FR2738430A1 - METHOD AND DEVICE FOR TRANSMITTING INFORMATION ON OPTICAL FIBER WITH DETECTION AND / OR LOCATION OF INTRUSION - Google Patents

Abstract

As known per se, a main wave (OP) carrying information and an auxiliary wave (OA) chosen to couple more easily with the outside than this main wave is injected onto a link fiber (14). According to the invention, a test modulation is applied to this auxiliary wave, the phase (A) of which is measured on the wave (OR) backscattered by the fiber. The invention applies to the transmission of confidential information.

Description

Method and device for transmitting information on fiber

  optical with detection and / or location of intrusion.

  The present invention relates to the transmission of information on optical fibers. It finds application when information to be transmitted must be protected against

  sampling and / or alteration attempts.

  The transmission of such information is often carried out by means of an optical link in the context of which a light wave carrying information is guided over a large distance by an optical fiber. This will be called

hereinafter connecting fiber.

  Although the protection of the information to be transmitted is easier when the transmission is made by such a link as by other means of transmission, it nevertheless poses the technicians, even in this case, a difficult problem. It is known that it is not necessary to cut the connecting fiber to take a small fraction of the light of the information carrier wave. This sampling can be done in particular by a curvature that is applied to this fiber and which flee the fraction of light to be taken. This fraction makes it possible to take cognizance of the information transmitted without it being necessary for it to affect in a detectable way the wave which is received in

fiber output.

  This constitutes a passive intrusion. But it will be understood that it is possible to perform in the same way an active intrusion by introducing light into the core of the binding fiber

  to alter the information transmitted.

  In the absence of being able to prevent such intrusions, we have sought

  to detect and locate them.

  In particular, it has been proposed to carry out such a detection of injecting into the connecting fiber, in addition to a main optical wave carrying the information and propagating in a core of this fiber, an auxiliary wave propagating in an annular guide formed in this fiber. fiber and surrounding this heart. If an attempt is made to intrude by curvature of this fiber, it is possible to detect an attenuation of the auxiliary wave received before a sampling or an alteration of the information carried by the wave.

principal is possible.

  Such detection methods are described in particular in the following documents: - EP-A-0083843 (Corning) - US-A-4134 642 (Kapron) - French patent application FR-A-2635 876 and its

  US correspondent US-SN 400 172 (Augé).

  The present invention can detect quickly

  and surely an intrusion of the kind above.

  Its main objectives are: - to ensure a precise and rapid location of such an intrusion, - to allow such detection and / or localization using

  a simple and inexpensive device.

  And it relates in particular to a method of transmitting information on optical fiber with intrusion detection and / or location in which is injected on a connecting fiber a main wave carrying information and an auxiliary wave chosen to couple more easily with the outside that this main wave, this method being characterized by the fact that one applies to this auxiliary wave a test modulation of which one

  measures the phase on the wave backscattered by the fiber.

  With the aid of the attached diagrammatic figures, the following will be described below how the present invention can be implemented, it being understood that the elements and provisions mentioned and

  represented are only as a non-limiting example.

  FIG. 1 represents an overview of a connection

  optical system embodying the method according to the present invention.

  FIG. 2 represents three diagrams representing the variation of the phase of a test reception signal, on the ordinate, as a function of an intervention distance, on the abscissa. According to FIG. 1, an optical fiber information transmission device with intrusion detection comprises the following elements which are known as to their indicated functions: a main laser 2 for receiving an information signal at transmitting SI and transmitting in response a main wave OP modulated by this information signal.

  - An optical fiber constituting a connecting fiber 14.

  A coupling system 10 for injecting the main wave OP into

this binding fiber.

  A main receiver 16 for receiving the main wave which has

  been guided by this binding fiber.

  All of these elements 2, 14, 10 and 16 constitute an optical link. In this connection it is known to associate monitoring means for detecting and locating an eventual intrusion. According to the present invention, these monitoring means comprise, for example, the following elements: a test generator 4 for providing a sinusoidal SM test transmission signal at a test frequency located in the field of

low frequencies.

  An auxiliary laser 6 for receiving this test transmission signal and for transmitting in response, over a wavelength greater than that of the main wave OP, an auxiliary wave OA carrying a

  modulation constituted by this signal.

