QPSK, M-QAM, and M-PAM.

The DP EO converter <NUM> is configured to separately modulate two light portions of coherent light received from a coherent light source <NUM>. In some embodiments, the DP EO converter <NUM> may be followed by an optical amplifier, such as e.g. an erbium-doped fiber amplifier (EDFA). In an embodiment, the coherent light source <NUM> is configured to emit light having a large coherence length, e.g. at least equal to, or preferably at least twice, a length of the optical fiber <NUM> to be tested. The coherent light source <NUM> may further provide reference light, also referred to as local oscillator (LO) light, to the DP OE <NUM> of the COR <NUM>, for homodyne detection of modulation in two polarization channels of the COR <NUM>. The DP OE converter <NUM> is configured to separately detect or measure signals modulating two different polarizations of a received light signal, and to convert the two detected signals into electrical signals 233X and 233Y, each carrying signals detected for a corresponding one of the two different polarizations of the received light ("polarization channels"). Digitized versions of the electrical signals 233X and 233Y are provided to a processor <NUM> for the fiber-sensing or apparatus self-calibration processing. In some embodiments the COR <NUM> may further include VGAs <NUM> for amplifying, with separately tunable gains, the electrical signals 233X and 233Y in the two polarization channels prior to the processing by the processor <NUM>.

The processor <NUM> may be an embodiment of the processor <NUM>, and is configured for digital processing of the received signals 233X, 233Y to perform an estimation of a transmission channel connecting the COT <NUM> to the COR <NUM>, e.g. as described above with reference to the processor <NUM>, or as further described below in this document for example embodiments.

When apparatus <NUM> operates in the self-calibrating mode, the processor <NUM> may process the received DP signal 233X and 233Y to estimate an imbalance between gains experiencing by signals in the two polarization channels ("polarization gain imbalance") for at least one of the COT <NUM> and the COR <NUM>. In some embodiments, VGA gains at the COT <NUM> and/or the COR <NUM> may be tuned at the calibration stage to at least partially compensate for the estimated polarization gain imbalance. In some embodiments, the controller <NUM> may be operatively coupled to the processor <NUM> and to the VGAs <NUM> and/or <NUM> to tune at least some of the VGAs <NUM> and/or <NUM> to counteract the estimated gain imbalance. In some embodiments, the polarization gain imbalance estimation may be used in the fiber sensing mode of operation for digital pre-compensation of the test signals prior to the transmission, and/or for digital post-compensation of the received signals. In some embodiments, the analog gain tuning at the calibration stage may be combined with the digital pre- or post-compensation at the fiber sensing stage. In some embodiments, the processor <NUM> may use signals received at the calibration stage to estimate and store a back-to-back channel transfer function of the apparatus, and to use the estimated back-to-back channel transfer function in the sensing mode, e.g. to compensate for linear signal deterioration, such as e.g. inter-symbol interference, in the electrical and electro-optical components of the COT <NUM> and the COR <NUM>. In some embodiments, the controller <NUM> may also generate control signals to control the 2x1 optical switch <NUM> for performing fiber sensing measurements or the apparatus self-calibration measurements.

<FIG> schematically illustrate an example embodiment of the COT <NUM>, which is referred to as the COT 300A. In this embodiment, the DP EO converter <NUM> of COT <NUM> is embodied using two optical modulators 350X and 350Y optically connected in parallel between a polarization splitter <NUM> and a polarization combiner <NUM>. In the illustrated embodiment, the optical modulators 350X and 350Y are each embodied as an optical IQ modulator, e.g. a nested Mach-Zehnder modulator (MZM), configured for QPSK, M-QAM, or M-PAM modulation as known in the art. In other embodiments, the optical modulators 350X and 350Y may each be embodied with an MZM configured, e.g. for BPSK modulation. A digital test sequence generator <NUM>, which may be an embodiment of TSG <NUM>, is configured to generate test signals 311X and 311Y in the form of digital test data sequences, for transmitting over the X- and Y-polarizations, respectively. The test signals 311X and 311Y are converted to analog domain by a DAC <NUM>. A modulation signal generator <NUM> further converts each of the test signals 311X and 311Y into in-phase (I) and quadrature (Q) modulation signals, which are then amplified by VGAs <NUM>. The gains of the VGAs <NUM> may be tuned separately for the X- and Y-polarization channels responsive to a control signal, e.g. from the controller <NUM>, to at least partially compensate for the polarization gain imbalance as estimated from the back-to-back measurements.

