DE19950132A1 - Chromatic dispersion compensation device for optical fibre system - Google Patents

Abstract

Several individually-switchable dispersion compensators (60-64) are combined into a dispersion compensation unit (50) in an optical signal transmission path. The dispersion compensators may have different degrees of compensation. Optical couplers and switches are arranged between individual dispersion compensators to connect or shunt dispersion compensation modules. An integrated optics chip may be used to connect or shunt the dispersion compensators, using thermo-optical elements to switch the optical path. The dispersion compensators may consist of dispersion compensation fibres or chirped Bragg grating-based dispersion compensators.

Description

Device for compensation of the chromatic dispersion in an optical fiber

The invention relates to a device for compensating in an optical waveguide (LWL), especially in a one mode fiber, when transmitting an optical signal occurring chromatic dispersion using so-called dis persion compensation modules / dispersion compensators.

Since the introduction of the EDFA optical amplifier (EDFA = Erbium doped fiber amplifier = erbium doped fiber amplifier ker) optical transport networks are increasingly dispersionsbe borders. In other words, pulse expansion limits that caused by the chromatic dispersion of single-mode fibers gently, the transmission length. The chromatic disper As is well known, sion depends on the material dispersion, that is on the dependence of the refractive index on the wavelength and on the waveguide dispersion, that is the dependence intensity distribution of wavelength and refraction index profile, from. The chromatic dispersion is the sum the material dispersion and the waveguide dispersion. To In To avoid symbol interference, the widened Pulses are compressed again before the bit streams in the fed into the next section or to a receiver be fed.

Disper. Have recently been used for dispersion compensation sions compensation modules used. These modules are based on different technologies, for example fiber Bragg grating or dispersion compensation fibers. A dispersion compen sationsmodul based on chirped Bragg grids as CDC (chromatic dispersion compensation) module from Pirelli Cavi e Sistemi SpA. The module that a ge  chirptes Bragg grille, is characterized by a porridge te bandwidth and low losses, and can fiber disper Compensate sions of fibers up to 100 km.

Dispersion compensation modules based on Kompensati Onsfiber are manufactured by Lucent Technologies as a DK series offered. These dispersion compensation modules have one high negative dispersion in the range of 1550 nm these modules can telecommunication systems of great length selected and high bit rates are transmitted. Furthermore become dispersion compensation based on fiber technology tion modules from Corning Incorporated under the Be drawing Corning © DCM © modules offered. This dis persion compensation modules provide a broadband compensation tion based on fiber compensation technology, where the effects of chromatic dispersion in lightwave systems that can be compensated for in the 1550 nm Windows work. With these modules, existing ones Standard single-mode fiber systems (SSMF systems) upgraded who the. These modules are used in long distance telecommunications systems and also for cable television AM video connections and used in networks between office units. It deals is a linear passive technology for the dis persion compensation.

A transmission path from a transmitter to a receiver includes in this technology in the order of the transmitter typically the following modules for the receiver: stronger (after the transmitter), a fiber transmission link, egg NEN dispersion compensation module, an intermediate amplifier in the transmission link, a fiber transmission link, another dispersion compensation module, another Repeaters on the track etc. and finally one Preamp in front of the receiver.  

With the dispersion compensation modules it can be like set out above to be based on fiber-based modules or on modules the basis of chirped Bragg gratings with fiber optic Act circulator. Common to all of these technologies that the degree of compensation is predetermined. As a degree of Compensation has become the length of the so-called standard single-mode fa SSMF established according to the recommendation ITU-T G 652, whose Im pulse expansion with the respective dispersion compensation module can be compensated. For different routes different dispersion compensations are required on modules. When planning a new route, the respective length is taken into account, and the dispersion compensation tion modules are planned accordingly. Existing About load paths must be measured by their length and chromatic dispersion. Dispersion Compens sations modules are then used accordingly. To change the route lengths or were in route planning or made mistakes when measuring the route the dispersion compensation modules are replaced.

The invention has for its object a device to provide the type mentioned above, their compensation onsgrad / assets change easily and ever can be adapted to the requirements.

