FR2533053A1 - Method and device for remote monitoring and remote control of equipment distributed along a digital transmission link via a fibre optic line - Google Patents

Abstract

This method of remote monitoring consists in transmitting remote monitoring or remote control information by means of a particular digital pattern constituted by isochronous binary elements of the same definition as the normal digital traffic transmitted to line in place of the latter, this particular digital pattern having a periodic structure generating, in its power spectrum, a characteristic frequency line exceeding in level the envelope of the power spectrum of the normal digital traffic on the line, and in receiving the said information by detection of the characteristic frequency line. The figure illustrates the circuits of one transmission direction of a receiver equipped with a photo emitter 9 whose laser diode is quadrupled and of a remote control receiver 13 controlling the permutation of the particular laser diode in service when it detects, in the signal on the line, the characteristic frequency line of a digital pattern attached to a permutation command.

Description

Method and device for monitoring and remote control of the equipment distributed along a digital transmission link by fiber optic line.

 The present invention relates to the remote monitoring and remote control of equipment distributed along a digital link by fiber optic line.

 In very long-range digital transmission systems using fiber optic lines equipped with repeaters, it is envisaged to use laser diodes as a light source. As laser diodes do not currently meet the conditions of life and reliability required for very long door transmission systems, there is provision for the first generation systems, a certain redundancy at the level of the laser diodes equipping the repeaters. The laser diodes are, for example, systematically quadruple, the four examples being connected to the outside of the same optical fiber by the intermediate = diary of a selector making it possible to choose the one in service. The use of such redundancy in inaccessible repeaters such as underwater repeaters involves remote monitoring of the copies in service of laser diodes and control of the selectors ensuring their permutation.

 The object of the present invention is to provide remote monitoring and remote control using a very small number of circuits in the distributed equipment so as not to compromise the reliability and the service life of a link.

 It relates to a method of remote monitoring and remote control of equipment distributed along a digital transmission link by fiber optic line using, as online signal, a series of isochronous binary elements. This method consists in transmitting remote monitoring or remote control information by means of a particular digital pattern which consists of isochronous binary elements of the same definition as those of the online signal, which is transmitted online by interrupting the normal digital traffic and which exhibits a periodic structure generating in its power spectrum a characteristic frequency line exceeding in the lower level of the online power spectrum of normal digital traffic, and receiving said remote monitoring or remote control information by the detection of the presence of said characteristic frequency line in the power spectrum of the online signal.

 It also relates to devices for transmitting and receiving remote monitoring or remote control signals implementing the method.

 The periodic nature of the digital patterns used to transmit remote control and remote monitoring information simplifies the circuits necessary for their development which do not have to memorize the patterns but only their elementary period. The characterization of each of the above-mentioned patterns by a natural frequency line allows their detection by simple analog filtering.

Other features and advantages of the invention will emerge from the appended claims and from the description below of an embodiment of the method given by way of example. This description will be made with reference to the drawing in which:
FIG. 1 represents a repeater of a digital link per fiber optic line, equipped with photo-emitters the laser diode of which is quadrupled, remote monitoring of the service diodes of the laser diodes and a remote control for their permutation,
- Figure 2 details a remote monitoring transmitter of the repeater of Figure 1
- And Figure 3 details a remote control receiver of the repeater in Figure 1.

 FIG. 1 shows, in general, a bidirectional repeater of a very long range digital link using a fiber optic line per direction of transmission. The transmission signal using optical fibers in light form is a digital signal composed of a series of isochronous binary elements. In each direction of transmission, the signal arrives at the repeater under one. light form by an optical fiber 1 respectively 2. I1 is put in electrical form in a photoreceptor 3 respectively 4. It is then applied to a clock recovery circuit 5 respectively 6 recovering the cadence of the binary elements or modulation speed and at a regenerative circuit 7 respectively 8 performing a reshaping and a resynchronization of the binary elements at the speed of modulation recovered. After regeneration, it is returned in light form by a photo-emitter 9 respectively 12 and re-emitted outside the repeater on an optical fiber 11 respectively 10.

