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    • 专利摘要:
    OTDR system (200) for the analysis of defects in a transmission line in which a complex signal generated and then modulated has been injected, comprising: - means (205) for measuring the modulated complex signal propagating in the transmission line a demodulator (206) of the measured signal capable of producing a demodulated complex signal, - a complex correlator (210) configured to correlate the demodulated complex signal with a copy of the generated complex signal, to produce a first temporal reflectogram corresponding to the part real complex correlation and a second temporal reflectogram corresponding to the imaginary part of the complex correlation, - a joint analysis module (211) of the first temporal reflectogram and the second temporal reflectogram to identify the presence of defects in the transmission line .
    公开号:FR3060128A1
    申请号:FR1662308
    申请日:2016-12-12
    公开日:2018-06-15
    发明作者:Esteban Cabanillas;Christophe Layer
    申请人:Commissariat a lEnergie Atomique CEA;Commissariat a lEnergie Atomique et aux Energies Alternatives CEA;
    IPC主号:
    专利说明:

    Holder (s): COMMISSIONER OF ATOMIC ENERGY AND ALTERNATIVE ENERGIES Public establishment.
    Extension request (s)
    Agent (s): MARKS & CLERK FRANCE General partnership.
    SYSTEM AND METHOD FOR DETECTING DEFECTS IN A TRANSMISSION LINE, USING A COMPLEX SIGNAL.
    FR 3 060 128 - A1 (5 /) Reflectometry system (200) for analyzing faults in a transmission line into which a complex generated and then modulated signal has been injected, comprising:
    a means (205) for measuring the modulated complex signal propagating in the transmission line,
    - a demodulator (206) of the measured signal capable of producing a demodulated complex signal,
    - a complex correlator (210) configured to correlate the complex demodulated signal with a copy of the complex signal generated, to produce a first time reflectogram corresponding to the real part of the complex correlation and a second time reflectogram corresponding to the imaginary part of the correlation complex,
    - a joint analysis module (211) of the first time reflectogram and the second time reflectogram to identify the presence of faults in the transmission line.
    200
    System and method for detecting faults in a transmission line, using a complex signal.
    The invention relates to the field of fault analysis impacting transmission lines, such as electric cables and more particularly communication cables.
    More specifically, the invention relates to the particular field of reflectometry applied to wired diagnosis which includes the field of detection, localization and characterization of faults in simple transmission lines or complex wired networks.
    The known reflectometry methods operate according to the following method. A mastered reference signal, for example a pulse signal or even a multi-carrier signal, is injected at one end of the cable to be tested. More generally, the reference signal used is chosen as a function of its intercorrelation properties. The signal propagates along the cable and is reflected on the peculiarities it contains.
    A singularity in a cable corresponds to a rupture of the conditions of propagation of the signal in this cable. It most often results from a fault which locally modifies the characteristic impedance of the cable by causing a discontinuity in its linear parameters. A defect can result from any type of local degradation of a cable, pinching, friction or surface degradation of the cable sheath.
    The reflected signal is back propagated to the injection point, then analyzed by the reflectometry system. The delay between the injected signal and the reflected signal makes it possible to locate a singularity, corresponding to an electrical fault, in the cable. A fault can result from a short circuit, an open circuit or even local degradation of the cable or even a simple pinching of the cable.
    Reflectometry is based on the principle of measuring an echo of the signal injected on a singularity of the cable analyzed. However, there are areas of the cable, called blind areas, for which an echo cannot be measured. These zones depend on the wavelength of the signal, therefore its frequency, the speed of propagation of the signal, the sampling frequency of the measured signal and the distance between the point of injection of the signal and the point where is the singularity. If a fault appears in a blind area, it is therefore not possible to detect its presence using a conventional reflectometry method.
    w Furthermore, fault detection with precision requires using a high frequency signal so that the wavelength of the injected signal coincides with the physical dimensions of the faults in the cable. Analog-to-digital converters that inject and measure a high-frequency signal are expensive. In addition, the transmission channels corresponding to the different cable technologies targeted by reflectometry applications are most often very frequency selective and therefore do not allow observation and broadband diagnosis. Certain frequency bands can be significantly attenuated or disturbed which can make the signal measured by the reflectometry system unusable or in any case complicate the identification of possible faults.