To solve this problem is the Einrich mentioned above tion characterized in that in a dispersion com pensationsmodul-unit several individual dispersion compen sations modules are summarized, which depending on the com dispersing dispersion, which depends on the fiber length, can be activated optionally. As the degree of compensation decreases is tunable, the track lengths no longer have to be exactly ge plans or be measured, and changes in the Track lengths can be easily compensated. This changes the logistics of the network planner  installers as well as the system provider considerably, as always the same module can be used. The dispersion The degree of compensation can be adjusted at least in stages, the size of the steps depends on how many compensa tion modules can be used in a module unit. For the individual compensation modules can the above-mentioned mod le or technologies for dispersion compensation tion are used.

An advantageous embodiment of the invention direction is characterized in that the individual dis persion compensation modules different compensation have just so that by the optional wiring of the Modules with different degrees of dispersion compensation can be adjusted. In other words, witd by se advantageous embodiment of the invention direction greater flexibility in setting the Degree of dispersion compensation reached.

Another advantageous embodiment of the invention Is characterized in that the dispersion Compensation modules have outputs that are manually ver are switching. The construction effort for the module unit ten reduced and the interconnection of the individual modules by visible and controllable from the outside.

Another advantageous embodiment of the invention Device is characterized in that optical coupler and switches between the individual dispersion compensation ons modules for connecting the dispersion compensation modules or the bridging thereof are arranged. In this embodiment it is advantageous that the Ver switching of the individual dispersion compensation modules elec tronic is also remotely controllable. This version is also particularly user-friendly.  

Another advantageous embodiment of the invention Device is characterized in that optical coupler in connection with electro-optical 1 × 2 switches (these Switches have one input and two outputs) for ver binding the dispersion compensation modules respectively monitoring the same are provided. With the optical Couplers are advantageously lossy me, wavelength independent combiner, and in the electro optical switches around so-called EO switches, which also low loss and broadband switches, the switching time in Range between a few milliseconds and a few seconds lies.

Another advantageous embodiment of the invention Device is characterized in that electro-optical 2 × 2 switches for connecting the dispersion compensation mo dule or bridging the same provided are. The low-loss, broadband 2 × 2 switches (EO- Switches with two inputs and two outputs) electro-optical coupler saved.

Another advantageous embodiment of the invention Device is characterized in that electro-optical 2 × 2 switches for connecting the dispersion compensation mo dule or bridging the same provided and that optical couplers at the inputs and / or Outputs of the dispersion compensation module unit vorese hen are. In other words, the electro-optical 2 × 2- Switch in the above embodiment by opti cal couplers are replaced, which corresponds to the design of the modules can be advantageous.

Another advantageous embodiment of the invention The facility is characterized by an integrated opti module for connecting the dispersion compensation mo  dule or bridging the same. This opti cal module advantageously fulfills the connection Bridging function for all dispersion compensation mo dule in the module unit.

Another advantageous embodiment of the invention The facility is characterized in that the integrated optical module thermo-optical elements for switching the optical path, which is a proven and reliable Technology is.

Another advantageous embodiment of the invention Is characterized in that the dispersion Compensation modules made from dispersion compensation fiber modules or grid dispersion compensation modules. In front existing technologies can therefore be used to some extent Dispersion compensation, that is, grid dispersion comm pension modules, in particular chirped Bragg gratings and Fa water dispersion compensation modules are applied, the have already proven themselves in practice.

Another advantageous embodiment of the invention Facility is characterized by the connection of the dispersion compensation fibers with connection fibers of the Switch or the coupler each have a thermi taper splice, which narrows the mode Includes field diameter, the Mo field diameter of the connecting fibers (approx. 10 µm at 1550 nm) and the dispersion compensation fiber (about 5 µm at 1550 nm) are adjusted, which leads to smaller splice losses.

Another advantageous embodiment of the invention The facility is characterized by an advertisement relationship wise reporting system that the allocation of the dispersion compensation tion modules and / or reports to a management system.  

This display or reporting function can be advantageous can be used to provide an operator with a ge demanded changes in the allocation of the dispersion compensa tion modules to display an error when connecting to avoid.