  An auxiliary receiver 8 for receiving a light wave of the same wavelength as this auxiliary wave and for providing a test receiving signal SR representative of a modulation of this light wave at said test frequency. - said coupling system 10 for coupling not only the main laser 2, but also the auxiliary laser 6 and the receiver

  auxiliary 16 at one end 13 of the connecting fiber 14.

  And a phase measuring element 12 for measuring the phase of this test reception signal with respect to the test transmission signal, this element being advantageously constituted by means of a synchronous detector. The fiber 14 is preferably monomodal at both lengths -4-

of waves used.

  In general, the method implemented by this device comprises, in a manner known per se, the following operations: - Injection of a main wave OP in a first end of the connecting fiber 14 so that this wave is guided to at a second end 15 of this fiber. This main wave carries an SI modulation representative of an information for producing an optical link transmitting this information between these two

ends.

  - Injection of an auxiliary wave OA in an auxiliary injection end 13 which is preferably, as in the example given, the first of the two ends of the connecting fiber. This wave is guided by this fiber to the other end 15 of the latter. It consists of an auxiliary light and has a "coupling characteristic" different from a corresponding "coupling characteristic" of the main wave OP. The meaning of this expression is as follows: These coupling characteristics represent the coupling possibilities of these waves with the outside of the bonding fiber in the case where an intervention would be made on the fiber 14 and would risk making such a coupling appear. at a point of intervention 17. They are chosen, for example as will be indicated below, so as to obtain the following effects: In a first case where only an intrusion detection would be sought, the effect to be obtained is that any intervention to detect stops the propagation of a substantial fraction of the auxiliary wave, preferably greater than 20% of its energy. In the second case where any intrusion must be located, the effect to be obtained is that an intervention certainly prevents the auxiliary wave OA from propagating in the connecting fiber 14 beyond the point of intervention 17 if this intervention affects sufficiently this fiber to allow coupling the main wave OP with an external system 18 foreign to the optical link. It is understood that such an intervention would intrude on this link. And monitoring a fraction of the auxiliary light reaching one end of the connecting fiber 14 to detect and possibly locate this intrusion. Such a location takes the form of a measurement of an unknown intervention distance x, which is that of the point of intervention 17 from the endpoint.

auxiliary injection 13.

  According to the present invention, during the auxiliary wave injection operation OA, the latter is injected into the connecting fiber 14 for a long time and carries a modulation. The latter is constituted at least by a test transmission signal SM which is periodic at a test frequency. As for the monitoring operation, it comprises the reception of a backscattered wave OR which consists of a fraction of the auxiliary light which has been backscattered by the connecting fiber 14 towards the auxiliary injection end 13. It comprises furthermore a measurement of the phase A of a test receiving signal SR which modulates the backscattered wave at the test frequency. This phase is

  measured against the test transmission signal SM.

  In the absence of intrusion, this phase has a value that is substantially constant or very slowly variable. In the event of an intrusion, it decreases much more rapidly as an increasing curvature or alteration is applied to the fiber. The finding of this

  decrease is the detection of an intrusion.

  The final value of the phase decrease decreases as the intrusion distance increases. Its measurement thus allows the localization

  of the intrusion. This possibility of localization constitutes an essential advantage of the present invention, the detection of the intrusion possibly being carried out by known means.

  In the context of this method, the following arrangements are preferably also adopted: said coupling characteristics different from the main OP and auxiliary OA waves are their optical wavelengths which respectively constitute a wavelength; main and an auxiliary wavelength. This auxiliary wavelength is chosen so that the product lk is less than two. In this product 1 represents the length of the connecting fiber 14 or at least the maximum value envisaged of the intervention distance x. k represents the linear attenuation coefficient of a light having this wavelength in this fiber. It must however be understood that, according to one variant, coupling characteristics of a different kind could also be constituted by different modes of propagation of the two waves. The latter could have the same wavelength, the auxiliary wave can for example be propagated in an annular guide which would be formed in the connecting fiber around and away from an axial guide traveled by the wave

main.

  - In the case where the two waves propagate in the same mode, the auxiliary wavelength is greater than the wavelength

  main. These wavelengths are for example close to 1500 and 1300 nm in the case of monomodal fibers generally used today.

  - A test frequency is between 20% and 90% of a limit frequency V / 41, V being the speed of propagation of the auxiliary light in the connecting fiber 14 and 1 being the length of this fiber. This test frequency is that of said test transmit signal if it is unique. If more than one test transmit signal is used, it is the lowest test frequency that falls within the indicated limits. Said phase measurement is a synchronous detection of the SR test reception signal of the optical intensity of the wave

backscattered.