    Another problem also concerns the compatibility of a reflectometry system with a communication cable or network of cables. For such cables, the injected reflectometry signal can disturb the communication signals also transmitted via these cables, which makes it impossible to diagnose while the communication network is in operation. Certain frequency bands cannot be used for diagnosis by reflectometry because they are reserved for data transmission.
    Reflectometry methods and systems for measuring the health of a cable and characterizing the presence of possible faults have been the subject of numerous publications.
    Without being exhaustive, mention may be made of international patent applications WO2014 / 144436 and WO2015 / 145068 which describe frequency reflectometry systems based respectively on spread spectrum signals and orthogonal multi-carrier signals (OFDM).
    These systems do not solve the aforementioned problems because they most often operate at a fixed frequency, do not make it possible to identify faults present in a blind area or to operate the reflectometry system on a network of communication cables in operation without disturbing the communications.
    The invention makes it possible to solve the problem of blind zones by using a complex reflectometry signal modulated in quadrature and by jointly exploiting the reflectograms obtained for the real channel and the imaginary channel of the measured signal.
    The invention also makes it possible to carry out a broadband frequency analysis of a cable by using a frequency transposition of the signal injected into the cable.
    The use of a complex signal also allows simultaneous operation of a data communication via the cable to be analyzed and a fault analysis of the cable by reflectometry with a data transmission rate doubled compared to a real signal.
    The subject of the invention is therefore a reflectometry system for analyzing faults in a transmission line into which a complex signal generated and then modulated has been injected, said system comprising:
    a means of measuring the modulated complex signal propagating in the transmission line,
    a demodulator of the measured signal capable of producing a complex demodulated signal,
    a complex correlator configured to correlate the complex demodulated signal with a copy of the complex signal generated, to produce a first time reflectogram corresponding to the real part of the complex correlation and a second time reflectogram corresponding to the imaginary part of the complex correlation,
    - a joint analysis module of the first time reflectogram and the second time reflectogram to identify the presence of faults in the transmission line.
    According to a particular aspect of the invention, the analysis module is configured to determine a single time reflectogram from the module of the complex correlation.
    According to an alternative embodiment, the system according to the invention further comprises a phase detector configured to measure the phase of the complex correlation at time abscissa 0 and a phase corrector configured to correct the demodulated complex signal of the measured phase by the phase detector.
    According to an alternative embodiment, the system according to the invention further comprises a complex signal generator, a modulator capable of modulating the complex signal to produce a modulated signal and means for injecting the modulated signal at a point of the transmission line .
    According to an alternative embodiment, the system according to the invention further comprises:
    a local oscillator capable of controlling the frequency of the modulator to carry out a frequency transposition of the signal and a local oscillator capable of controlling the frequency of the demodulator to carry out a transposition of the signal into baseband,
    - a control device able to control the value of the frequency at which the signal is transposed.
    According to a particular aspect of the invention, the control member is configured to determine the value of the transposition frequency of the signal as a function of at least one analysis of the first time reflectogram and / or the second time reflectogram.
    According to a particular aspect of the invention, the analysis of the first time reflectogram and / or of the second time reflectogram relates to a measurement of the attenuation of the measured signal.
    According to a particular aspect of the invention, the complex signal generated is a frequency signal with multi-carriers, said system further comprising for this purpose an inverse Fourier transform module applied to the complex signal generated and a Fourier transform module applied to the complex demodulated signal.
    According to a particular aspect of the invention, the complex correlator comprises a correlator of the frequency signal generated with the demodulated frequency signal and an inverse Fourier transform applied to the result of the correlation.
    According to a particular aspect of the invention, the complex signal generator comprises an interface for receiving digital data to be transmitted and a modulator for converting digital data into complex symbols, said system further comprising a receiver for converting the complex demodulated signal into digital data received.
    According to an alternative embodiment, the system according to the invention further comprises an encoder of the digital data to be transmitted and a decoder of the digital data received, the control member being configured to determine the coding rate of the encoder and the decoder .
    According to an alternative embodiment, the system according to the invention further comprises a module for calculating the error rate between the decoded digital data and the digital data to be transmitted, the control member being configured to determine the value of the frequency signal transposition and / or the coding rate as a function of at least the calculated error rate.
