NL1002544C2 - Optical packet switched network for telecommunications - Google Patents

Abstract

The network includes two nodes connected by an optical connection. An address signal and a data signal of each polarised packet signal being transmitted are signals which have the same wavelength. The optical connection is a transmission line. The second node includes a polarisation controller. The controller is between the transmission line and a polarisation separator. This adjusts a polarisation orientation of the incoming packet signals, with respect to the separator. The second node includes a power splitter which has an input port connected to one end of the transmission line.

Description

Title: Optical Packet Switching System A. Background of the Invention 1. Field of the Invention

The invention is in the field of optical signal processing systems. More specifically, it concerns the address field recognition in an optical packet-switched network.

2. State of the art

In an optical packet-switched network, data, usually in digital form, is transported through the network in optical packets. 10 An optical packet is a data modulated optical signal of a certain wavelength and with a certain defined structure. It is usual that such a packet, such as, for example, an ATM cell, comprises a header part and a data part, hereinafter referred to as address field ('header') and information field ('payload'), respectively. The address field includes encrypted routing and / or destination information, while the information field contains the actual data to be transported through the network. Arriving at a node of the network, an optical packet must be forwarded via switching means either to a receiver connected to the node or to a subsequent node based on the information in the address field of the packet. For this purpose, the address field of the packet must be read, and possibly changed for transport to a subsequent node, while the information field thereby remains (can remain) unread and unchanged. In principle, therefore, the optical packets from the optical domain can first be converted to the electrical domain; in the electrical domain the packets are switched after analysis and possible change of the address field; and then the switched packets are converted back to the optical domain. However, this is soon a much too slow switching procedure, especially in view of the desire for increasingly higher bit rates. Another possibility is to leave the optical packets in the optical domain as much as possible and switch optically. The optical switching means to be used for this purpose, however, require electrical control. Therefore, a relatively small part (eg 10%) of the optical power of the signal containing the optical packet is split off, to be analyzed therefrom after analysis of the address and / or route information in the address field. deriving the optical or electrical domain electrical control signals for driving the optical switching means. The optical packet (ie the remaining part of the signal power, which contains the full packet information) is meanwhile, if necessary, guided via temporary storage means, such as, for example, a delay line, to an input of the switching means.

A technique in which the address field analysis is performed in the electrical domain is known, for example, from reference [1] (for more details regarding the cited references 10 see below under C.). Thereby, the divisional part of the packet signal, which contains the full packet information, is completely converted into an electrical signal. In general, since the address field signal is much shorter in length than the information field signal (for example, for an ATM cell, the length ratio of address field and information field signal is approximately 1:10), it actually takes unnecessarily long before the actual analysis can start.

Reference [2] discloses a technique in which only the first 5 bytes (the address field) of the split-off part of the optical signal from an ATM cell are converted into an electrical signal, using a part split off simultaneously from the same obtained synchronization signal. An analysis signal for the switching means is derived from analysis of the electrical address field signal. The analysis also results in a new address field signal which is converted into an optical signal. The new address field signal is coupled synchronously to the other part of the ATM cell signal via a beam coupler to replace the old address field signal therein.

Reference [3] discloses a network of the type mentioned in the preamble of claim 1, in which the address field signal is separated from the split-off part of the optical packet signal in the optical domain. In that reference, an optical telecommunication system is described in which packets are transmitted which are composed of an optical data signal of a first wavelength, modulated with data to be transmitted, and an optical control signal of a second wavelength. The second wavelength is specific to a particular destination, and therefore effectively forms the address field signal of the packet. A network node of the system is provided with an optical switch and with control means selectively addressing 1002544 3 signals of the second wavelength to route a particular packet through the switch. In addition, part of the signal power of a packet is split off and examined by filtering for a signal of the second wavelength specific for the node. When this node-specific signal is found, this signal is converted to the electrical domain and used as the control signal for the switch. The system known from reference [3] has a number of limitations.

Due to the use of signals of different wavelengths within one package, additional measures are required to counter dispersion problems. The wavelength range from which the node-specific wavelengths are selected is no longer available for any extension of the transmission capacity in the network. There is no option to give a 15 package a different destination on the way.

In addition to the limitations already mentioned, the known techniques discussed above have the further drawback that part of the packet signal power is lost due to signal splitting for analysis of the address field of the packet. In the technique of reference [2], such a signal loss also occurs in the beam coupler with which the new address field signal is coupled synchronously to replace the old address field in the packet signal. Such signal losses require additional signal amplification, especially if packets are to be routed through several nodes.

B. Summary of the invention

The object of the invention is to provide an optical packet-switched network, which does not have the above-mentioned limitations and drawbacks of the known art. To this end it offers a network in which in the optical domain the address field signal is separated from the packet signal on the basis of a different physical quantity than known from the technique of reference [3]. It uses optical packets therein which are optical signals, the signal parts of which form the address field and the information field are signals of the same wavelength and with different polarizations. In doing so, it makes use of the fact that in the standard glass fibers customary for optical connections, although not the polarization 1002544 4 itself, but the angular relationship is retained, these two different polarization states in a Poincaré representation are as points on the globe of Poincaré. In addition, it makes use of the fact that no signal power is lost in polarization splitters, combiners and controllers. In the further description of the invention, the optical signal parts constituting the address field and the information field of an optical packet signal will be referred to as address signal and data signal, respectively.