Another advantageous embodiment of the invention Finally, the facility is characterized by the fact that Display or notification system display elements on the Dispersion compensation modules, a coding of the An end sockets and an interface to the management system includes, whereby the display or reporting system in configured in a particularly simple and reliable manner becomes. The display elements can be legs, and the code Connection sockets can be done electrically gene, so that the display or reporting system with simple means can be realized.

Embodiments of the invention are now based on the lying drawings described. Show it:

Figure 1 is a discretely tunable dispersion compensation module unit with manual connection.

Fig. 2 is a front view of a slide-in, in which the ma manual interconnection can be carried out;

Figure 3 is a discretely tunable dispersion compensation module unit with optical couplers and 1 × 2 scarf tern.

Fig. 4 is a discretely tunable dispersion compensation module unit with 2 × 2 switches;

Fig. 5 is a discretely tunable dispersion compensation module unit with 2 × 2 switches and an optical coupler at the output; and

Fig. 6 is a discretely tunable dispersion compensation module unit with an integrated switch module.

Fig. 1 shows a discretely tunable dispersion compensation module module 2 with manual connection as a schematic diagram. The module unit 2 has three individual dispersion compensation modules 4 , 6 and 8 , which are used to compensate for a 40 km long standard single-mode fiber of the type SMF-28 (module 4 ), a 20 km long single-mode fiber SMF-28 (module 6 ) and a 10 km long single-mode fiber SMF-28 (module 10 ) are designed. Two input connections 10 , 12 and two output connections 14 , 16 are provided on the module unit 2 , each of which is connected to one another by an optical waveguide. The individual modules 4 , 6 , 8 are assigned the inputs 18 , 20 , 22 and the outputs 24 , 26 , 28 . Below the schematic circuit diagram of the module unit 2. FIG. 1 shows an example of how the individual modules 4, 6, 8 26, 22/28 interconnected by suitable connecting or bridging their inputs and outputs 18/24, 20 / with each other, in order to compensate for the chromatic dispersion occurring in a 10 km, 20 km, 30 km or 70 km long single-mode fiber SMF-28. From these examples it can be seen that route lengths from 10 km to 70 km can be compensated in steps of 10 km by the inputs 10 , 12 or 14 , 16 with the inputs or outputs of the modules 4 , 6 , 8 respectively be switched.

Fig. 2 shows the individual connection options in a symbolic representation, as they can be provided on the front of the module unit 2 a push. By actuating the arranged in the upper part of the slide-in, the different inputs and outputs of the modules 4 , 6 , 8 represent the button, the desired connections and thus the degrees of compensation can be established.

Examples of the possible interconnection of four modules (DKM10 / 20/30/40 = dispersion compensation module for 10/20/30/40 km fiber length) for compensation of the dispersion in an up to 100 km long fiber optic link is shown in the following Table given:

In the modular unit according to the invention, in addition to the Ab range (e.g. 0-200 nm SSMF) and the step wide (between 10 and 50 km) also statements about the maximum Attenuation in the form of an overall attenuation to the length of the compen SSMF (for example <0.3 dB / km SSMF) and the Wel length range from 1500 to 1640 nm).

Fig. 3 shows a discretely tunable dispersion compensation module unit 30 with optical couplers 32 , 34 , 36 and electro-optical 1 × 2 switches 38 , 40 , 42 , which connect or bridge between individual dispersion compensation modules 44 , 46 , 48th can effect. The incoming signal S _IN is given to the switch 38 and there according to the control voltage U _S either given to the module 44 (as shown) or bypassed the module 44 (if the switch 38 had been switched). An output of the module 44 and an output of the switch 38 are connected to an optical coupler 32 , the output of which is connected to the next switch 40 , which either gives the signal to the module 46 or bypasses it to a further coupler 34 , which is also connected to the output of module 46 . The connection of the third module 48 is carried out accordingly, and the signal S _{OUT is present} at the output of the module unit 30 .