    Other characteristics and advantages of the present invention will appear better on reading the description which follows in relation to the appended drawings which represent:
    - Figure 1, a diagram of a fault detection system in a transmission line according to the prior art,
    - Figure 2, a diagram of a fault detection system in a transmission line according to the invention,
    - Figure 2bis, two examples of reflectograms illustrating the contribution of the use of a complex reflectometry signal,
    - Figure 3, a diagram of a fault detection system using an OMTDFt type signal,
    - Figure 4, a diagram of a fault detection system in a transmission line according to a particular embodiment of the invention,
    FIG. 5, the diagram of FIG. 4 in which the correlation module is explained,
    - Figure 6, a diagram of a fault detection system according to an alternative embodiment of the invention.
    Figure 1 shows schematically a system 100 for detecting faults in a transmission line, by reflectometry, according to a principle known from the prior art.
    The system 100 mainly comprises a generator 102 of a reference signal from the parameters 101 of the signal. The reference signal can be time or frequency. It can be a simple time pulse or a more elaborate signal insofar as it has good autocorrelation properties, i.e. the result of an autocorrelation calculation applied to this signal gives a significant amplitude peak that can be identified and detected. For example, the signal used can be of the OMTDR (Orthogonal Multi-tone Time Domain Reflectometry) or MCTDR (MultiCarrier Time Domain Reflectometry) type. A digital-to-analog converter 103 converts the digital signal into an analog signal which is then injected at a point on the transmission line (not shown in FIG. 1) via a coupler 104.
    The system 100 then comprises a measurement part which comprises a coupler 104 (identical to the preceding or separate) for measuring, at a point on the line, the reflected and back-propagated signal in the transmission line. The analog measured signal is digitally converted via an analog to digital converter 105. The digital signal can be filtered 106 or averaged in order to limit the influence of the measurement noise, then a correlator 107 is responsible for correlating the measured signal and the signal generated, for different time offsets, in order to produce a time reflectogram. An example of a time reflectogram is given at the bottom of FIG. 1. It includes a number of amplitude peaks which translate impedance discontinuities in the transmission line. The time abscissas of the peaks on the reflectogram correspond to positions in the transmission line. The conversion relation between temporal abscissa t and position d is given by the relation d = Vt where V is the speed of propagation of the signal in the line. The reflectogram obtained can be corrected 108 by calculating its difference with respect to a reference reflectogram 109. On the reflectogram given in example in FIG. 1, there is a first peak Po corresponding to the discontinuity of impedance at the point of injection of the signal then a second peak Ρ Ί which corresponds to another impedance discontinuity which may result from an electrical fault on the line. Thus, by analysis of the reflectogram, it can be deduced therefrom the presence and location of faults in a transmission line.
    On the right of FIG. 1, there is shown an example of frequency response B of a propagation channel associated with a transmission line, for example a communication cable. On the same diagram, the spectral occupation B s of a typical reflectometry signal is shown. This diagram illustrates the fact that, more often than not, the frequency band available in the cable is much wider than that of the signal injected, in particular due to the limitations of the digital-analog converter 103.
    An objective of the invention is to propose a system which is more flexible in terms of the configuration of the spectral occupancy of the reflectometry signal injected into the cable to be analyzed. On the one hand, a high frequency operation allows better characterization of small faults and on the other hand, certain frequency bands can be disturbed by interference, attenuated due to the frequency selectivity of the frequency response of the cable or reserved for other applications (for example for data communication).
    To this end, the system 200 shown diagrammatically in FIG. 2 is proposed, according to the invention. A main difference between the system 200 according to the invention and a system 100 according to the prior art lies in the use of a complex reflectometry signal and no longer a real signal as is usually the case. Thus, a complex signal is generated 201,202 and delivered at the input of a digital-analog converter 203 in the form of two parallel channels, a channel in phase I and a channel in quadrature of phase Q. The converter 203 thus produces two analog signals which are supplied to an IQ 204 modulator which performs phase modulation to produce an analog phase modulated signal. The modulated signal is injected into the transmission line by means of a coupler 205 or any other equivalent device.