According to the invention, an optical packet-switched network of a type as known from reference [3], and as summarized in the preamble of claim 1, has the feature of claim 1. Since the address signal and the data signal have the same wavelength, no dispersion problem, as may be the case with the technique known from reference [3].

Further preferred embodiments of the network according to the invention are summarized in subclaims.

The invention also provides a transmitting device, and a device for replacing the address signal in an optical packet signal, for use in a network according to the invention.

These devices have the advantage that they can be realized with components that are easy to integrate.

The invention further provides an optical packet signal which is polarized in the sense as defined in the feature of claim 1.

An advantage of the application of the polarization as a distinguishing physical quantity of the address signal and the data signal in an optical packet signal can still be that the position of the address signal is no longer critical within the packet structure. Therefore, the packet structure is not necessarily tied to a structure in which the address field takes precedence, and the length of an optical packet can be limited. This does require that each receiver connected to the network be equipped with a polarization beam splitter and separate detectors for both polarizations in order to receive the full packet information. On the other hand, both the transmitter and the address replacement device can operate less time-critical, which can make these devices simpler and cheaper.

From references {4] and [5], techniques are known in which address recognition takes place in the optical domain. Thereby locally (ie in a node receiving a packet) a synchronously generated bit pattern is compared with the address information in the address field of the power split portion of the optical packet signal. When this bit pattern is encountered, an electrical control signal is generated for controlling an optical switch, to an input of which the optical packet is guided via a delay line. For the purpose of synchronous generation of the bit pattern, a pulse-shaped clock signal, which is orthogonally polarized with respect to the optical packet signal, is added immediately before the address field is transmitted. Locally, this clock signal is separated by polarization splitting of the divisional part of the packet signal.

Reference [6] describes a technique in which a packet structure is applied, in which a so-called "CW period" is added between an address field signal and an information field signal. This CW period is a constant signal with a length adapted to the address field. After analysis, in the electrical domain, of the Ares field signal in the power splitting portion of an incoming packet signal, the "CW period" of the delayed other portion of the packet signal is used to modulate a new address field therein.

C. References 25 [1] F. Masetti, et al., "ATMOS (ATM Optical Switching): Results and conclusions of the RACE R2039 project", ECOC '95, September 1995, Brussels, conference paper no. 243 (pages) ; [2] F. Masetti and J.M. Gabriagues, "Optical cell processor for ATM gigabit photonic switches", ECOC '92, pp. 1-4; [3] WO-A-9321706; [4] I. Glesk, et al., "All-optical address recognition and self-routing in a 250 Gbit / s packet-switched", Electronic Letters, 4th August 1994, Vol. , No. 16, pp. 1322/3; [5] D. Cotter, et al., "Self-routing of 100 Gbit / s packets using 6 35 bit keyword recognition", Electronic Letters, December 7, 1995, Vol. 31, no. 25, pp. 2201/2; [6] J. Spring et al., "Photonic header replacement for packet switching", Electronic Letters, 19th August 1995, Vol. 29, no.

10 0 L 5 4 4 6 17, pp. 1523-1525; [7] EP-A-0513919; [8] WO-A-93/17363; [9] EP-A-0562695; [10] EP-A-0522625; [11] Dutch patent application no. 1000182 (from applicant; not published in time).

All references are considered to be incorporated in the present application.

D. Brief description of the drawing

The invention will be further elucidated by a description of an exemplary embodiment, with reference being made to a drawing comprising the following figures: FIG. 1 schematically shows an optical packet-switched system according to the invention provided with a network node according to a first variant; FIG. 2 schematically shows a network node according to a second variant; FIG. 3 schematically shows an optical packet transmitter according to the invention in a first variant; FIG. 4 schematically shows an optical packet transmitter according to the invention in a second variant; FIG. 5 shows a detail of the optical packet transmitter according to the second variant; FIG. 6 schematically shows a device for separating and combining an address signal and a data signal from an optical packet signal according to the invention.