<FIG> schematically illustrate a COT 300B, which may be an embodiment of the COT <NUM> and is a modification of the COT 300A configured for digital pre-compensation of a polarization gain imbalance, e.g. as obtained using back-to-back measurements by the processor <NUM> (<FIG>). In this embodiment, test signals 311X, 311Y may be first digitally pre-processed, in a fiber sensing mode of operation, using a pre-compensation processor <NUM>, so as to at least partially pre-compensate for a polarization gain imbalance estimated from back-to-back measurements at the calibration stage. The pre-compensated digital signals are converted to analog domain by the DAC <NUM>, and passed to the modulation signal generator <NUM> for converting to the I and Q modulating signals in each of the two polarization channels.

<FIG> illustrates an example embodiment of the COR <NUM>, which is referred to below as the COR <NUM>. A DP OE converter <NUM>, which may be an embodiment of the DP OE converter <NUM> of COR <NUM>, includes a DP optical mixer <NUM> coupled to balanced photodetectors (BPD) <NUM>. The DP optical mixer <NUM> is configured to separately mix two different polarization complements, e.g. "X" and "Y", of a received optical signal <NUM> with corresponding polarization components of LO light <NUM>. The LO light <NUM> and the received optical signal <NUM> may originated from a same source of coherent light, e.g. the optical source <NUM>, and may retain a sufficient degree of mutual coherency for phase-sensitive measurements. The DP coherent optical mixer <NUM> may include, e.g. two <NUM>° optical hybrids, one per polarization channel, connected at their inputs to corresponding outputs of two optical polarization splitters (not shown). Output optical signals of the DP coherent optical mixer <NUM> in each polarization channel, denoted as 422X and 422Y, are separately converted to electrical signals 433X and 433Y by the BPDs <NUM>. The electrical signals 433X and 433Y may then be amplified separately in each of the two polarization channel, e.g. by amplifiers <NUM>, digitized by an ADC <NUM>, and passed to a signal processor, e.g. the processor <NUM> or <NUM> described above. In some embodiments the amplifiers <NUM> may be VGAs connected to have their gains adjustable by a controller, e.g. the controller <NUM> of <FIG>, independently for each polarization channel.

The operation of a fiber sensing apparatus of the present disclosure, such as apparatus <NUM> or apparatus <NUM>, in the fiber sensing mode and the self-calibration mode is further described below with reference to <FIG> for example embodiments.

In an embodiment, a fiber sensing apparatus, such as the apparatus <NUM> or <NUM> described above, may implement a method that includes the following operations: switchably operating a COT and a co-located COR in a first configuration and in a second configuration, wherein the COT and the COR are optically connected either to an end of an optical fiber link in the first configuration, or back-to-back to each other in the second configuration; the COT transmitting a light signal carrying different test signals on orthogonal polarizations thereof; the COR separately measuring different polarization components of received light and outputting signals indicative thereof in both the first and second configurations; processing the signals received from the COR in the second configuration to estimate gain imbalance in at least one of the COT and the COR; processing the signals received from the COR in the first configuration to measure a portion of the light signal backscattered by the optical fiber link.