    A measurement of the back propagated signal in the transmission line is carried out by picking up the signal via the same coupler 205 or a second coupler different from the first coupler 205 and is then supplied at the input of an IQ 206 demodulator which performs a phase demodulation of the signal to produce two analog signals corresponding respectively to a phase I channel and a phase Q quadrature channel. The two signals are then digitized via an analog-digital converter 207.
    The system 200 also includes a complex correlator 210 for achieving a correlation, at different time points, between the complex signal measured at the output of the analog-digital converter 207 and the complex signal generated at the input of the digital-analog converter 203. Thus, the correlator 210 provides two distinct reflectograms, a first reflectogram corresponding to the real channel (I) of the complex signal and a second reflectogram corresponding to the imaginary channel (Q) of the complex signal. In other words, the first reflectogram corresponds to the real part of the complex correlation while the second reflectogram corresponds to the imaginary part of the complex correlation. The two reflectograms are used by an analysis module 211 to detect and characterize the presence of possible faults.
    The use of a complex signal associated with the exploitation of two distinct reflectograms makes it possible to improve the detection of faults, in particular by solving the problem of blind zones.
    As explained above, there are zones called blind zones, corresponding to certain values of distance between the point of injection of the signal and the fault, for which the echo of the signal on the fault is not detected. This problem is well known in the field of reflectometry and depends on various parameters including the length of the cable, the wavelength of the signal, its sampling frequency and the speed of propagation of the wave in the cable.
    Thus, the usual reflectometry systems such as that described in FIG. 1, which only use a real signal, do not make it possible to detect the presence of a fault if it is located in a blind zone.
    When using a complex signal, as proposed via the system of FIG. 2, the blind zones for the real part of the signal are not located at the same distances as the blind zones for the imaginary part of the signal. Specifically, the blind zones which relate to the real part of the signal correspond to zones where the imaginary part of the signal is maximized. Thus, by jointly exploiting a first reflectogram corresponding to the real part of the signal and a second reflectogram corresponding to the imaginary part of the signal, the detection and localization of faults is improved since it is then possible to characterize a defect whatever its position on the cable.
    This principle is illustrated in FIG. 2bis which represents two examples of reflectograms corresponding respectively to the real part of the complex correlation 210 (on the left of the figure) and to its imaginary part (on the right of the figure). The diagrams in Figure 2bis illustrate the results obtained by varying the position of a fault along a cable. Each diagram represents the amplitude of the reflectogram as a function of the time abscissa on the one hand and the position of the defect relative to the injection point on the other (expressed in meters). The amplitude peak observed in a reflectogram gives the corresponding position of the detected defect. This position is obtained by converting the time abscissa of the peak in the range of distances (via the speed of propagation of the signal).
    On each of the two reflectograms, it can be observed that for certain values of the distance between the fault and the signal injection point, no amplitude peak is observed in the reflectogram. This phenomenon occurs periodically when the position of the fault along the cable is varied. The areas for which no peak is observed in the reflectogram correspond to the so-called blind areas.
    However, it is also noted that the blind zones are not located at the same positions for the reflectogram corresponding to the real part of the signal and for the reflectogram corresponding to the imaginary part of the signal.
    Thus, by exploiting the two reflectograms, there is no fault position for which it is not possible to identify an amplitude peak in at least one of the two reflectograms.
    The analysis 211 of the two reflectograms can consist in observing the two reflectograms separately, for example by fixing a detection threshold for each reflectogram and by retaining the observed amplitude peaks, which exceed this threshold, in one or the other. of the two reflectograms.
    Analysis 211 can also consist in calculating a single reflectogram from the two reflectograms supplied by the correlator 210, for example by calculating the module of the complex correlation or the module squared of the complex correlation. Thus, an amplitude peak corresponding to a defect will be present in the complex correlation module regardless of the position of the defect.
    In the diagram of FIG. 2, a single system 200 has been represented which includes both the elements dedicated to the generation and injection of the signal into the cable and the elements dedicated to the measurement of the reflected signal, to calculation and the reflectogram analysis.
    In an alternative embodiment not shown in FIG. 2, the system 200 can be broken down into two distinct systems, a first system dedicated to the generation and injection of the signal at any point of the cable (for example at one end) and a second system dedicated to measuring the signal reflected at any point on the cable, to calculating and analyzing the reflectogram. This variant is particularly advantageous when the signal injection point and the measurement point of the reflected signal are two separate points, for example when the cable is very long or for complex cable networks.
