DE4323826A1 - Optoelectronic coupling circuit with change-over switch - Google Patents

Abstract

For low-loss optical switching between one optical waveguide on the input side and two optical waveguides on the output side, it is known to arrange the end face of the one optical waveguide in an accessible manner between the end faces of the two other waveguides. As a result of the comparatively low switching rate and of the additionally occurring coupling losses, a fast low-loss optical coupling circuit is desirable. According to the invention, the object is achieved in that an optoelectronic coupling circuit is constructed by means of dielectric waveguides, a control electrode to which an electric control signal can be applied being provided above at least one of these waveguides, and being a laser diode and/or photodiode arranged in optical connection. <IMAGE>

Description

The invention relates to an optoelectronic coupling circuit circle according to the preamble of claim 1.

To reduce the effort for optical messages Transmission is particularly in the case of near-optical optics Networks for both directions of transmission both at point to point connections as well as with passive optical networks common optical fiber used. In terms of The available laser diodes will also be used for both Direction of transmission with one within the specimen Scattering worked the same wavelength. With regard the so-called called ping-pong operation, in which the laser diodes for the alternately send both directions of transmission and thereby in the transmitting and receiving stations filter devices for the separation of the transmission signals of the two transmission directions can be omitted. The prerequisite is the Ver Use of so-called 2: 1 couplers for coupling the lasers diode and the photodiode on the common light waves ladder. Through this coupler the performance of the optical Signals but weakened by 3 to 4 dB, so that for networks with higher number of participants or higher data rates or distance Laser diodes with high transmission power and photodiodes must be used with high sensitivity, the Let effort increase again. An alternative to this is the possibility of switching the light paths between lasers diode and optical fiber on the one hand and photodiode and Optical fibers on the other hand. For switching from Light trails are known with electromechanical equipment the end face of the used for the transmission Optical fiber between the end faces of the coupling fibers to shift to the laser diode and the photodiode. These  In addition to the coupling losses, the solution also has the further after part of the comparatively slow switching speed, through which it is impossible, for example, from a digita len multiplex signal for voice transmission single bytes decouple. In connection with the development of ring-shaped However, there is an increasing amount of optical networks after fast coupling circuits with a switch Possibility to set up so-called coupling multiplexers also be called add-drop multiplexers.

The object of the present invention is therefore therein, an optoelectronic coupling circuit with Um to develop switches of the type mentioned at the beginning, that with very low coupling losses, the switching times like this are small that even digital time-division multiplex signals with bit rates of a few hundred Mbit / s can be separated with bit accuracy can.

The object is achieved by an optoelectronic solved coupling circuit of the type mentioned, the indicated by the characterizing part of claim 1 Characteristics is further developed. Especially with regard to the comparatively little effort and universal use Availability useful training and development of the Invention According optoelectronic coupling circuit are in the Claims 2 to 9 described.

The invention is intended in the following with reference to in the drawing illustrated embodiments are described in more detail. It shows:

Fig. 1 is an opto-electronic coupling circuit according to the invention in integrated form,

Fig. 2 shows a further opto-electronic coupling circuit in the schematic diagram,

Fig. 3 shows the ring structure of an optical network in which the coupling circuits according to the invention can be used and

Fig. 4 is a partial circuit of the ring structure of FIG. 3.

The practical use of the optoelectronic coupling circuit according to the invention will mainly be in the form of an optoelectric integrated circuit, as shown in FIG. 1. In Fig. 1, a laser diode LD, a photodiode PD, a connection for an optical fiber LWL and a controllable Mach-Zehnder interferometer MZI in stripline technology are arranged on a first carrier plate CHI. The Mach-Zehnder interferometer MZI contains a first coupling side KS1 with two connections, to which the laser diode LD and the photodiode PD are each separately coupled. From the first coupling side KS1 go to each other at a defined distance and with a defined length arranged dielectric waveguides L1, L2 to a second coupling side KS2, one connection of which is connected to the optical fiber provided for the transmission, while the other connection remains free. To control the light transmittance of the dielectric waveguide, an electrode EL is arranged above the second dielectric waveguide L2, which can be supplied with an electrical signal, the arrangement of a further electrode above the first dielectric waveguide L1 is also possible.

The manufacture of the optoelectronic integrated circuit circle can be done in such a way that on a support silicon wafer, the laser diode, the photodiode, the Mach-Zehnder interferometer with electrode EL and possibly also Transistors for amplifier arrangement connected to the diodes Solutions by applying III-V semiconductors, such as wise GaAs or InP can be produced.  