E. Description of Output Examples. FIG. 1 shows a first variant for a node 1 of an optical packet-switched network, comprising a number of such nodes, which are interconnected via optical fiber connections. The node 1 has an input port 2 and an output port 3, respectively coupled to fiber connections 4 and 5 of the network. At the end 4.1 of the fiber connection 4, a packet transmitter 6 is connected to the network. The packet transmitter 6 may be part of a main node (not shown) of the network, or of a node similar to node 1 (see below). The packet transmitter 6 generates packet optical signals P, and transmits them over the fiber connection 4 towards the node 1. Each packet signal P is an optical signal having a two-part structure, an address signal Ax and a data signal 10. These partial signals are information modulated signals, the address signal containing information for routing the packet through the network to a desired destination, while the data signal contains information to be transported by the network to that destination. In the packet signal, the address signal and the data signal are optical signals of the same wavelength, but with different polarizations, which are preferably mutually orthogonal. Such a packet signal is hereinafter referred to as polarized packet signal. This is indicated by indices 1 and 0 in the indications A1 and I0 for the address signal and the data signal, respectively; and further with the characters φ and · in the rectangles in the figure corresponding to the address signal Aj and the data signal I0, respectively, which together form a packet signal P. The node 1 comprises an optical 2x2-20 switch 7, an optical power splitter 8, a polarization beam splitter 9, an optoelectric converter 10, and a controller 11. The power splitter 8 is provided with an input port 8.1 coupled to the input 2 of the node 1, of a first output port 8.2, possibly over a delay line 12, 25 coupled to a first input port 7.1 of the switch 7, and of a second output port 8.3 coupled to an input port 9.1 of the polarization beam splitter 9. An output port 9.2 of the polarization beam splitter 9 is coupled to an input port 10.1 of the optoelectric signal converter 10. An input 11.1 of the controller 11 is electrically connected to an output port of the signal converter 10, while an output 11.2 thereof is electrically connected to a control signal input 13 of the switch 7. A first output port 7.2 of the switch 7 is coupled to the output 3 of the kn point 1. A second output port 7.3, depending on the function of the node, is coupled either with an optical receiver 14 or with a further output 15 of the node 1, to which a further fiber optic connection 16 of the network is connected. An optical transmitter 17, which is of the same type as the optical transmitter 6, can be connected to a second input port 7.4 of the optical 1002544 8 switch 7.

A polarized packet signal P emitted by the transmitter 6 arrives via the fiber optic connection 4 at the input 2 of the node 1. In the power splitter 8, the polarized packet signal is split according to power (eg in a ratio of 1: 9) in signal-identical form. polarized packet signals Pj and P2 which differ only in intensity from the polarized packet signal P. The polarized packet signal Ρχ is coupled through the output port 8.3 to the input port 9.1 of the polarization beam splitter 9. The polarization beam splitter 9 is oriented such that polarized packet signal Pj is split into a separate address signal Aj, which is fed via the output port 9.2 to the input port 10.1 of the O / E converter 10, and a separate data signal I0, which appears at the output port 9.3.

The separate data signal I0 is no longer used in this embodiment. In the O / E converter, the separate address signal Aj is converted into an electrical address signal A. From the electrical address signal, a control signal c is derived from the electrical address signal 11, which signal is sent via the output 13 to the control signal input 13 of the optical switch 7. is put. The derivation of such a control signal is known per se and is therefore not further elaborated here. The other polarized packet signal P2, which exits at the first output port 8.2 of the power splitter 8, is fed via the delay line 12 to the first input port 7.1 of the switch 7. The transit time delay in the delay line 12 is such that the switch 7 can be brought into the correct switching position by the control signal c in time to route the polarized packet P2 through the switch. Depending on the control signal c, the packet signal is either fed via the first output port 7.2 to the fiber connection 5 connected to the output 3 of the node 1, or via the second output port 7.3 to the optical receiver 14 connected to it.

In the foregoing, it has been indicated that the polarization beam splitter is oriented with respect to a received packet signal that the polarization splitting of the address signal and the data signal is performed optimally. However, this is only feasible if the packet signal is sent via a polarization-preserving transmission path, for example if the fiber connection 4, and further up to the input port of the polarization beam splitter, is formed by a polarization-retaining fiber.

However, such fibers are expensive, so that usually the fiber connections are not polarizing. Moreover, as a result of changing environmental influences, such as temperature and mechanical stress, optical signals sent over a fiber connection in a fixed polarization state do not always arrive in the same polarization state. Relatively slow variations occur here. However, the angular relationship (considered on the Poincaré sphere) between two different polarization states, with which optical signals are transmitted simultaneously or successively over such fiber connections, is preserved. Therefore, in the signal path between the second output port 8.3 of the power splitter 8 and the input port 9.1 of the polarization beam splitter 9, a polarization controller 20 will have to be included in order to continuously adjust an incoming polarized packet signal to the normally fixed orientation of the polarization beam splitter 9. Such a polarization controller 20 is controlled by the control element 11 with a control signal r (shown in the figure with a broken dashed line), which is derived, for example, from the average intensity of the electrical signal received at input 11.1. Polarization controllers are known per se. An integrated embodiment of a polarization controller, known from reference [9], is used in the device shown in FIG. 6 and explained below.

If the packet structure of the polarized packet signal is such that the address signal directly precedes the data signal in time order, the same optical receiver as for non-polarized packet signals can be used to receive such a packet signal.

A polarized packet signal can be generated such that the address signal, viewed in time order, is wholly or partly within the data signal, or even forms the tail of the packet.

In FIG. 1, such a packet signal Q, in which the address signal Aj lies entirely within the data signal I0, is schematically shown. The address signal of such a polarized packet signal Q can also be separated from the data signal in the 1002544 node 1. For such a type of packet signal, the delay time of the delay line will have to be slightly adjusted for correct routing by the optical switch 7. However, the packet signal will have passed the switch itself earlier, so that it can be available again a little faster for routing the next signal packet. An optical receiver 14 for such a packet signal must now be provided with a polarization beam splitter 17 for separating the address signal and the data signal, and with two O / E converters 18 and 19 for the separate detection of the separated address and data signals.