<FIG> illustrates a method <NUM> for operating a fiber sensing apparatus, such as e.g. the apparatus <NUM> or <NUM>, according to an embodiment. The method <NUM> includes: (<NUM>) a coherent optical transmitter; e.g. COT <NUM>, <NUM>, 300A, or 300B, transmitting a light signal carrying different test signals on orthogonal polarizations of the light signal; (<NUM>) connecting the coherent optical transmitter to the coherent optical receiver in a back-to-back configuration, (<NUM>) estimating, and in some embodiments at least partially compensating, polarization gain imbalance in at least one of the coherent optical transmitter and the coherent optical receiver; (<NUM>) connecting the coherent optical transmitter and the coherent optical receiver to a same end of an optical fiber to be tested; (<NUM>) the coherent optical receiver separately measuring different polarization components of received light to monitor fiber events; and (<NUM>) processing signals received from the coherent optical receiver to measure a portion of the light signal backscattered by the optical fiber in the fiber-sensing configuration to detect fiber-affecting events. The processing may include, e.g. detecting variations of at least one of the phase and the amplitude of the back-scattered radiation originating from a particular section of the optical fiber.

For an example embodiment, the estimation (step <NUM>) of polarization gain imbalances in the coherent optical transmitter and/or the coherent optical receiver of the fiber sensing apparatus, e.g. the apparatus <NUM> or <NUM>, performed by an associated digital processor, e.g. the processor <NUM> or <NUM>, may be described using a Jones matrix formalism and the following approximate mathematics. A Jones matrix is a 2x2 matrix that describes conversion between an input and an output polarization states of an optical system, when the input and an output polarization states are each described by a two-element Jones vector (Ex, Ey)T; here "T" indicates a transpose operation, and Ex and Ey represent amplitudes of two orthogonal polarization components of an optical field, e.g. the X-polarization and the Y-polarization components of the optical field. A transfer function of a dual-polarization communication channel in the back-to-back configuration, from a source of test signals, e.g. <NUM>, <NUM>, or <NUM>, to a receiver-coupled processor, e.g. <NUM> or <NUM>, may be approximately described using a 2x2 matrix Hb<NUM>b defined by the following Equation (<NUM>): <MAT>.

Here U is an input Jones vector which elements are the test signals at the input to the COT, e.g. 211X and 211Y, or 311X and <NUM>1Y, and W is a two-element vector which elements are signals in the X and Y polarization channels, e.g. 233X and 233Y, or 433X and 433Y, that a corresponding COR provides to a coupled processor, e.g. the processor <NUM> or <NUM>. In some approximation, e.g. in embodiments where non-orthogonality of the X and Y polarizations at the COT and the COR is negligible, and the polarization-dependent (optical) loss (PDL) of the back-to-back optical connection between the COT and the COR is insignificant, the DP back-to-back (B2B) channel transfer matrix Hb<NUM>b satisfies the following equation (<NUM>): <MAT>.

Elements hxx, hxy, hyx, hyy of the DP B2B channel transfer matrix Hb<NUM>b are complex numbers relating the two polarization components, Erx and Ery, of the optical field detected at the COR to the corresponding polarization components Etx and Ety of the optical field as generated at the corresponding COT. The parameters a and b describe relative amplification of the X-polarization and Y-polarizations signals at the COT, c and d describe relative amplitude amplification of the X-polarization and Y-polarizations signals at the COR. The amplification parameters a, b, c and d may be complex-valued, e.g. when a quadrature IQ modulation format is used in the optical transmission. The absolute values of the parameters a and b, |a| and |b|, may be referred to as relative polarization gains, or polarization gain coefficients, of the COT, and the absolute values of the parameters c and d, |c| and |d|, may be referred to as the relative polarization gains, or polarization gain coefficients, of the COR. The COT-to-COR optical connection in the back-to-back configuration may be described by a rotation matrix Hopt: <MAT>.

Matrix Hopt describes polarization rotation that may occur in the back-to-back optical connection from the COR to the COT, e.g. in a connecting optical waveguide such as a length of an optical fiber, and/or an optical switch. In the absence of PDL, Hopt is a unitary matrix with |e|<NUM> + |f|<NUM> = <NUM>. Hence, the absolute values, i.e. modules, of e and f may be expressed as a function of a rotation angle θ , with |e| = | cos θ | and|f| = | sin θ |. In embodiments where the test signals have a relatively small bandwidth, e.g. less than <NUM>, or about <NUM> or less in some embodiments, frequency selectivity of the transmission channel may be neglected, and the channel matrix Hb<NUM>b may be single-tap.