 The electro-optical conversion of the signal from the regenerative circuit 7, 8 is done in the photo-emitters 9, 12 by means of a laser diode driven by a modulator and equipped with a polarization circuit with regulation keeping its power constant 'light resignation. This bias circuit, of conventional design, implements a servo which tends to increase the intensity of the bias current when the power of the light emission decreases and, conversely, to decrease this intensity when the power of the light emission believes, it is indeed well known that the light emisslon of a laser diode occurs as soon as the intensity of its current.

polarization exceeds a certain threshold and, beyond this threshold the power of the light emission varies in the same direction as the intensity of the polarization current.

 For reasons of reliability and lifespan, each photo-emitter 9, respectively 12 has four copies of laser diodes equipped with individual polarization circuits 91, 92, 93, 94 respectively 121, 122, 123, 124 and attacked by individual modulators 95, 96, 97, 98 respectively 125, 126 127, 128. The aging of each unit is monitored by means of a current threshold detector fitted to the individual polarization circuit and controlling the intensity of the polarization current It is known in fact that at constant temperature, the polarization current of a laser diode operating at constant power increases with aging and that beyond a certain maximum threshold, an imminent end is foreseeable. The selection from among four of the working copy of the laser diode of a photo-emitter- 9, 12 is ensured by means of a modulator selector 99, 129 and an optical selector 100, 130. The one and the other are produced in mechanical form and driven by a motor 101, 131 controlled by a remote control receiver 13, 14 itself connected to the output of the regenerator 7, 8 belonging to the same direction of transmission.

 The individual bias circuits of the four copies of the laser diode of a photo-emitter 9, 12 have outputs on which are available binary aging control signals generated by their current threshold detectors. These outputs are joined by a logic gate of type "or" 15, 16 at the input of a remote control transmitter 17, 18 interposed at the output of the regenerative circuit 7, 8 in the other direction of transmission by means of a coupler 19, 20.

 As soon as, in a repeater, a laser diode in service on a direction of transmission has a bias current greater than the threshold of the current detector of its bias circuit, the remote control transmitter is triggered which is inserted in the repeater on the other direction of transmission and which interrupts normal digital traffic by a digital remote monitoring signal characteristic of the rank of the repeater. The terminal at the origin of the direction of transmission processed by the laser diode in service showing signs of aging recognizes the remote monitoring signal and generates, instead of normal digital traffic towards the repeater concerned, a characteristic digital remote control signal of the rank of the repeater. This remote control signal is detected by the remote control receiver of the repeater concerned and triggers the starting of the actuation motor of the photo-transmitter selectors which change the copy in service of the laser diode.

The remote control and telemonitoring signals used are formed of digital patterns made up of isochronous binary elements of the same definition as those of normal digital traffic and are assimilated by repeaters regenerators to normal digital traffic so that their transmission from a repeater to a terminal or vice versa does not require any particular provision. Each digital pattern has a periodic structure generating in its power spectrum a characteristic frequency line exceeding in level the envelope of the power spectrum of normal online digital traffic. Fo being the speed of modulation, a digital pattern having a constitutive period formed of
M binary elements have a fundamental frequency characteristic Fm.

Fo
F which can be adjusted by playing on the value M and whose power level can be adjusted relative to the envelope of the power spectrum of normal digital traffic online by playing on the duration of the pattern.

 Assigning specific characteristic frequencies to remote control or remote monitoring signals, for example by assigning them distinct M values, enables reception of these signals by frequency detection achievable using very simple analog circuits.

The periodicity of their structures also makes it possible to simplify the digital transmission circuits contributing to their development.

 FIG. 2 details the constitution of the remote control transmitter 17 of the repeater represented in FIG. 1. This comprises a circuit for composing the pattern of the remote monitoring signal, circuits and guidance controlling access to the composition circuits in one direction of the connection and a tripping circuit have the switching circuit and the active time of the composition circuit.

 The composition circuit is formed by a multiplexer 170 addressed by a counter 172. The multiplexer 170 has data inputs 171 in number equal to that of the binary elements of the period constituting the digital pattern of the telemonitoring signal considered, brought to the level logic O or 1 depending on the definition of this period, a given output and addressing inputs. The counter 172 is connected by outputs parallel to the addressing inputs of the multiplexer 170. It is looped on itself and has a counting capacity equal to the number of binary elements of the period constituting the digital pattern of the remote monitoring signal When it is oadenced by the signal from the clock recovery circuit 5, it causes at the output of the multiplexer 170 the emission of a series of binary elements having the periodic structure of the digital pattern of the remote monitoring signal considered.