Transmitters (see FIGS. 3 and 4) will be described below for both types of polarized packet signals.

The node 1 as shown in FIG. 1 switches packet signals unaltered, i.e. without adjusting the address signal. And by way of example, a 2x2 switch has been chosen as the optical switch, for switching packet signals in one of two directions.

In FIG. 2 schematically shows a variant for a node 21 of a packet-switched network, in which packet signals can be forwarded with possibly changed address signals in one of two or more different directions. Node 21 comprises an optical mxn switch 22 known per se with m input ports 25 ΐρ - ', ΐβ and n output ports Uj, -, ^. The n output ports also form the n outputs of the node, which n outputs can be coupled to as many fiber connections of the network. For each input port ij, for j-1, -m, node 21 includes means 23 for separating address signals and data signals from incoming polarized packet signals, temporarily storing data signals, and combining address signals and data signals into outgoing polarized package signals. Such a member 23 is hereinafter briefly referred to as S / C member 23. Each S / C member has a packet signal input 24 and a packet signal output 25, 35 for incoming and outgoing polarized packet signals, respectively, and an electrical signal output 26 and input 27. Each packet signal input 24 also forms an input of the node 21, which can be coupled to a fiber connection of the 1002544 11 network. The packet signal output 25 of each member 22 leads to a separate input port ij of the optical switch 22. The node further includes a controller 28 coupled to the electrical signal input 26 and output 27 of each S / C member. 23.

An S / C member includes a polarization beam splitter 29, an optoelectric signal converter 30, hereinafter referred to as O / E converter, an electro-optical signal converter 31, hereinafter referred to as E / O converter, and a polarization beam combiner 32 An input port 29.1 of the polarization beam splitter 29 forms the packet signal input 24 of the S / C member 23. The polarization beam splitter 29 is coupled to a first output port 29.2 over a delay line 33 with a first input port 32.1 of the polarization beam combiner. 32, and with a second output port 29.3 coupled to an input port 30.1 of the O / E converter 30. An output port 30.2 of the O / E converter 30 and an input port 31.1 of the E / O converter 31 form the electrical signal output 27 and signal input 26 of the S / C member 23. An output port 31.2 of the E / O converter 31 is coupled to a second input port 32.2 of the polarization beam combiner 32. An output port 32.3 forms the packets signal output 25 of the S / C member 23. The control member 28 supplies an electrical control signal cc to the optical switch 22 via a signal line 34.

A polarized packet signal P arriving at the packet signal input 24 of the S / C member 23 arrives at the input port 29.1 of the polarization beam splitter 29. The polarization beam splitter 29 is oriented such that the polarized packet signal P is split into a separate address signal Aj, which is fed via the output port 29.2 to the input port 29.1 of the O / E converter 29, and a separate data signal I0, which exits at the output port 29.3 and via the delay line 33 to the first input port 32.1 of the polarization beam combiner 32 is guided. In the O / E converter 30, the separate address signal Aj is converted into an electrical address signal A, which is fed via the electrical signal output 27 to the controller 28. From the electrical address signal A 35, a modified electrical address signal A 'and a control signal cc for the switch 22 are derived by the control member 28. The modified electrical address signal A 'is applied to the electrical signal input 26 of the S / C member, and the 1002544 12 control signal cc is sent via the signal line 34 to a control signal input 35 of the switch 22. The derivation of such a modified electrical address signal and of such an electrical control signal, and the manner of control of the optical mxn switch is known per se, as for example from reference [2], and is therefore not further elaborated. In the E / O converter, the modified electrical address signal A 'is converted to optically (polarized) modified address signal Aj', which is then fed to the second input port 32.2 of the polarization beam splitter 32. Meanwhile, the separate data signal I0 is fed through the delay line 33, which is preferably realized by means of a polarization-preserving channel-shaped waveguide, to the first input port 32.1 of the polarization beam combiner 32. In the polarization beam combiner 32, the modified address signal A. ' 15 and the separate data signal I0 are combined. The transit time delay in the delay line 32 is selected such that a polarized packet signal P 'emerges at the output port 32.3 of the polarization beam combiner 32, which is fed via the packet signal output 25 to the relevant input ij of the switch. In the switch 22, the polarized packet signal P 'is routed to one of the outputs Uj, ··, ^ under the control of the control signal cc derived by the controller 28.

Node 21, and more particularly S / C member 23, can also process packet signals Q in which the address signal is not necessarily a lead signal. In fact, only the delay line 33 in the S / C member needs to be adjusted for this.

If the transmission path to which the packet signal input 24 is connected is not polarization-retaining, polarization control must also be used for this network node in this second variant. To this end, a polarization controller 36 is controlled between the packet signal input 24 and the input port 29.1 of the polarization beam splitter 29, which is controlled by a control signal rr, which is derived by the controller 28 from received electrical address signals A.