    The analysis module 211 can restore the analysis results to a user via a man-machine interface (not shown), for example a screen or any other interface. The analysis results can consist in providing the calculated reflectogram (s) or in directly providing the position (s) of the identified defect (s) as well as any other information concerning the defects detected.
    According to a particular embodiment of the invention, the system 200 also includes a control member 212 coupled to a local oscillator 213 which acts on the modulator 204 to carry out a transposition of the signal into frequency before its injection into the cable. Conversely, the local oscillator 213 also acts on the demodulator 206 to bring the signal back to baseband after its acquisition. Although a single local oscillator 213 has been shown in FIG. 2, there may be two separate local oscillators associated respectively with the IQ modulator 204 and the IQ demodulator 206.
    The controller 212 controls the local oscillator by communicating the value of the signal transposition frequency to it.
    An advantage of this embodiment of the invention is that it makes it possible to transpose the signal into the high frequencies of the propagation channel associated with the cable to be analyzed. A high frequency signal has a short wavelength which allows better characterization of small faults. Furthermore, the control unit 212 can determine the transposition frequency as a function of various parameters.
    The transposition frequency can be selected so as to place the signal in a frequency band authorized for fault analysis and to avoid any frequency band prohibited because it is reserved for other applications.
    The transposition frequency can also be selected so as to choose the signal frequency band according to the parameters of the cable to be analyzed. In fact, the frequency band of a cable is generally very frequency-selective and the choice of the signal frequency has a direct impact on the measured reflectogram and therefore on the accuracy of the characterization of the faults. It is therefore important to be able to optimize the frequency band of the signal and to be able to vary it dynamically as a function of the type of cable analyzed.
    The controller 212 can also determine the transposition frequency as a function of an analysis of the reflectogram supplied by the correlator 210. More specifically, the controller 212 can analyze the level of attenuation of the signal on the reflectogram and by deduce information on the power level of the signal measured in the current frequency band. If the power level is too low, this means that the selected frequency band is too attenuated, in this case the control member 212 can select another frequency band and therefore a new transposition frequency.
    Other analysis criteria can be used by exploiting the reflectogram to, for example, determine if the frequency band of the signal is disturbed by interference or if more generally the reflectogram is not usable and requires a band change from frequency. Thus, the controller can dynamically modify the transposition frequency if the current frequency band of the signal is disturbed.
    The system 200 comprising the control member 212 can also be used to carry out a broadband reconstruction by performing a successive scan of the entire frequency band of the cable in sub-bands. In this way, several reflectograms associated with several frequency sub-bands can be determined and an overall reflectogram associated with the total frequency band of the cable can be obtained in fine.
    According to another embodiment of the invention, the system 200 may also include a part 201,202 for transmitting data as well as a part 208,209 for receiving data. The transmission of data is done via the reflectometry signal, thus making it possible to design a system 200 which functions both as a communication system and as a reflectometry or transferometry fault analysis system. An advantage of this embodiment is that it allows the two systems to operate simultaneously without them interfering with each other or interfering with each other.
    The transmission part of the system includes a digital data generator 201 or more generally an interface for receiving digital data from a communication application. It further comprises a digital modulator 202 able to convert binary data into complex symbols in order to provide a complex digital signal to the converter 203. The digital modulator 202 can be a phase modulator PSK (Phase Shift Keying) or an amplitude modulator QAM (Quadrature Amplitude Modulation) or any other symbol modulator or encoder capable of converting a sequence of bits into complex digital symbols belonging to a given symbol constellation.
    Optionally, the digital modulator 202 may also include a channel coder or correction coder or encoder of digital data which aims to add redundancy to the bits to be transmitted in order to protect them against possible disturbances causing transmission errors in the propagation channel .
    The reception part of the system includes a digital demodulator 208 which converts the complex symbols of the measured signal into bits as well as a data receiver 209 which transmits the demodulated bits to the application intended for the data. Optionally, the digital demodulator 208 includes a decoder for decoding the demodulated bits if they have been coded in transmission. The digital demodulator 208 may also include a module for calculating the error rate on the symbols or on the bits received by comparison with the symbols or the bits transmitted or by a mechanism integrated into the decoder.