 The switching circuits consist of a selector 173 routing the timing signal either to the regenerative circuit 7 or to the counting input of the counter 172 and of a logic gate of type "and" with two inputs 174 which is inserted at the output of the multiplexer 170 and which makes it possible to maintain the output of the remote control transmitter at level 0 when the latter is not triggered.

 The trigger circuit is a monostable 175 which determines the duration of the digital pattern of the remote control signal considered and which is connected as an output to the control of the selector 173 and to an input of the logic gate of type "and" 174. of this monostable 175 which is that of triggering of the remote control transmitter is attacked by the logic gate of type "or" 16 centralizing the aging control signals of the copies of the laser diode of the photo-transmitter 12 (FIG. 1). In its stable state corresponding to the non-triggering of the remote control transmitter 17, the monostable 175 delivers at its output a logic level 0 which is reproduced on the output of the remote control transmitter 17 by the logic gate of type "and" 174 and which causes the application of the timing signal to the regenerative circuit 7. In its unstable state corresponding to the deolenehement of the remote control transmitter 17, the monostable 175 delivers at its output a logic level 1 which makes the a logic gate of type "and" 174 transparent to the output signal from the multiplexer 170 and which causes the application of the timing signal to the counter 172.

 The regenerative circuit 7 outputs a logic level 0 when it is deprived of the timing signal of the clock recovery circuit 5. The coupler 19 is a circuit fulfilling a logic function of type '! Or ". Logic level 0 constant supplied by the remote control transmitter 17 when it is not triggered makes it transparent to the output signal from the regenerative circuit 7 formed by normal digital traffic while the constant logic level 0 applied to it by the circuit. the remote control transmitter 17 is triggered makes it transparent to the output signal from the remote control transmitter which interrupts normal traffic.

 In practice, the modulation speed being very high, it is possible to do without the logic gate of type "and" 174 and insert capacitors at the inputs of the coupler 19 which block the transmission of the continuous level (logic state 1) possibly present at the output of the multiplexer 170 while it is addressed by the counter 172 in the blocked state. it should be noted here the extreme simplicity of the circuit for composing the pattern which memorizes at the inputs of the multiplexer 170 only one period of the pattern and which does not include a synchronization circuit a pattern which can start without drawback at any point of its constitutive period.

 FIG. 3 details the constitution of the remote control receiver 13 of the repeater represented in FIG. 1. This comprises a narrow band filter 1151 centered on the characteristic frequency of the remote control signal considered followed by an amplifier-detector 142, of a level 132 circuit, a noise suppressor circuit and a step-by-step control circuit -the selector drive motor ensuring the commissioning of one of the four copies of the photo diode laser- transmitter 9.

 The narrow band filter 941 is for example a quartz filter whose selectivity is sufficient to allow only one frequency line to pass among those used to characterize the remote control or remote monitoring signals.

 The level threshold circuit 132 can be a Schmitt trigger.

it allows the receiver to enter sensitive only to characteristic frequency lines of a sufficient power level. Its hysteresis ensures a frank release free of beat phenomenon.

 the interference suppressor circuit consists of a logic gate of type "and" 133 with two inputs connected to the output of the level threshold circuit 132, one directly, the other by means of a delay circuit 134 This delay circuit 134 provides a time delay making it possible to ensure that the remote control receiver is triggered on a remote control signal and not on a parasite.

 The step-by-step control circuit consists of a D type flip-flop 135 of a power amplifier 136 and an auxiliary contact 137. The D type flip-flop has its D input constantly brought to logic level 1, its clock input CP connected to the output of the suppressor circuit, its reset input MR connected to ground via a resistor 138 and to a source of positive bias via a capacitor 139 and of the auxiliary contact 137. A resistor 140 connects to the ground the connection point of the capacitor 139 and of the auxiliary contact 137. The amplifier 136 is connected between the supply of the motor 101 and the output Q of the rocker 135.

 The auxiliary contact 137 is closed by the motor 101 in each of the four positions of the selectors corresponding to the commissioning of one of the four copies of the laser diode of the photo-emitter 9.