35 Referring to FIG. 3 and FIG. 4, two variants for a transmitter for polarized packet signals will now be described in more detail. Both variants use components known per se, which can be integrated well, for example on 1002 544 13 semiconductor material such as InP. FIG. 3 schematically shows a first variant of such a transmitter. It includes two modular optical signal sources 41 and 42, a controller 43 for modulating the signal sources, and an optical signal combination circuit 44. The circuit 44 has two input ports 44.1 and 44.2, and an output port 44.3. The output port 44.3 also forms the output of the transmitter. The signal sources 41 and 42 are optically coupled to the input ports 44.1 and 44.2 of the circuit 44, respectively. The signal sources 41 and 42 are driven by the controller 43 and emit modulated optical signals of the same wavelength. To emit a packet signal P, the signal source 41 is modulated with an electrical address signal A, and the signal source 42 with an electrical data signal I. DBR lasers or DFB lasers can be selected for the signal sources. In an integrated version of the transmitter, such lasers can be integrated, preferably in an identical form. In such a situation they transmit light signals with the same polarization, which propagate in a connecting channel-shaped waveguides, for example as TE modes. The signal sources 41 and 42 are coupled via monomodal waveguide channels 45 and 46 to the input ports 44.1 and 44.2 of the circuit 44, respectively. The emitted signals therefore propagate therein as zero-order TE modes. The guided polarization modes TE and TM are hereinafter indicated with a 0 and a 1 as an index in the designations of the address and data signals, respectively. Modulated with the respective electrical modulation signals A and I, the signal sources 41 and 42 respectively transmit the address signal A0 over the channel 45, and the data signal I0 over the channel 46. The circuit 44 is a combined polarization converter and conductor for guided polarization modes. This circuit is a polarization converter / splitter applied in the opposite propagation direction, which is known per se from reference [7]. The circuit includes an asymmetric Y junction 47 and a passive mode converter 48. The Y junction has a bimodal waveguide stem 49 and two monomodal waveguide branches 50 and 51, which are different in propagation constant. of branch 51 than that of branch 50, that in this example of the two branches branch 51 has the greatest propagation constant. The asymmetric Y junction operates such that a zero-order 1002544 14 TE or TM mode further propagating from the branch 50 into the bimodal trunk converts to a first-order TE or TM mode, while such mode converts from the other branch 51 further propagates in the bimodal trunk 49, remains in the zero-order mode. The passive mode-5 converter 48 is based on a central bimodal channel-shaped waveguide 52 which on the one hand connects to the bimodal trunk 49 of the asymmetric Y junction 47 and on the other hand is coupled to the output port 44.3 of the circuit 44. The central bimodal waveguide 52 of the mode converter 48 has a periodic geometric structure dimensioned for a 100% TE01 ™ TM00 conversion. Such a mode converter is selective for the pair of guided modes, i.e. first order TE mode and zero order TM mode, so that a zero order TE mode is passed unchanged.

Thus, an address signal A0 or A0 'emitted by the signal source 41, which propagates via the monomodal channel 45 in the' narrow 'monomodal branch 50 as zero-order TE mode, appears at the output port 44.3 as zero-order TM mode, so as an address signal Aj or Aj '. A data signal I0 transmitted by the signal source 42, which enters the 'wide' monomodal branch 51 via the monomodal channel 46, will leave the output port 44.3 unchanged in zero-order TE mode.

By appropriate timing of the control of the signal sources 41 and 42 by the controller 43, the address and data signals (A0 or Aq ', and I0) can be transmitted at such times that the output port 44.3 over a fiber connection 53 connected thereto. 25 polarized packet signals P or Q are sent. By choosing branch 50 'wide', and branch 51 'narrow', precisely the data signal I0 in circuit 44 will be converted to the other polarization, while the address signal Aq, so that polarized signal packets (A0, I1) at the output to show up. Such signal packets are fully equivalent to signal packets (Αρίφ).

The required polarization conversion can also be performed in one of the monomodal waveguide channels 45 and 46, for example with a passive monomodal polarization converter (100% TE00 * * TM00). In that case, the circuit 44 may be replaced by a simpler polarization splitter, such as that described, for example, in reference [11].

Of course, two lasers can also be used for the signal sources 41 and 42, which emit mutually orthogonally polarized 1002544 optical signals, for example one TE signals and the other TM signals. In that case, too, the circuit 44 may be replaced by the simpler polarization splitter mentioned above. The integration of a pair of such lasers, if practicable at all, makes the manufacture of the transmitting device considerably more complicated. In an embodiment with discrete components, such a mutual orientation of the transmitting lasers to be used is easier to realize.

