FR2696302A1 - Fibre=optics amplifier for long distance telecommunications - has amplifier module extracting interrogation signal, mixing with pump signal and injecting supervisory signal - Google Patents

Abstract

A sub-carrier interrogation signal (SQ) is carried on the principal signal (S). The amplifier operates in a narrow band frequency range to propagate the principal signal. Incoming interrogation signals are coupled (10) to a separate line (10Q), and to an interrogation detector (12). A pump frequency (WP) is injected via a coupler (6) downline to the first coupler to down-convert the signal. The down-converted signal is passed to an address circuit (14), and a local signal (26) added, allowing the transmission (8) of a supervisory signal (SL) along a line (10L), and then to be reinjected in the main fibre optic transmission line (10), amplified (2) and passed through a filter (30) to reduce parasitic light transmission. ADVANTAGE - Service signal can be transmitted over long distances (3-10 km).

Description

Fiber optic link and amplifier For this link.

 The present invention relates to guided optical wave telecommunication systems and more particularly those of these systems which include links covering long distances, for example from 3000 to 10000 km.

 Such a link includes numerous amplifiers distributed over the length of a transmission line made up of optical fibers connected in series. The function of these amplifiers is to compensate for the natural attenuation of a main signal which is guided by this line and which carries the information which the link is intended to transmit.

 The link also includes means for monitoring and improving the operation of these amplifiers by local control. It also includes means for supervising and possibly improving this operation from at least one terminal of this link. Service signals must be transmitted for this along the line.

More particularly, supervision signals representative of the local operating state of each amplifier must be transmitted by this amplifier and be transmitted by the link in order to inform the terminal of this local state. More generally, the supervision signal will be called below "any service signal to be transmitted in the link from an amplifier.

 It is known to give service signals the form of optical waves capable of being transmitted by the optical fiber line itself. It is still necessary to inject these signals into this line.

 European patent document EP-450 524 describes a known injection mode for injecting a service signal into such a line from an amplifier. I1 proposes to use an optical coupler necessarily present in any fiber amplifier, namely the pump coupler which injects into the amplifying fiber the pump wave necessary for the excitation and therefore for the operation of this fiber. This coupler has four branches, two of which are connected in the transmission line, a third receives the pump wave and a fourth receives a service signal.

 This pump coupler is, at least preferably, selective in wavelength because on the one hand the pump wavelength is necessarily different from the main wavelength, that is to say that of the wave which carries the main signal and which must be amplified, on the other hand the injection efficiency of the pump wave must be sufficient to ensure the necessary amplification without for this reason using a power pump wave excessive. The service wavelength, that is to say that of the wave which carries the service signal, is within the scope of this document, different from both the main wavelength and the wavelength pump.

 This known mode of injection is well suited to short distance links but it is less well suited to long distance links. I1 would indeed have in these latter the disadvantage that the service signals would be badly received by the terminal of the link.

 The object of the present invention is in particular to allow good long-distance transmission of supervision signals.

And for this purpose it has in particular for object a fiber optic link comprising successive amplifiers on a line made up of optical fibers and which each comprise:
an optical amplifier means such as an amplifier fiber or a semiconductor amplifier, inserted in series in said line to compensate for a weakening of main signals carrying information to be transmitted by said link,
- a supervision transmitter for transmitting supervision signals at an optical wavelength,
- and a coupler for injecting said supervision signals into said line,
- Said link being characterized by the fact that the optical wavelength of said supervision signals is included in a wavelength band in which said amplifying means amplifies the optical waves so as to compensate for their natural attenuation in said line.

 Such a wavelength band will be referred to as the "gain band" below.

 Using the attached schematic figures, we will describe below how the present invention can be implemented, it being understood that the elements and arrangements mentioned and represented are only by way of nonlimiting examples. When the same element is represented in several figures, it is designated therein by the same reference sign.

 FIG. 1 represents an overall diagram of a bidirectional link according to the present invention.

 FIG. 2 represents a diagram of an amplifier of the connection of FIG. 1.

 This bidirectional link includes two unidirectional links 100 and 200 conveying information to be transmitted in two opposite directions on the same route. These two links are identical. Only the link 100 will therefore be described in detail below, it being understood that the reference numbers of the mutually identical elements of the two links are the same except that the number in the hundreds is 1 for the link 100 and 2 for the link 200.

as shown in FIG. 1, the link 100 includes the following elements:
- An input terminal 101 able to receive information to be transmitted N, and to provide in response a main signal SP consisting of an optical carrier wave having a main wavelength and carrying this information. This main wavelength is for example 1550nm.