    The controller 212 can be configured to select the type of digital modulation / demodulation and / or the type of bit coding / decoding. In particular, the control unit 212 can determine the best coding rate to be applied to the bits to be transmitted as a function of the analysis of the reflectogram which gives an indication of the state of the transmission channel.
    The controller 212 can also use the error rate information calculated by the decoder to determine the parameters of the coder and the decoder but also to select the transposition frequency. Indeed, the error rate gives information on the level of disturbance in a given frequency band. Thus, if the error rate is too high, for example greater than a given threshold, the control unit can decide to select another frequency band for the signal.
    The system 200 according to this embodiment suitable for communication can allow several simultaneous communications on different frequency bands, by choosing a different transposition frequency for each system in the case of a network of communication cables comprising several communication systems 200 connected to different points of the network. This scenario corresponds to a transferometry application.
    We now describe a particular embodiment of the system according to the invention associated with a reflectometry and frequency communication signal with multi-carriers of the OFDM (Orthogonal Frequency Division Multiplexing) type. This technology was used in particular to develop specific signals used in reflectometry such as OMTDFt (Orthogonal Multi-tone Time Domain Reflectometry) or MCTDR (MultiCarrier Time Domain Reflectometry).
    FIG. 3 represents a diagram of a reflectometry and data transmission system based on an OMTDR type signal.
    The system described in FIG. 3 comprises a digital modulator 301, or a symbol coder, for converting a sequence of binary data to be transmitted into complex digital symbols via a phase modulation PSK or an amplitude modulation QAM. The complex digital signal thus formed is transmitted to a serial-parallel multiplexer 302 and then to a preprocessing module 303 which achieves Hermitian symmetry of the symbols and adds a guard time. The symbols are then transmitted to an inverse Fourier transform module 304. At the output of this module, the symbols are purely real due to the preprocessing operation 303 performed before the inverse Fourier transform 304. A demultiplexer 305 then makes it possible to serialize the real digital signal which is sent to a digital-analog converter 306 then to a coupler 307 to be injected into a transmission line.
    The system also includes a coupler 307 for measuring the signal reflected at a point on the line. The measured signal undergoes the opposite operations to those carried out in transmission. It is digitized via an analog-digital converter 308, then multiplexed via a multiplexer 311. A direct Fourier transform module 312 converts the signal in the frequency domain, then a postprocessing operation 313 opposite to the preprocessing operation. treatment 303 performed on transmission, is applied. A demultiplexer 314 makes it possible to serialize the complex digital signal which is then demodulated via a digital demodulator 315 or a symbol decoder.
    The analysis of faults is carried out on a real signal by performing a correlation 309 between the signal at the input of the analog digital converter 306 and the signal at the output of the analog-digital converter 308. An analysis module 310 makes it possible to characterize the possible faults at from the measured reflectogram.
    FIG. 4 represents an evolution of the system of FIG. 3 to which the principles of the invention described in FIG. 2 have been applied.
    The common elements between the system 400 of FIG. 4 and the system 300 of FIG. 3 are identified with the same reference number. Likewise, the common elements between the system 400 of FIG. 4 and the system 200 of FIG. 2 are also identified with the same reference number.
    The invention applied to the system of FIG. 3 thus consists in directly exploiting a complex signal at the output of the inverse Fourier transform module 304 instead of a real signal as is the case for FIG. 3. For this purpose, deletes the preprocessing modules 303 and postprocessing 313 used in order to render the real signal at the output of the IFFT module 304. In this way, the redundancy symbols inserted at the input of the module 304 can be deleted. The complex correlation 210 is carried out between the signal at the input of the converter 306 and the signal at the output of the converter 308. To optimize the complexity of implementation, in particular the number of operations required, the correlation 210 is carried out by calculating the transform inverse Fourier product of the direct Fourier transforms of each of the two signals x and x '. This calculation can be illustrated by the following formula:
    c (t) = / a / (t + t). ® * (r) dr = TF -1 {TF {/ (t)} TF {»* {/)}}
    J - QO
    FIG. 5 represents an alternative embodiment of the system described in FIG. 4. In this alternative, a systolic implementation of the inverse Fourier transform 401 and direct 402 is used so that it is possible to suppress the multiplexers and demultiplexers 302,305,311,314.