In FIG. 4 is a schematic representation of a second variant for a transmitter for polarized packet signals. This variant includes an optically modular signal source 61, a controller 62, and a polarization switch 63. The polarization switch 63 includes an optical signal input port 63.1 and an optical signal output port 63.2. The signal output port 63.22 also forms the output of the transmitter. The signal source 61 is coupled via a monomodal waveguide channel 64 to the input port 63.1 of the polarization switch 63. The signal source 61 is of the same type as the signal sources 41 and 42 of the first variant. It is driven by the controller 62, both with the electrical address signal A and with the electrical data signal I, which are now presented successively by the controller 62. Thus driven, the signal source 61 emits a packet signal P0 propagating over channel 64 in zero-order TE mode, wherein the address signal and the data signal have the same polarization. The polarization switch 63 is switchable by means of a switching signal s which is sent to the switch by the control member 62 via an electrical signal line 65. The polarization switch 63 consists of a mode switch 66 and a passive mode converter 67, as shown schematically in FIG. 5. The mode switch 66 is based on a 100% TE ^ ^ TX ^ converter, which is provided with electrode means 68, which can be driven via the signal line 65, for switching between two states: a first state S1 in which a zero-order TE mode entering through the input port 63.1 is converted to a first-order TX-35 mode (TX is TE or TM), and a second state S2 in which the conversion does not take place. Such a mode switch is known from reference [8]. The passive mode converter 67 is a 100% TX01 «* TM00 converter, the bimodal central waveguide of which connects directly to 1002544 16 that of the mode switch 66. The mode switch is controlled by the control device so that at the moment it is signal source 61 emitted packet signal P0 with the address signal A0 enters the mode switch 66, is in the first state S1, and the mode switch 66 is switched to the second state S2 in the transition between the address signal Aq and the data signal I0. At the output gate 63.1, the address signal emerges as a zero-order TM mode, i.e. as an address signal Aj, while the subsequent data signal I0 exits unchanged, so that together they form a polarized packet signal P.

For the signal sources 41 and 42 in the first variant, and the signal source 61 in the second variant of the transmitter, instead of modular lasers, of course, on / off switchable lasers with a constant optical signal can also be selected, which are connected in series with a signal modulator that is controlled by the controller with the appropriate modulation (AI) signals.

In FIG. 6 schematically shows an integrated optical embodiment of an S / C member 81 corresponding to the S / C member 23 of FIG. 2, for separating and combining an address signal and a data signal from a polarized packet signal. The S / C member 81 has a packet signal input 81.1 and a packet signal output 81.2. The S / C member 81 includes a polarization controller 82, a mode splitter 83, a polarization filter 84, a polarization retaining delay line 85, a polarization splitter 86 used as a combiner, a photo detector 87, and a modular laser 88. The polarization controller 82 has a monomodal input channel 82.1, which forms the packet signal input of the S / C member 81, and a bimodal output channel 82.2. The polarization controller is of a type such as 30 known from reference [9]. The polarization controller includes a passive mode converter 89 for mode order number and polarization (ic 100% TX (j0 «* TY01 converter with TX is TE or TM, and TY is TM or TE). The polarization controller also has two control signal inputs 90 and 91, respectively, for a phase control signal and an amplitude-35 control signal (control signal rr of FIG. 2). With these control signals, the polarization controller is continuously adjustable such that an optical signal received via input channel 82.1 is composed of two signal components with mutually orthogonal polarizations, in the 1002544 17 output channel 82.2 appears as an optical signal in which the two signal components have the same polarization but differ in order number (so as TY00 and TY01 signal). an asymmetric Y junction with a bimodal trunk 83.1 that continues the bimodal output channel 82.2 of the polarization controller 82, a first, monomodal "wide" branch 83.2, d it leads to the photo detector 87, and a second, monomodal 'narrow' branch 83.3. The polarization filter is of a type known from reference [10]. This filter is a TY filter, adapted to the chosen passive mode converter. The filter consists of two asymmetric Y-junctions, each with a 'narrow' monomodal branch, 84.1 and 84.2, respectively, and a 'wide' monomodal branch, 84.3 and 84.4, respectively, which are coupled 'back-to-back' via a common waveguide stem 84.5 which is monomodal for one polarization (TX) and bimodal for the other polarization (TY). The 'broad' branches 84.3 and 84.4, and the 'narrow' branches, 84.1 and 84.2, lie in diagonal positions relative to the common trunk 84.5. The 'narrow' branch 83.3 of the mode splitter 83 is coupled via an adiabatic adapter to the 'wide' branch 84.3 of the polarizing filter 84. The 'wide' branch 84.4 is coupled to a first end 85.1 of the delay line 85, while the ' narrow 'branch 84.1 is coupled to the other end 85.2 of the delay line 85. The' narrow 'branch 84.2 is coupled to a first mono-modal input channel 86.1 of the polarization splitter 86 used as a combiner, while on a second mono-modal input channel 86.2 the laser 88 is connected. A monomodal output channel 86.3 of the polarization splitter 86 forms the packet signal output of the S / C member 81. The polarization splitter shown schematically here is of a type as described in reference [11].

In order to be able to separate the address signal Aj from the data signal 10 from a polarized packet signal P, which is input at the input 81.1 of the S / C member 81, and to be able to detect it via the photo detector 87, the polarization controller 82 must be such that in the bimodal output channel 82.2 the address signal propagates as a zero-order guided mode signal and the data signal propagates as a first-order guided mode signal. In that case, the address signal Aj is fed via the 'wide' branch 83.2 of the mode splitter 83 to the photo detector 87 and placed as electrical address signal A on the electrical output port 87.1 1 0 0 2 5 4 4 18 (for example for a controller 28 in Fig. 2). The data signal, now as Ij signal, propagates as zero-order TY mode through the 'narrow' branch 83.1 of the mode splitter 83 and through the 'wide' branches 84.3 and 84.4 of the polarization filter to the input 85.1 of the 5 delay line 85. After traversing delay line 85, the data signal Ij, still in zero-order TY mode, enters polarization filter 84 through the 'narrow' branch 84.1, and exits the filter in the same guided mode via 'narrow' branch 84.2. Subsequently, the data signal Ij propagates unaltered by the polarization splitter 86, via the input channel 86.1 and the output channel 86.3, to the packet signal output 81.2 of the S / C member. The laser is modulated with a modified electrical address signal A 'received at the electrical input port 88.1 of the laser 88, and sends a modified address signal Aq' to the input channel 86.2 of the polarization splitter. In the polarization splitter 86, the changed address signal A0 'is combined with the data signal Ij into an outgoing polarized signal packet P' with a changed address signal.