From equations (<NUM>) - (<NUM>), the following system of equations may be obtained: <MAT> where parameters A, B, C, and D denote squares of absolute values of the corresponding polarization gain coefficients, and represent relative power gains for the respective polarization channels at the COT and the COR: <MAT>.

The determinant of the matrix Hb<NUM>b provides an estimate of the product of the four gain parameters A, B, C, D: <MAT>.

In an embodiment, a processor of the fiber-sensing apparatus, e.g. the processor <NUM> or <NUM>, may be configured to estimate elements hi,j of the back-to-back channel response matrix Hb<NUM>b based on signals measured by the associated COR, e.g. <NUM> or <NUM>, in two polarization channels thereof. The processor may further be configured to numerically solve the non-linear system of equations (<NUM>) and (<NUM>) to compute relative gains for the two polarization for at least one of the COT, i.e. |a| and |b|, and for the COR, i.e. |c| and |d|. One skilled in the art would be able to select a suitable computer-executable algorithm to solve the system of non-linear equations (<NUM>) and (<NUM>); by way of a non-limiting example, methods based on non-linear least squares algorithms, e.g. a trust-region or a Levenberg-Marquardt method, maybe used. The processor may also be configured to estimate the strength of the polarization cross-talk in the back-to-back configuration, as defined by parameters |e| and |f| or, equivalently, the polarization rotation angle θ.

In one embodiment the relative polarization gain coefficients for only one of the COT and the COR may be estimated, e.g. when the other of the COT and the COR are known to be suitably balanced. In one embodiment, a control circuit of the apparatus coupled to the processor, e.g. the controller <NUM> of <FIG>, may be configured to tune gains of one or more VGAs of at least one the COT and the COR, e.g. the VGAs <NUM> and/or <NUM>, or the VGAs <NUM> and/or <NUM>, to at least partially compensate for the estimated polarization gain imbalance(s). In one embodiment, the control circuit may be configured to tune the gains of at least one of the VGAs of both of the COT and the COR to at least partially compensate for the estimated polarization gain imbalances separately for the COT and the COR.

By way of example, the processor at step (<NUM>) may estimate the ratios |a| / |b| = <NUM>, |d| / |c| ≅ <NUM>, and the control circuit may decrease the gain of the X-channel VGA(s) of the COT by a corresponding proportion, e.g. by approximately <NUM>%, or increase the gain of the Y-channel VGA(s) of the COT by a corresponding proportion, e.g. by approximately <NUM>%; the control circuit may further increase the gain of the X-channel VGA(s) of the COR by a corresponding proportion, e.g. by approximately <NUM>%, or decrease the gain of the Y-channel VGA(s) of the COR by a corresponding proportion, e.g. by approximately <NUM>%.

In some embodiments, at step (<NUM>) the processor may direct the control circuit to tune at least one of the X-channel VGA(s) or the Y-channel VGAs of the COT to a tuned state wherein the polarization gain imbalance at the COT, e.g. estimated as <MAT> or <MAT>, is at least reduced. The processor may further direct the control circuit to tune at least one of the X-channel VGA(s) or the Y-channel VGAs of the COR to a tuned state wherein the polarization gain imbalance at the COR, e.g. estimated as <MAT> or <MAT>, is at least reduced. In some embodiments, the processor may repeat the process of polarization gain imbalance estimation followed by the VGA tuning until the estimated values of the polarization gain imbalances at both the COT and the COR are below a target threshold or thresholds.

In an example embodiment, the processor <NUM> or <NUM> may be configured to estimate the elements hxx, hxy, hyx, hyy of a Jones matrix of a transmission channel, e.g. the back-to-back channel response matrix Hb<NUM>b, based on a knowledge of the test signals <NUM> generated by the corresponding TSG, e.g. <NUM>, <NUM>, or <NUM>, in the back-to-back mode of operation. In some embodiments, the processor <NUM> or <NUM> may estimate the elements hxx, hxy, hyx, hyy based on a comparison between the signals detected by the COR for two different light polarizations, e.g. pairs of signals 233X and 233Y or 433X and 433Y, and the test signals <NUM> or <NUM>, respectively, transmitted by the corresponding COT over the two polarizations. In some embodiments, estimating the elements hxx, hxy, hyx, hyy may include correlating the signals detected by the COR for two different light polarizations and the test signals transmitted by the corresponding COT over the two polarizations.