    In addition, the correlator 403 can be simplified by directly performing the inverse Fourier transform of the product of the signals taken respectively at the input of the IFFT module 401 and at the output of the FFT module 402.
    FIG. 6 also represents a diagram of a fault detection system according to another alternative embodiment of the invention.
    According to this variant, the system 200 described in FIG. 2 is completed with a phase detector 602 and a phase corrector 603 which aim to correct the phase errors that the signal can undergo during its propagation in the cable and also compensate for the phase shifts that may exist between the local oscillators associated with the IQ modulator 204 and the IQ demodulator 206. Similarly, if the transposition frequency is modified during operation, the phase of the signal can be modified on reception. A phase shift may also appear between the signal injected into the cable and the measured signal due to the respective frequency translation operations performed on the injected signal and on the measured signal.
    The reflectometry signal transmitted in baseband is denoted x (t).
    The signal at the output of the IQ 204 modulator performing a translation from frequency to frequency f 0 is denoted x r / (t) = 5R (x (t) e 7 ' 27r ^ oi ), where 5R () denotes the real part d 'a complex signal.
    The signal x r f (t) is demodulated at the output of the IQ demodulator 206. If the phase error between the modulator 204 and the demodulator 206 is equal to φ 0 , and, by neglecting the attenuation of the channel between transmitter and receiver , the received baseband signal is defined as:
    x '(t) = x (t) e i <Po (l + θ _ ϊ (2π2ί ° Ο)
    The frequency component at 2f 0 is filtered (filter not shown in FIG. 6 which can be integrated into the demodulator 206).
    The reflectogram is obtained from the correlation between the received signal x ’(t) and filtered and the injected signal x (t), by calculating the complex correlation c (t):
    J λ CO s * CO x '(t + τ) χ * (τ) άτ = e i <Po I x (t + τ) χ * (τ) άτ τ = —oo —co
    The phase error can thus be directly extracted from the value c (t = O) of the reflectogram because for t = 0 the result of the integral + T ) x * ( T ) dT ®st real. Thus c (t = O) = e j (p0 .
    Thus, the system 600 described in FIG. 6 comprises a phase detector 602 capable of measuring the value at t = 0 of the reflectogram calculated at the output of the correlator 210. A phase corrector 603 is then applied to the signal at the output of the analog converter- numeric 207 before calculating a new reflectogram.
    According to a variant, the phase detector 602 can integrate a loop filter in order to smooth the potential variations of the phase error and to ensure a convergence of the system.
    The phase corrector 603 can be produced by a simple complex multiplier.
    The corrected signal at the output of the phase corrector 603 can thus be correctly demodulated then to recover the binary data transmitted via the signal.
    The various components of the system according to the invention can be implemented by means of software and / or hardware technology. In particular, the invention can be implemented in whole or in part by means of an on-board processor or a specific device. The processor can be a generic processor, a specific processor, an integrated circuit specific to an application (also known under the English name of ASIC for "Application-Specific Integrated Circuit") or a network of programmable doors in situ (also known under the English name of FPGA for "Field-Programmable Gate Array"). The system according to the invention can use one or more dedicated electronic circuits or a general-purpose circuit. The technique of the invention can be carried out on a reprogrammable calculation machine (a processor or a microcontroller for example) executing a program comprising a sequence of instructions, or on a dedicated calculation machine (for example a set of logic gates like an FPGA or ASIC, or any other hardware module).
    权利要求:
    Claims (12)
    [1" id="c-fr-0001]
    1. Reflectometry system (200,400,600) for analyzing faults in a transmission line into which a complex signal generated and then modulated has been injected, said system comprising:
    a means (205) for measuring the modulated complex signal propagating in the transmission line,
    - a demodulator (206) of the measured signal capable of producing a demodulated complex signal,
    - a complex correlator (210,403) configured to correlate the demodulated complex signal with a copy of the complex signal generated, to produce a first time reflectogram corresponding to the real part of the complex correlation and a second time reflectogram corresponding to the imaginary part of the correlation complex,
    - a joint analysis module (211) of the first time reflectogram and the second time reflectogram to identify the presence of faults in the transmission line.