In principle, the delay line 85 can also be coupled with its ends 85.1 and 85.2 directly or via intersecting waveguides with the 20 'narrow' branch 83.3 of the mode splitter 83 and the input channel 86.1 of the polarization splitter 86. In integrated form, intersecting waveguides have the advantage of less space. Such intersecting waveguides can be realized by channel-shaped waveguides which intersect at a sufficiently large angle. A narrower version is formed by two asymmetric Y junctions coupled by a common bimodal trunk. The polarization filter 84 is again a special shape thereof, in that the common trunk is bimodal for only one of the polarizations. As a result, a signal in the signal passage is filtered to polarization via the 'narrow' branches 84.1 and 84.2. This corrects the data signal I1 in case the delay line 85 is not exactly polarization-preserving.

The delay line 85 can be integrated, for example in the form of a spiral loop. Since, in an integrated channel-shaped waveguide, a signal propagating in a TM mode experiences less attenuation, for the passive mode converter 89 in the polarization controller 82, a TEqq ™ converter is preferably chosen.

A polarization-retaining fiber 1002544 19 can also be used as delay line 85, the ends of which 85.1 and 85.2 are connected via suitable connectors 92 and 93 to the 'narrow' branch 84.1 and the 'wide' branch 84.4 of the polarization filter 84, respectively. . Such an embodiment has the advantage that, for a specific application of the S / C member 81, the delay time of the delay line can be easily adjusted by a fiber of a suitable length.

1002544

Claims (22)