Once the polarization gains at the COT and/or the COT are estimated, and in an example embodiment at least partially equalized, the polarization sensing apparatus, e.g. <NUM> or <NUM>, may be switched to the fiber sensing mode, and steps or operations <NUM> and <NUM> are performed. Operations at step <NUM> may include e.g. switching the 2x1 optical switch <NUM> to the first configuration in which the COT and the COR are connected to an end of the optical fiber being sensed.

In some embodiments, the estimated polarization gain imbalances may be digitally pre-compensated at the COT and/or post-compensated at the COR without adjusting amplifier gains in the analog portions of the respective circuits. In some embodiments, the processor may be configured, while the apparatus in the back-to-back calibration mode, to repeat the measurements of the polarization gain imbalance(s) followed by the VGA tuning, and/or adjusting parameters of the digital pre- or post-compensation of the transmitted or received signals in other embodiments, until the estimated polarization gain imbalances at the COR and the COT are within desired tolerances.

Referring to <FIG>, in an embodiment the step or operation <NUM> may include processing signals measured by the COR in two polarization channels, e.g. signals 233X, 233Y or 433X, 433Y, to compute a series of Jones matrices Hn, n = <NUM>,. , N; the processing may include, e.g. correlating the measured signals with the original test data signals, e.g. 211X, 211Y or 311X, 311Y, provided to the COT. These Jones matrices characterize the back-scattering responses of consecutive sections <NUM><NUM>, <NUM><NUM>,. , <NUM>N of an optical fiber <NUM> under test. In <FIG>, the optical fiber <NUM> may represent e.g. a length of the optical fiber <NUM> of <FIG> or a length of the optical fiber <NUM> of <FIG>. Non-uniformities in the optical fiber <NUM> that induce the back-scattering of light propagating in the fiber are symbolically indicated by dots <NUM>.

The length ΔL of each fiber section <NUM>i defines the spatial resolution of the sensing, and is a function of the test signal symbol rate and of the oversampling factor at the COR. In some embodiments, the processing may include generating four polarization transfer functions Hxx, Hxy, Hyx, and Hyy, each containing corresponding elements of the N. Jones matrices Hn, e.g. in the form of four vectors: <MAT> <MAT> <MAT> <MAT>.

These four vectors comprise a dual-polarization back-scattering response along the optical fiber, and may be used in some embodiments for identifying approximate locations of fiber affecting events. In some embodiments, a phase ϕ for the back-scatters light may be estimated per segment <NUM>, e.g. from a phase of the determinant D(n) of the Jones matrix of the segment: <MAT> <MAT>.

The phase ϕ may be periodically estimated to capture its evolution for each fiber segment <NUM> to obtain a spatio-temporal map of fiber-affecting events.

In some embodiments, apparatus <NUM> or <NUM> may further be configured to perform DP channel equalization in the fiber sensing mode, e.g. to at least partially compensate for linear signal deterioration in the COT and the COR at each polarization channel, e.g. pulse spreading and inter-symbol interference (ISI) associated therewith.