  The injection of the auxiliary wave OA and the test emission signal SM modulating this wave are prolonged for a duration

  at least one hundredth of a second, it being understood that longer times and even continuous injection are generally preferred.

  The method which has just been described by its main arrangements uses the rear Rayleigh scattering which accompanies the propagation of the auxiliary wave OA and which creates the backscattered wave OR. This latter wave is formed by the superposition of the elementary waves which are backscattered by each of the successive sections of the connecting fiber. With respect to the elementary wave backscattered by a section adjacent to the auxiliary injection end 13, the elementary wave which is backscattered by a section of the same length located at a distance z from this end is attenuated by a factor e -2kz and has a time delay 2z / V, V being the speed of propagation of the auxiliary light in the connecting fiber. If the test transmission signal is of the form cos (wt), the test receive signal will be proportional to cos (wt + A), where A is the phase at

measure.

  When the connecting fiber 14 will undergo, in the context of an intrusion, a strong curvature at the point of intervention 17 located at a distance x from the end 13, this curvature will cause the auxiliary light to leak outside this fiber . No backscattering of this light will therefore be possible from the sections of this fiber which are located beyond this point. The test receiving signal SR will be given, with a coefficient, by the following expression: rx -2kz SR = cos (w (t-2z / v)) e 2dz Figure 2 indicates on the ordinate the tangent tgA of the phase A of this signal, this as a function of the intervention distance x to be determined which is plotted on the abscissa in kilometers. Diagrams 20, 22, and 24 of this figure were obtained by the

  calculation for the following values of the coefficient k, respectively: 0.5 dB / km, 0.3 dB / km, and 0.2 dB / km.

  A backscattered intensity measurement can complete the location. This can only be done when a -8-

  intrusion has been detected or suspected by other means.

  As for the precision of the location, the main parameter is the ratio of the measurement range, that is to say in general of the length 1 of the connecting fiber 14, to the attenuation length 1 / k of this fiber for auxiliary light. Beyond a limit length 1 = 2 / k, phase A is practically no longer sensitive to

  the intrusion and its measurement therefore no longer allows localization.

  This limit length is 18 km for an attenuation of 0.5

  dB / km and would reach 45 km for attenuation of 0.2dB / km.

  Moreover, the precision of the localization increases as w2 that is to say as the square of the test frequency, which leads to

choose a high frequency.

  But the location becomes ambiguous if this frequency exceeds a limit which is worth V / 41. Therefore, unless a complementary measure makes it possible to remove the ambiguity, this frequency should preferably be located around 50 to 75% of the

  limit frequency. That is, the wavelength of the modulation formed by the test transmission signal in the bonding fiber should be about six to eight times the length of that fiber.

  The intensity of the backscattered wave is of the order of one thousandth of that of the auxiliary wave. This is why the auxiliary laser 6 and the coupling system 10 are chosen to emit a high power

  and to minimize coupling losses.

  Complementary distance measurements can be made by modulating the auxiliary wave by several test transmit signals simultaneously or successively, these signals having a small number of different test frequencies. This number seems to be limited to three. Such complementary measurements may make it possible to locate an intrusion even in the case where the auxiliary wave is still propagating, although much more weakly, beyond the point of intervention. The following document can be pointed out:

H.GHAFOORI - SHIRA and T.OKOSCHI.

  Optical Frequency Domain Reflectometry Optical and Quantum Electronics 18, p.265 (1986) This document describes an amplitude and phase measurement of the backscattering of an optical signal modulated according to the method of frequency-dependent reflectometry (OFDR): Optical Frequency Domain Reflectometry ). By this method, the analysis over a large frequency range of the backscattered signal allows, by Fourier transform, to obtain the characteristic of local transmission of an optical fiber. The device used for this can be made in the laboratory but is too complex to be in an industrial context. The curvature localization method according to the

  The present invention also exploits backward Rayleigh scattering.

  But it includes a backscatter measurement at a single test frequency or at a small number of such frequencies. He can thanks to that

  be implemented using a much simpler device.