1. An optical packet switched system comprising a first and a second node connected by an optical transmission line, in which system the first node is provided with transmission means for generating and transmitting optical packet signals over the transmission line, each packet signal having an address signal (" header ") and includes a data signal, and the second node is provided with switching means for forwarding packet signals, signal separating means for separating the address signal from at least part of the signal power of a packet signal, and control means for separating the separated signal deriving an address signal from a control signal for controlling the routing of a packet signal by the switching means, characterized in that the transmitting means in the first node are arranged for generating and transmitting optical packet signals, in which the address signal and the data signal are signals, which is essentially this 1d have wavelength and are polarized according to different polarization states, which packet signals are hereinafter referred to as polarized packets, and the signal separation means in the second node includes polarization separating means for separating the address signal from a polarized packet. 2. Optical system according to claim 1, characterized in that the second node is provided with a power splitter provided with an input port coupled to an end of the transmission line, and with a first output port coupled to an input port of the switching means, and from a second output port, the polarization separating means comprising a polarization beam filter having an input port coupled to the second output port of the power splitter, and from an output port coupled to an input of the control means, the polarization beam filter is oriented such that a polarized packet incoming to the input port of the polarization beam filter exits the address signal through the output port of the polarization beam filter. 3. Optical system according to claim 2, characterized in that the polarization beam filter is a polarization beam splitter from which an output port is not used. Optical system according to claim 2 or 3, characterized in that 1002544 includes a polarization controller between the second output port of the power splitter and the input port of the polarization beam splitter. Optical system according to claim 1, characterized in that the control means in the second node are provided with address modifying means for generating, in response to an incoming address signal, a modified optical address signal with substantially the same wavelength as the incoming address signal ; that the polarization separating means comprises a polarization beam splitter 10 which has an input port coupled to an end of the transmission line, and a first output port and a second output port coupled to an input of the control means, the polarization beam splitter is oriented such that, of a polarized packet entering the input port of the polarization beam splitter, the data signal and the address signal essentially exit through the first and second output ports of the polarization beam splitter, respectively, and that the second node is further provided with polarization beam combining means combining the modified optical address signal and the data signal emerging from the first output port of the polarization beam splitter into a polarized pack, said polarization beam combining means comprising a first input port coupled to the first output port of the polarization splitter, of a second input port coupled to the address modifying means, and of an output port coupled to an input port of the switching means. 6. Optical system according to claim 5, characterized in that the input port of the polarization beam splitter is coupled to the end of the transmission line via a polarization controller. Optical system according to any one of the preceding claims, characterized in that the address signal and the data signal have orthogonal polarizations. 8. Transmitter for generating optical packet signals, which comprises a packet structure which includes an address signal ("header") and a data signal ("payload"), which device comprises: - control means, and 1 0 0 <£ 5 4 4 - an optical signal generator that can be modulated by the control means for transmitting a packet signal modulated according to the packet structure via an outgoing optical waveguide, characterized in that the device further comprises polarization adjusting means which can be switched by the control means, which are included in the outgoing optical waveguide, for switching the polarization of the address signal according to a first polarization state, and of the data signal according to a second polarization state, different from the first polarization state, for each packet signal sent via the outgoing signal control waveguide is broadcast. Transmitting device according to claim 8, characterized in that the first and the second polarization states are mutually orthogonal. Transmitting device according to claim 9, characterized in that the outgoing waveguide is a monomodal waveguide channel in which a zero-order mode packet signal propagates from a first polarization of two mutually orthogonal polarizations (TE, TM), and the switchable polarization adjustment means enclosing a switchable and a passive polarization converter in series, which switchable polarization converter is switchable between a first switching state in which a zero order mode of the first polarization (TE or TM) is converted to a first order mode of the second polarization (TM or TE) and a second switching state, in which no conversion takes place, and which passive polarization converter converts a first order mode of the second polarization (TM or TE) into a zero order mode of the second polarization . 11. Transmitting device for generating optical packet signals, which are provided with a packet structure which encloses an address signal ("header") and a data signal ("payload"), which device comprises: - control means, and - optical modules which can be modulated by the control means. signal generating means for transmitting a packet signal modulated in accordance with the packet structure via an outgoing optical waveguide, characterized in that the control means comprise a 1002544 first modulable signal generator for generating an address signal polarized according to a first polarization state, and a second modulable signal generator for generating a data signal polarized according to a second polarization state, and signal combination means for combining the address signal and the data signal into a packet signal, wherein the data signal and the address signal have different polarization positions, which packet signal is called polarized packet signal. Transmitting device according to claim 11, characterized in that the first and second polarization states are mutually orthogonal, and that the signal combination means comprise a polarization beam combination. 13. Transmitting device according to claim 11 or 12, characterized in that the first and the second polarization states are mutually equal, that the signal combination means comprise a polarization beam combiner provided with a first input port coupled to the first signal generator, and a second input port coupled to the second signal generator, and an output port which is coupled to the output light conductor, and that one of the two signal generators is coupled via a polarization converter to the respective input port of the polarization beam combiner. Transmitting device according to claim 11 or 12, characterized in that the signal combination means comprise 25. an asymmetric waveguide Y-junction with monomodal first and second input channels, and a bimodal stem channel, and - a polarization converter for converting a first order mode signal from a first (TE or TM) of two mutually orthogonal polarizations (TE and TM) to a zero order mode signal of the second polarization (TM or TE), the first and second signal generators via monomodal channel waveguides are coupled, respectively, to the first and second input channels of the asymmetric Y junction, and wherein the address signals generated by the signal generators have the same of the two mutually orthogonal polarizations. 15. Device for replacing an address signal in an optical packet signal, which has a packet structure which includes an address signal ("header") and a data signal ("payload"), which device comprises: - a packet signal input for a incoming packet signal, and a packet signal output for an outgoing packet signal, - signal separating means for separating an address signal from an incoming packet signal, - an address signal output for outputting the separated address signal, - an address signal input for receiving from a further address signal, signal combination means for combining at least a part of the received packet signal with the further address signal into an outgoing packet signal, characterized in that the separating means enclose a polarization beam splitter provided with an input port, which is coupled to the packet signal input, and from a first output port and a second output port which second output port is coupled to the address signal output, and that signal combination means includes a polarization beam combiner provided with a first input port coupled to the first output port of the polarization splitter, of a second input port coupled to the address signal input, and from an output gate coupled to the packet signal output, the incoming and outgoing packet signals being signals in which the address signal and the data signal are signals polarized according to different polarization states, which packet is hereinafter referred to as polarized packet signal. 16. Device according to claim 15, characterized in that the first input port of the polarization beam combiner and the first output port of the polarization beam splitter are coupled via a polarization-retaining waveguide. Device according to claim 15 or 16, characterized in that the device further comprises polarization control means which are included between the packet signal input and the input port of the polarization beam splitter. 18. Device as claimed in claim 16 or 17, characterized in that the device further comprises an optical delay range, which is included in the polarization-retaining waveguide via a waveguide junction. Device according to claim 17, characterized in that the polarization means comprise a polarization controller known per se, which is based on a passive mode converter for converting a zero-order guided mode from a first polarization 1002544 to a first order-guided mode of a second polarization orthogonal to the first polarization, and which includes a monomodal input channel and a bimodal output channel, the polarization beam splitter is a mode splitter based on an asymmetric Y-5 junction with a bimodal trunk, which is coupled to the bimodal output channel of the polarization controller. Device as claimed in claim 18, characterized in that the waveguide crossing is formed by a polarization filter known per se. 20. Device as claimed in any of the claims 15, 19, characterized in. that the address signal output is the electrical output of an optoelectric signal converter whose optical input is coupled to the second output port of the polarization beam splitter, and that the address signal input is the electrical input of an electrical optical signal converter, the optical output of which is coupled to the second input port of the polarization beam combiner. 21. An optical packet signal for an optical packet-switched system, which signal comprises a packet structure comprising an address signal ("header") and a data signal ("payload"), characterized in that the address signal and the data signal are signals which have substantially the same wavelength and which are polarized according to mutually different polarization states. Packet signal according to claim 21, characterized in that the address signal and the data signal have mutually orthogonal polarizations. 1002544