<FIG> illustrates a flowchart of a method <NUM> which may be implemented by apparatus <NUM> or <NUM> according to an example embodiment. Method <NUM> may be a version of method <NUM> described above, which includes an additional step or operation <NUM> in the calibration configuration, and in which the processing of measurements performed in the fiber-sensing configuration (step <NUM> of method <NUM>) includes signal processing steps <NUM> and <NUM>. The step or operation <NUM> includes estimating a DP B2B channel response <NUM>, and saving the estimated DP B2B response <NUM> in a processor-readable memory. The estimated DP B2B response <NUM> accounts for possible signal deterioration in the fiber-sensing apparatus itself, e.g. due to hardware limitations at the COT and the COR. The step or operation <NUM> includes DP processing of back-scattered light from an optical fiber under test to estimate a DP end-to-end channel response <NUM> in the fiber-sensing mode (step <NUM>). The step or operation <NUM> includes estimating a DP channel response <NUM> for back-scattering in the optical fiber, based on the a DP end-to-end channel response <NUM> measured in the fiber-sensing mode, and the DP B2B channel response <NUM> saved at <NUM>.

Operations performed by the apparatus <NUM> or <NUM> at step <NUM> may be similar to those performed in the fiber sensing mode at step <NUM>, e.g. as described above with reference to <FIG>. These operations may include periodically transmitting, by the COT, synchronized test sequences of digital symbols over two different polarizations, and estimating, by processor <NUM> or <NUM> for the back-to-back channel, a sequence of Jones matrices Hb2b, or elements thereof. The processor may then select one or more of the Jones matrices Hb2b for estimating the polarization gain imbalance, e.g. as described above with reference to equations (<NUM>)-(<NUM>).

Referring to apparatus <NUM> of <FIG> by way of example, the processor <NUM> may, at step <NUM> and/or <NUM>, process signals 233X and 233Y received from the COR <NUM> in the back-to-back configuration to estimate a subset {Hb2b} of P Jones matrices Hb2b(n), e.g. with n = <NUM>,. , P, where P may be smaller than N. The subset {Hb2b} carries time-dependence information for a DP transfer function of the back-to-back channel. In an embodiment, the subset {Hb2b} may be estimated e.g. using a correlation processing, e.g. as described below with reference to equations (<NUM>)-(<NUM>) or (<NUM>)-(<NUM>) for an embodiment.

In some embodiments, the processor <NUM> or <NUM> may estimate, at step <NUM> or <NUM>, an intensity transfer function I(n) <NUM> (<FIG>) for the B2B channel response. The intensity I(n) for each time interval tn may be typically estimated by computing an absolute value of the determinant D of a Jones matrix, I(n)=|D(n)|. One of the back-to-back Jones matrices Hb2b(n) with a suitably large intensity, e.g. at or near the maximum of the intensity transfer function I(n) <NUM>, may be chosen for estimating the polarization gain imbalance, e.g. as described above with reference to equations (<NUM>)-(<NUM>).

In an embodiment, the processing at step <NUM> may include performing a new channel estimation for the apparatus in the back-to-back configuration, now with the equalized gains, to obtain a new subset {Hb2b} of Jones matrices HB2B(n). The new subset {Hb2b} provides an estimate of a gain-equalized DP channel response of the apparatus in the back-to-back configuration. The new subset {Bb2b}, or information indicative thereof, may be stored at step <NUM> as the estimated B2B DP channel response <NUM>. In an embodiment, the processor <NUM> may store four vectors HxxB2B, HxyB2B, HyxB2B, and HyyB2B, each containing corresponding elements of Jones matrices HnB2B of the second subset {Hb2b}: <MAT> <MAT> <MAT> <MAT>.

The vectors HxxB2B, HxyB2B, HyxB2B, and HyyB2B describe the DP response of the back-to-back channel as a function of discrete time.

In some embodiments, e.g. when the gain imbalances on the apparatus are found to be within pre-defined tolerances, the step of gain equalization may be omitted.

Once the apparatus is switched to the fiber sensing configuration (step <NUM>), at step <NUM> the processor <NUM> or <NUM> may periodically generate measurements defining a set {H(n)}N of N Jones matrices H(n), n=<NUM>,. , N, as described above with reference to <FIG>, based on the signals received from the COR <NUM> or <NUM>. This set {H(n)}N of N Jones matrices provides an estimate <NUM> of an end-to-end DP channel response in the fiber-sensing mode, which comprises a DP backscattering response of the optical fiber under test, and a DP channel response of the fiber-sensing apparatus itself. At step <NUM>, the DP backscattering response of the optical fiber under test may be estimated based on the stored B2B DP channels response <NUM>.