In Fig. 4, a discretely tunable dispersion compensation module unit 50 with electro-optical 2 × 2 switches 52 , 54 , 56 , 58 is shown. The optical 2 × 2 switches are located at the input and output of the module unit 50 , and they serve to connect or bridge individual dispersion compensation modules 60 , 62 , 64 . From Fig. 4 it is clear that an input signal S _IN , which is present at the switch ter 52 , depending on the control voltage U _{S, is} either supplied to the individual module 60 or bypassed to a switch 54 . The switch 54 forwards the incoming signal depending on the control voltage U _S to the module 62 or past it to a switch 56 . Depending on the control voltage U _S, the switch ter 56 forwards the signal to the module 64 or past it to a switch 58 at the output of the module unit 50 .

Fig. 5 shows an alternative circuit to the circuit of Fig. 4, wherein the switch 58 of Fig. 4 is replaced by an optical coupler 66 's. The switch 52 could also be replaced by an optical coupler 66 .

Fig. 6 shows a discretely tunable dispersion compensation module unit 70 which has an integrated optical chip 72 which takes over the connection / bridging function for individual dispersion compensation modules 74 , 76 , 78 . In the chip 72 , thermo-optical switches 80 , 82 , 86 are provided, which, under the control of a control current I _s, switch the optical path to the dispersion compensation modules 74 , 76 , 78 or bridge these compensation modules. The input signal S _IN is therefore coupled to the individual dispersion compensation modules 74 , 76 , 78 or bypassed according to the above-mentioned scheme and is given as the output signal S _OUT .

The exemplary embodiments described above have in common that the tunability of the dispersion compensation module Unit via a cascading of dispersion Compensation modules with fixed compensation takes place so that through a corresponding selection of the degrees of compensation and a wide range of optical connections of transmission path lengths can be compensated. Not required dispersion compensation modules in one module unit can be bridged or used for further / different routes compensations are used.

Claims (13)

1. Device for compensating the chromatic dispersion in an optical waveguide by means of dispersion compensators, characterized in that several dispersion compensators ( 4 - 6 ; 44 - 50 ; 60 - 64 ; 74 - 78 ) can be individually switched into an optical signal transmission path. are combined in a dispersion compensation module ( 2 ; 30 ; 50 ; 50 '; 70 ). That the individual dispersion compensators 2. Device according to claim 2, characterized in that (4 - 6; 44-50; 60-64; 74-78) aufwei sen different degrees of compensation. 3. Device according to claim 1 or 2, characterized in that the dispersion compensators ( 4 - 6 ) have outputs which are to be connected manually. 4. Device according to claim 1 or 2, characterized in that optical couplers and switches between the individual Dispersions compensators ( 44 - 50 ; 60 - 64 ) are arranged for connecting the dispersion compensation modules or bridging the same. 5. Device according to claim 1 or 2, characterized in that optical couplers in connection with electro-optical 1 × 2 switches for connecting the dispersion compensators ( 44 - 50 ) or bridging the same are hen. 6. Device according to claim 1 or 2, characterized in that electro-optical 2 × 2 switch for connecting the disper sions expansion joints (60-64) and the lock-up thereof are provided and in that optical couplers at the input and / or the output of the Dispersion compensation module unit ( 50 ') are provided. The same is provided or the bridging - 7. A device according to claim 1 or 2, characterized by an integrated optical chip (72) for connecting the dispersion compensators (78 74). That the integrated optical chip thermo-optical elements (80 - 84) 8. The device according to claim 7, characterized in having to switch the optical path. 9. Device according to one of the preceding claims, characterized in that the dispersion compensators made of dispersion compensators ons fibers or lattice dispersion compensators exist. 10. Device according to claim 9, characterized in that chirped Bragg- as grating dispersion compensators Lattice dispersion compensators are provided. 11. The device according to claim 1, characterized in that the connection of the dispersion compensation fiber with An final fibers of the switches or couplers in each case have a thermal splice that narrows the Mode field diameter includes.   12. Device according to one of the preceding claims, marked by Display or notification system that the occupancy which displays dispersion compensators and / or to management management system reports. 13. Device according to claim 12, characterized in that the display or reporting system display elements on the dispersion compensators, a coding of the An end sockets and an interface to the management system stem includes.