-10-

Claims (9)

  1) Method for transmitting information on optical fiber with intrusion detection and / or localization, in which a main wave (OP) conveying information and an auxiliary wave (OA) is injected onto a connecting fiber (14) chosen to be easier to couple with the outside than this main wave, this method being characterized by the fact that at least one test modulation (SM) is applied to this auxiliary wave and the   phase (A) on the wave (OR) backscattered by this fiber (14).   2) Method according to claim 1, this method comprising the following operations: - injection of a main wave (OP) into a first end (13) of an optical fiber constituting a connecting fiber (14) for this wave to be guided by this fiber to a second end (15) of this fiber, this main wave carrying a modulation (SI) representative of an information for making an optical link transmitting this information between the two said ends, injection of a wave auxiliary (OA) in an auxiliary injection end (13) which is one of said two ends of said connecting fiber so that this wave is guided by this fiber to the other end (15) of this last, this auxiliary wave being constituted by an auxiliary light and having a different coupling characteristic of a corresponding coupling characteristic of said main wave, these characteristics s of coupling being chosen so that such an intervention at least partially prevents said connecting fiber (14) from guiding said auxiliary wave (OA) beyond a point of intervention (17), which would make an intrusion on this connection, and monitoring of a fraction of said auxiliary light arriving at a said end of said binding fiber to detect and / or locate possibly a said intrusion, - said method being characterized by the fact that during said operation of injection of said auxiliary wave (OA), this latter is injected into said connecting fiber (14) so as to   extended and carries a modulation constituted at least by a test transmission signal (SM) which is periodic at a test frequency.   said monitoring operation comprising the reception of a backscattered wave (OR) which is constituted by a fraction of said auxiliary light which has been backscattered by said connecting fiber (14) towards said auxiliary injection end (13), this an operation further comprising measuring the phase (A) of a test receiving signal (SR) which modulates said backscattered wave at said test frequency, said phase being measured   with respect to said test transmission signal (SM).   3) Method according to claim 2 wherein said different coupling characteristics of said main (OP) and auxiliary (OA) waves are their optical wavelengths which constitute respectively a main wavelength and an auxiliary wavelength, this auxiliary wavelength being such that the product lk is less than two, 1 being a monitored length of said connecting fiber (14) and k being the linear attenuation coefficient of a light having this wavelength in this fiber.   4) Method according to claim 3 characterized in that said auxiliary wavelength is greater than said main wavelength. 5) Method according to claim 2 characterized in that said test frequency is between 20% and 90% of a limit frequency equal to V / 41, V being the speed of propagation of said auxiliary light in said connecting fiber ( 14) and 1   being a monitored length of this fiber.   The method of claim 2 wherein said phase measurement is a synchronous detection of said test receive signal (SR). 7) Method according to claim 2 characterized in that said injection of said auxiliary wave (OA) and said signal   The test transmitting (SM) modulating this wave is prolonged for an injection duration of at least one hundredth of a second.   -12- 8) Method according to claim 2 characterized in that said auxiliary injection end of said connecting fiber   is constituted by its said first end (13).   9) Method according to claim 2 characterized in that said auxiliary wave (OA) is modulated by a number of said   test transmission signals of not more than three.   ) An optical fiber information transmission device with intrusion detection and / or localization comprising: - a main laser (2) for receiving an information signal to be transmitted (SI) and for transmitting in response a main wave (OP modulated by this information signal, - an optical fiber to form a connecting fiber (14), - a coupling system (10) for injecting said main wave (OP) into said connecting fiber (14), - a main receiver (16) for receiving said main wave at the output of said link fiber whereby an optical link is formed, and monitoring means for detecting and / or locating a possible intrusion on said optical link, said device being characterized by the fact that said monitoring means comprise: - a test generator (4) for providing at least one periodic test transmission signal (SM) at a test frequency in the low frequency domain an auxiliary laser (6) for receiving said test transmission signal and for transmitting an auxiliary wave (OA) carrying a modulation constituted by said test transmission signal; - an auxiliary receiver (8) for receiving a a light wave of the same wavelength as said auxiliary wave and for providing a test reception signal (SR) representative of a modulation of this light wave at said test frequency, - said coupling system (10) for coupling said main laser, said auxiliary laser, and said auxiliary receiver at one end (13) of said connecting fiber (14), and a phase measuring member (12) for measuring the phase of said reception signal of said test with respect to said test transmission signal. 11) Device according to claim 10 characterized in that said auxiliary wave (OA) has a wavelength greater than that of said main wave (OP). 12) Device according to claim 10 characterized in that said phase measuring member (12) is a synchronous detector.