In an embodiment, the processing at steps <NUM> and <NUM> may include generating the four vectors Hxx, Hyy, Hxy, and Hyx of N complex values as described above with reference to equations (<NUM>)-(<NUM>), one vector per Jones matrix element, followed by a B2B response deconvolution to obtain an estimate <NUM> of the DP backscattering response of the optical fiber under test. The deconvolution process may include four independent deconvolutions: each of the four N-long. vectors Hxx, Hyy, Hxy, and Hyx is deconvolved by a corresponding P-long B2B vector HxxB2B, HyyB2B, HxyB2B, and HyxB2B stored in memory. The processor <NUM> or <NUM> may perform the deconvolutions in the time domain or in the frequency domain. This process produces a new set of four equalized backscattered channel estimations, e.g. in the form of four N-long vectors Ĥxx, Ĥyy, Ĥxy, and Ĥyx or equalized response functions, which provide an estimate of the DP backscattering response of the optical fiber wherein the impact of the apparatus response is removed or at least lessened. In some embodiments, elements of the four equalized response functions Ĥxx, Ĥyy, Ĥxy, and Ĥyx may be used to estimate the phase response of the optical fiber, e.g. based on equations (<NUM>) and (<NUM>).

A fiber-sensing apparatus of the present disclosure, e.g. apparatus <NUM> or apparatus <NUM>, may estimate dual-polarization response functions of an optical communication channel, e.g. an optical fiber, using polarization-multiplexed transmission of sequences of test signals followed by a detection of the test signals in portion of the coherent light signal provided to a coherent optical receiver with polarization diversity, e.g. due to the back-scattering in the optical fiber, or back-to-back. In an example embodiment, the test signals described above with reference to <FIG>, e.g. the test signals <NUM>, and test signal pairs 211X, 211Y and 311X, 311Y, may comprise complementary data sequences, such as e.g. binary Golay sequences, transmitted over two orthogonal polarizations. A DP channel response may be extracted, e.g., by correlating these sequences with signals detected by the coherent optical receiver for two different polarizations of the back-scattered light signal. The use of complementary (Golay) data sequences for a DP optical fiber sensing is described in detail, for example, in a European Patent Application <CIT>, and in an article by <NPL>, the content of both of which are incorporated herein by reference in their entirety.

Referring by way of example to apparatus <NUM> of <FIG>, the test signals 233X and 233Y may include complementary data sequences, such as e.g. binary Golay sequences, which are transmitted by the COT <NUM> over the X- and Y-polarizations, respectively. In general, a Golay sequence G(n) contains a sequence of values, where each value is either +<NUM> or -<NUM>. Two complementary Golay sequences Ga(n) and Gb(n) exhibit the following property: <MAT> where n is a symbol counter, ⊗ is the correlation operator, and δ is the Dirac delta function.

In an embodiment, the X-polarization and the Y-polarization tributaries of the optical signal <NUM> generated by the COT <NUM> are modulated with complementary (Golay) sequences Gx(n) and Gy(n) of length N, e.g. to have polarization components that may be represented as follows: <MAT> <MAT> where Etx and Ety represent the X-polarization and the Y-polarization components of the optical signal <NUM> for perfectly balanced modulation, N, is the repetition period, k is the k-th repetition of period Nr; a common scaling factor is omitted.

Optical signal received at the COR <NUM> may then comprise the following X- and Y-polarization components: <MAT> <MAT> where Erx is the X polarization component, Ery is the Y polarization component, and hxx, hyy, hxy, and hyx are elements of a 2x2 transmission channel matrix <MAT> describing a DP transmission channel from the COT <NUM> to the COR <NUM>. Estimates of the polarization-dependent channel responses h'xx(n), h'yx(n), h'xy(n), h'yy(n) as observed at the COR <NUM> can then be computed by the processor <NUM>, e.g. in one or more of the steps <NUM>, <NUM>, <NUM> of the methods <NUM> and <NUM> described above, by correlating the electrical signals 233X and 233Y received by the processor <NUM> from the COR <NUM> in the two polarization channels, denoted Jx and Jy , with each of the complementary sequences Gx(n) and Gy(n): <MAT> <MAT> <MAT> <MAT> where Jx and Jy are the electrical signals 233X, 233Y received by the processor <NUM> from the COR <NUM> in the two polarization channels.