    [2" id="c-fr-0002]
    2. The reflectometry system (200,400,600) according to claim 1 wherein the analysis module (211) is configured to determine a single time reflectogram from the complex correlation module.
    [3" id="c-fr-0003]
    3. A reflectometry system (600) according to one of the preceding claims further comprising a phase detector (602) configured to measure the phase of the complex correlation at time abscissa 0 and a phase corrector (603) configured to correcting the complex demodulated signal of the phase measured by the phase detector (602).
    [4" id="c-fr-0004]
    4. A reflectometry system (200,400,600) according to one of the preceding claims further comprising a generator (201,202) of complex signal, a modulator (204) capable of modulating the complex signal to produce a modulated signal and means (205) for inject the modulated signal at a point on the transmission line.
    [5" id="c-fr-0005]
    5. A reflectometry system (200,400,600) according to claim 4, further comprising:
    - A local oscillator (213) able to control the frequency of the modulator (204) to achieve a frequency transposition of the signal and a local oscillator (213) able to control the frequency of the demodulator (206) to achieve a transposition of the signal in band basic,
    - a control member (212) capable of controlling the value of the frequency at which the signal is transposed.
    [6" id="c-fr-0006]
    6. A reflectometry system (200,400,600) according to claim 5 in which the control member (212) is configured to determine the value of the transposition frequency of the signal as a function of at least one analysis of the first time reflectogram and / or of the second time reflectogram.
    [7" id="c-fr-0007]
    7. The reflectometry system (200,400,600) according to claim 6, in which the analysis of the first time reflectogram and / or of the second time reflectogram relates to a measurement of the attenuation of the measured signal.
    [8" id="c-fr-0008]
    8. A reflectometry system (400) according to one of claims 4 to 7 in which the complex signal generated is a frequency signal with multicarriers, said system further comprising for this purpose an inverse Fourier transform module (304,401) applied to the complex signal generated and a Fourier transform module (312,402) applied to the demodulated complex signal.
    [9" id="c-fr-0009]
    9. A reflectometry system (400) according to claim 8 in which the
    5 complex correlator (403) comprises a correlator of the frequency signal generated with the demodulated frequency signal and an inverse Fourier transform applied to the result of the correlation.
    [10" id="c-fr-0010]
    10. Reflectometry system according to one of claims 4 to 9 in
    Wherein the complex signal generator comprises an interface (201) for receiving digital data to be transmitted and a modulator (202,301) for converting the digital data into complex symbols, said system further comprising a receiver (208,315) for converting the demodulated signal complex in digital data
    15 received.
    [11" id="c-fr-0011]
    11. A reflectometry system (200) according to claim 10 further comprising an encoder (202) of the digital data to be transmitted and a decoder (208) of the digital data received, the control member
    20 (212) being configured to determine the coding rate of the encoder and the decoder.
    [12" id="c-fr-0012]
    12. A reflectometry system (200) according to claim 11 further comprising a module for calculating the error rate between the data
    Decoded digital data and digital data to be transmitted, the control unit (212) being configured to determine the value of the signal transposition frequency and / or the coding rate as a function of at least the calculated error rate .
    100 120 140
    2/7
    200
    LO
    Ο
    CM
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    引用文献:
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    2018-06-15| PLSC| Publication of the preliminary search report|Effective date: 20180615 |
    2019-12-31| PLFP| Fee payment|Year of fee payment: 4 |
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    优先权:
    申请号 | 申请日 | 专利标题
    FR1662308|2016-12-12|
    FR1662308A|FR3060128B1|2016-12-12|2016-12-12|SYSTEM AND METHOD FOR DETECTING DEFECTS IN A TRANSMISSION LINE USING A COMPLEX SIGNAL|FR1662308A| FR3060128B1|2016-12-12|2016-12-12|SYSTEM AND METHOD FOR DETECTING DEFECTS IN A TRANSMISSION LINE USING A COMPLEX SIGNAL|
    US16/467,973| US11156652B2|2016-12-12|2017-11-29|System for detecting faults in a transmission line by using a complex signal|
    EP17804207.3A| EP3552032A1|2016-12-12|2017-11-29|System for detecting faults in a transmission line by using a complex signal|
    PCT/EP2017/080767| WO2018108526A1|2016-12-12|2017-11-29|System for detecting faults in a transmission line by using a complex signal|
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