 This input terminal is further capable of generating SQ question signals and having them carried by the same carrier wave. For this reason, it constitutes an interrogation terminal.

 - An alternative succession of line sections 102 and amplifiers 104 for transporting the main signal and service signals SL, SQ of an optical nature, in a continuous line made up of optical fibers.

 - Finally, an output terminal 106 able to receive the main signal and to restore in response the information to be transmitted. This terminal is further able to receive and use at least some of said service signals. For this reason, it constitutes a supervision terminal.

 - Each line section is made up of optical fibers 108 which transport the main and service signals by applying attenuation to them.

- Each amplifier such as 104 includes the following elements (see Figure 2):
- An amplifying fiber 2 connected in series in the line to transport the main and service signals. This fiber includes a doping material capable of being excited to amplify the optical waves whose wavelength is included in a gain band depending on this material and the way in which it is excited. This gain band is specific to the amplifying fiber and includes the main wavelength.

This doping material is the same and it is excited in the same way in all the amplifiers of the link.

It is for example erbium, the fibers being made of silica. It may be noted in this regard that the entire link has a narrower gain band than that of an isolated amplifying fiber, this due to the series connection of numerous amplifiers and possibly the presence of line filters, these gain bands being defined between two wavelengths corresponding to 50% of the maximum gain.

 - A pump generator 4 for generating a pump wave WP at a pump wavelength which is capable of exciting the doping material and which is for example 1480 nm.

 - A pump coupler 6 for injecting this pump wave into the amplifier fiber 2. This makes it possible to apply to the main signal an amplification at least partially compensating for the weakening which it undergoes in the line sections.

 This pump coupler is selective in wavelength so that the injection of the pump wave is carried out with good energy efficiency.

 - A supervisory transmitter 8 for transmitting a service signal constituting a supervisory signal SL and consisting of an optical wave having a supervisory wavelength and carrying local information available in this amplifier.

 According to the present invention, this supervision wavelength is included in the gain band of the amplifying fiber 2. It is more particularly included in the gain band of the link, and more particularly still, chosen as close as possible to the main wavelength.

 To simplify the description we will consider below that it is, at least substantially, equal to the main wavelength.

 The weakening of the supervision signal in the line sections following the amplifier 104 is thus compensated by its amplification in the following amplifiers.

 - A non-selective wavelength supervision coupler 10 for injecting this supervision signal SL into the line.

This supervision coupler 10 and the pump coupler 6 are arranged on either side of the amplifying fiber 2 and oriented to inject the supervision signal
SL and the pump wave, respectively, in the amplifier fiber. The supervision signal is thus amplified a first time in the amplifier 104, immediately after its injection into the fiber optic line.

 - Finally an isolator 30 to eliminate parasitic light waves which propagate in the line in the opposite direction to that of the main signal SP. The presence of such an isolator requires that on the one hand the supervision signal SL propagates in the same direction as the main signal, on the other hand the pump wave propagates in the opposite direction, since this signal and this wave are injected into the amplifying fiber 2 from the two ends thereof, respectively. Compared to a direct direction which is that of the propagation of the main signal, the pump wave propagates in an opposite direction and the isolator 30 is disposed downstream of the pump coupler 6, which is itself placed downstream of the amplifier fiber 2, the supervision coupler 10 being placed upstream.

 The interrogation terminal 101 is able to generate interrogation signals of an optical nature at the supervision wavelength. Each such signal contains a query and the address of an amplifier and constitutes a service signal. The supervision coupler 10 comprises, on the one hand, a supervision branch 10L for receiving the supervision signals and injecting them into the line, on the other hand, an interrogation branch 10Q for extracting the interrogation signals from the line.

The amplifier also includes the following elements:
- An interrogation receiver 12 receiving the interrogation signals at the output of the interrogation branch. This receiver provides in response in electrical form the address and the interrogation contained in each such signal.

 - A supervision circuit 14 receiving said local information from a circuit 26. The latter collects partial information for this from sensors not shown. In the presence of an interrogation signal, the receiver 12 supplies the circuit 14 with the address and the interrogation contained in this signal. This circuit recognizes this address when it is that of the amplifier 104. I1 then controls the supervision transmitter 8 in response to this interrogation so that this transmitter transmits said supervision signal. Due to the presence of the isolator 30, the interrogation signals propagate in the direct direction like the supervision signals, which means that, as previously indicated, the interrogation terminal is the input terminal 101 and the supervision terminal the output terminal 106.