When the output of the suppressor circuit goes to level 1 attesting to the detection of a characteristic frequency line of sufficient level to correspond to a remote control signal, the D type flip-flop is triggered, its Q output going to logic level 1 causing the setting in operation of the motor 101 via the power amplifier 136. The selectors rotate causing the exchange of the working copy of the laser diode of the photo-emitter 9. At the same time the auxiliary contact 137 opens so as not to close at the end of said exchange and generate a positive pulse at the reset input of flip-flop 135 which resets the output Q of said flip-flop to logic level 0 and interrupts the operation of motor 101.

 In a transmission system at 280 M bit / s, the duration of a remote control or remote monitoring signal determined by the monostable 175 of the remote control transmitters is advantageously taken equal to 10 ms and the delay of the delay circuit 134 of the suppressor circuit of the remote control receiver socket equal to 2ms.

 Given the configuration of the system, it is possible to adapt the same pattern for a remote control signal and a remote monitoring signal. it is also possible to improve the system at the cost of greater complexity: - transmission of a remote monitoring signal on interrogation of a receiver by a terminal, - remote control for looping from one direction of transmission to the other at level of a repeater, - remote monitoring of several thresholds of the polarization current of the copies in service of the laser diodes of the photo-emitters of the receivers.

Claims (6)

1 / Method for remote monitoring and remote control of equipment distributed along a digital transmission link by fiber optic line using as a line signal a series of isochronous binary elements, characterized in that it consists in transmitting information of remote monitoring or remote control via a particular digital pattern which consists of isochronous binary elements of the same definition as those of the online signal, which is transmitted online by interrupting normal digital traffic and which has a periodic structure generating in its power spectrum, a characteristic frequency line exceeding in the lower level of the online power spectrum of normal digital traffic, and in receiving said remote monitoring or remote control information by detecting the presence of said characteristic frequency line in the signal strength spectrum online. 2 / Device for implementing the method according to claim 1 placed in equipment of a digital transmission link by optical fiber line comprising clock means (5) delivering a timing signal at the speed of modulation of the signal online, characterized in that it comprises at least one transmitter (17) which delivers on command a particular digital pattern with periodic structure and characteristic frequency line corresponding to remote monitoring information known as a remote control interrupting normal digital traffic and which comprises - means for composing (172, 170) of a particular digital pattern with periodic structure clocked by the clock means (5) delivering said pattern in series form at the speed of modulation of the online signal, - means for switch (173, 174) controlling access to the transmission link for the composition means, - and trigger means (175) controlling the time of activity and of conn exion to the liaison of the means of composition. 3 / Device according to claim 2 applied to a digital transmission link by optical fiber line employing a binary digital signal online, characterized in that the means for composing a particular digital pattern with periodic structure comprise - a multiplexer (170) with entries given in number equal to the number of elements of the period constituting the particular digital motif, brought to logical levels 0 or 1 according to the definition of this period and with addressing entries, - and a counter (172) at parallel outputs connected to the addressing inputs of the multiplexer (170), said counter (172) being clocked by the clock means (5) and having a capacity equal to the number of elements of the period constituting the particular digital pattern.  4 / Device according to claim 2 arranged in a repeater of a transmission link by fiber optic line comprising a regenerator for the online digital signal- clocked by a signal at the speed of modulation of the online signal by the clock means ( 5) characterized in that said switching means comprise - a selector (173) controlled by the triggering means (175) routing the clock signal to the regenerator or to the composition means. 5 / device for implementing the process according to claim 1, placed in an equipment of a transmission link by fiber optic line and characterized in that it comprises at least one receiver which is sensitive to the line of characteristic frequency of a particular digital pattern corresponding to remote monitoring or remote control information and which comprises - a narrow band filter (141) which is centered on the frequency line characteristic of the particular digital pattern and which receives the transmitted signal as an input online, - a detector amplifier (1112) connected at the output of the narrow band filter (1111), - a level threshold circuit (132) placed following the amplifier (1112) which delivers a binary signal whose state corresponds to the detection or not of the remote monitoring or remote control information. 6 / Device according to claim 5, characterized in that the receiver further comprises a suppressor circuit formed by a delay circuit (134) and a logic gate of type "and" (133) with two inputs connected to the output from the level threshold circuit (132), one directly, the other via the delay circuit (134).