In an embodiment wherein the COT <NUM> implements an IQ modulation format, such as e.g. a QPSK or a QAM, the test signals 211X and 211Y may include mutually orthogonal pairs of complementary binary (Golay) sequences, GxI(n) and GxQ(n) for modulating the X-polarization and GYI(n) and GYQ(n) for modulating the Y-polarization: <MAT> <MAT> where the mutually orthogonal pairs of test sequences GxI(n), GxQ(n), and GYI(n), GYQ(n) satisfy conditions of mutual orthogonality as described e.g. in a European Patent Application <CIT>, and in an article by <NPL>.

The correlation processes employed by the processor <NUM>, e.g. in one or more of the steps <NUM>, <NUM>, <NUM> of the methods <NUM> and <NUM> described above, to determine the transmission channel responses may be, e.g. as follows: <MAT> <MAT> <MAT> <MAT>.

In an embodiment, in the fiber sensing mode the processor <NUM> may compute a series of Jones matrices Hn, n = <NUM>,. , N, e.g. using correlation processing such as that described by equations (<NUM>)-(<NUM>) or (<NUM>)-(<NUM>). In the fiber-sensing mode of operation, these Jones matrices characterize the back-scattering responses of consecutive sections <NUM><NUM>, <NUM><NUM>,. , <NUM>N of an optical fiber <NUM> under test (<FIG>). In the back-to-back mode of operation, these Jones matrices characterize the back-to-back response of the apparatus.

The example embodiments described above are not intended to be limiting, and many variations will become apparent to a skilled reader having the benefit of the present disclosure. For example, test sequences that are coded differently than described above may be used for channel estimation. Furthermore in the description above, for purposes of explanation and not limitation, specific details are set forth such as particular architectures, interfaces, techniques, etc. in order to provide a thorough understanding of the present invention. In some instances, detailed descriptions of well-known devices, circuits, and methods are omitted so as not to obscure the description of the present invention with unnecessary detail. Thus, for example, it will be appreciated by those skilled in the art that block diagrams herein can represent conceptual views of illustrative circuitry embodying the principles of the technology. All statements herein reciting principles, aspects, and embodiments of the invention, as well as specific examples thereof, are intended to encompass both structural and functional equivalents thereof.

Claim 1:
An apparatus (<NUM>, <NUM>) comprising:
a digital source of test signals (<NUM>, <NUM>);
a coherent optical transmitter (COT, <NUM>, <NUM>) to transmit a light signal carrying different portions of the test signals on orthogonal polarizations thereof;
a coherent optical receiver (COR, <NUM>, <NUM>) capable of separately measuring different polarization components of light received therein and to output signals indicative thereof;
characterized in that the apparatus (<NUM>, <NUM>) also comprises:
an optical switch (<NUM>, <NUM>) operable to selectively optically connect the COT (<NUM>, <NUM>) and the COR (<NUM>, <NUM>) to an end of an optical fiber link (<NUM>, <NUM>) in a first configuration of the optical switch (<NUM>) and to optically back-to-back connect the COT (<NUM>, <NUM>) and the COR (<NUM>, <NUM>) in a second configuration of the optical switch (<NUM>, <NUM>); and
an electrical processor (<NUM>, <NUM>) connected to receive the signals from the COR (<NUM>, <NUM>) and configured to estimate a gain imbalance between a first and a second of the orthogonal polarizations in at least one of the COT (<NUM>, <NUM>) and the COR (<NUM>, <NUM>) based on the signals received from the COR (<NUM>, <NUM>) in the second configuration, and to measure a portion of the light signal backscattered by the optical fiber link (<NUM>, <NUM>) in the first configuration.