 The supervision terminal 106 supplies the local information contained in each supervision signal of the link 100, including an address of the amplifier such as 104 which sent this signal, to the input terminal 201 of the link 200. This the latter transmits this information, through the output terminal 206 of the link 200, to the input terminal 101 of the line 100. This terminal 101 examines this information and generates appropriate service signals to ensure the proper functioning of the link 100 Each unidirectional link such as 100 therefore carries, in addition to the main signal for the transport of which it was created, the service signals relating to this link and those relating to the other unidirectional link such as 200, these service signals including SQ interrogation signals and SL supervision signals.

 Of course, the service signals SL, SQ are carried by subcarriers having non-optical frequencies remote from the non-optical frequencies of the main signal SP.

Claims (9)

1 / Fiber optic link comprising amplifiers (104) which follow one another on a line consisting of optical fibers (108) and which each comprise: - an optical amplifier means (2) inserted in series in said line to compensate for a weakening of signals main (SP) carrying information to be transmitted via said link, - a supervision transmitter (8) for transmitting supervision signals (SL) at optical wavelength, - and a coupler (10) for injecting said supervision signals in said line, - said link being characterized in that the optical wavelength of said supervision signals (SL) is included in a wavelength band in which said optical amplifier means (2) amplifies the optical waves of so as to compensate for their natural weakening in said line. 2 / Fiber optic link comprising: - an input terminal (101) capable of receiving information to be transmitted (N) and providing in response a main signal (SP) consisting of an optical carrier wave having a length of main wave and carrying said information to be transmitted, - an alternative succession of line sections (102) and amplifiers (104) for transporting said main signal and service signals (SL, SQ) of optical nature, in a continuous line consisting of optical fibers, - and an output terminal (106) capable of receiving said main signal and of reproducing in response said information to be transmitted, said terminal being further capable of receiving and using at least some of said service signals, and constituting a supervision terminal, - each said line section consisting of optical fibers (108) for transporting said main and service signals, this transport being accompanied by a weakened - each said amplifier comprising - an amplifying fiber (2) connected in series in said line for transporting said main and service signals, this amplifying fiber including a doping material capable of being excited to amplify the optical waves whose lengths d the waves are included in a band of wavelengths constituting a gain band and including said main wavelength, this doping material being the same and excited in the same way in all of said amplifiers, - a pump generator ( 4) to generate a pump wave (WP) at a pump wavelength suitable for exciting said doping material, - a pump coupler (6) for injecting said pump wave into said amplifying fiber (2) so applying to said main signal an amplification at least partially compensating for said weakening, - and a supervisory transmitter (8) for transmitting a said constitutive service signal uant a supervision signal (SL) and constituted by an optical wave having a supervision wavelength and carrying local information available in this amplifier, means being provided for injecting this supervision signal into said line, said link being characterized by the fact that said supervision wavelength is included in said gain band. 3 / Line according to claim 2, characterized in that said supervision wavelength is substantially equal to said main wavelength. 4 / Line according to claim 3, characterized in that said amplifier (104) comprises a supervision coupler (10) non-selective in wavelength to inject said supervision signal (SL) into said line, said pump coupler (6) being selective in wavelength. 5 / Line according to claim 2, characterized in that a supervision coupler (10) and said pump coupler (6) are arranged on either side of said amplifying fiber (2) and oriented to inject said supervisory signal (SL) and said pump wave, respectively, in said amplifying fiber. 6 / Line according to claim 5, characterized in that that of the two said terminals which is not said supervisory terminal (106) constitutes an interrogation terminal (101) and is capable of generating interrogation signals ( SQ) of an optical nature at said supervision wavelength, said interrogation signals each comprising an interrogation and the address of a said amplifier and constituting said service signals, - said supervision coupler (10) comprising on the one hand a supervision branch (10L) for receiving said supervision signals and injecting them into said line, on the other hand an interrogation branch (10Q) for extracting said interrogation signals from said line, - said amplifier (104 ) further comprising: - an interrogation receiver (12) for receiving said interrogation signals at the output of said interrogation branch and for supplying in response said address and interrogation in electrical form, - And a supervision circuit (14) for receiving said local information, for receiving said address and interrogation, for recognizing said address when it is that of said amplifier and for then controlling said supervision transmitter (8) in response to said interrogation of so that this transmitter transmits said supervision signal (SL). 7 / Line according to claim 6, said input terminal (101) constituting said interrogation terminal, and said output terminal (106) constituting said supervision terminal. 8 / Line according to claim 6, characterized in that said service signals (SL, SQ) are carried by subcarriers having non-optical frequencies remote from the non-optical frequencies of said main signal (SP). 9 / Amplifier according to any one of the preceding claims.