When functioning as an optical switch in the ping-pong Operation between the laser diode and the optical fiber or the photodiode and the optical waveguide, the elec trode EL controlled so that when sending the station's Laser diode LD the total light output in the light waves LWL conductor arrives while receiving light Mach-Zehnder-Inter from the opposite station ferometer MZI is switched by the electrode so that the light reaches the photodiode PD completely.

Instead of a Mach-Zehnder interferometer MZI, a directional coupling switch known per se or a so-called digital Y switch can also be used, as described, for example, in "Electronics Letters" from April 25, 1991, Vol. 27, No. 9, pages 699 and 700. Instead of the Mach-Zehnder interferometer, an optical semiconductor amplifier with twin waveguides, as described, for example, in "IEE-Proceedings-J." Vol. 139, No. 1, from February 1992, pages 79 to 82, when at least one electrode is additionally arranged on the respective structures. Fig. 2 shows a simplified embodiment of the optoelectronic coupling circuit according to the invention, in which in order to generate an optical semiconductor amplifier with twin waveguides on a second carrier plate CH2 in turn a photodiode PD and a laser diode LD with elec trical connections and applied to the two dielectric waveguides L11, L21 are coupled. The dielectric waveguides L11 and L21 are part of a 2: 1 coupler which is connected to the optical waveguide LWL intended for transmission. The waveguides are in turn combined with an active zone with a waveguide-like layer structure, which also serves as an optical semiconductor amplifier. In the exemplary embodiment, a first and a second electrode EL1, EL2 for signal switching are applied over both waveguides L11, L21. The electrodes EL1, EL2 are connected to an electrical control device, not shown in FIG. 2, which is controlled during ping-pong operation as a function of the transmission or reception operation of the station in question.

The formation of the optoelectronic coupling circuit according to Fig. 1 or 2 in semiconductor technology enables ver comparatively high switching speeds, so that now the use of such coupling circuits as multi plexer and demultiplexer for generating or dividing time-division multiplexed signals is possible. Such a possible application is shown in FIG. 3, in which the annular cell of an optical network suitable for the forwarding of so-called ATM signals (asynchronous transfer mode) in asynchronous transmission mode with four coupling multiplexer combinations ADM1. . . ADM4 is shown. The individual switching multiplexer combinations have the task that for a specific subscriber T1. . . T4 or a certain group of subscribers decouple certain information packets from the data or signal flow in the ring and insert new information packets and therefore contain a first coupling multiplexer KM1 for coupling out and a second coupling multiplexer KM2 for coupling in. The information packages consist of the address of the respective subscriber T1. . . T4 and the user data to be transmitted together. The coupling multiplexer combinations used are optically transparent and therefore have the particular advantage that the optoelectric and electro-optical signal conversion of the respective user data can be omitted in the coupling, and depending on the data that is generated, coupling multiplexer combinations of different processing speeds can also be used.

To explain the function of the arrangement according to FIG. 3, a switching multiplexer combination is shown in more detail in FIG . The first coupling multiplexer KM1 is connected on the output side to the output of a first optical fiber LWL1, which serves as part of the ring structure for connecting the first to the second coupling multiplexer combination ADM1, ADM2. The first coupling multiplexer KM1 is constructed accordingly to FIG. 2, however the coupling to the laser diode LD via the dielectric waveguide L21 is omitted, at this point an optical delay line device VL is connected. The output of the delay line VL is connected to the photodiode connection of a second coupling multiplexer KM2, the structure of which otherwise corresponds to that of the coupling multiplexer according to FIG. 2. With the output of the second coupling multiplexer KM2, the input connection of a further optical fiber LWL4 is connected, which serves in the ring for connecting the first and the fourth coupling multiplexer combination ADM1, ADM4. The arranged above the dielectric waveguides of the first coupling multiplexer KM1 electrodes EL3, EL4 are electrically connected to a source for the packet frame clock PCL of the transmitted signals and to an address recognition ADR, to which the photodiode PD2 of the first coupling multiplexer KM1 is also connected via a photo diode amplifier connected. The electrodes EL3, EL4 are switched with the packet frame clock PCL in such a way that the addresses pass through the photodiode for address detection ADR. In the address detection ADR, a control signal for the electrodes EL3, EL4 of the First coupling multiplexer KM1 generated, by means of which the corresponding user data are coupled out of the optical user data stream and reach the photodiode PD of the first coupling multiplexer KM1, from which the user data are finally forwarded to the subscriber T1 as an electrical signal via the address recognition ADR. The user data not intended for the subscriber concerned are routed in optical form via the optical delay line VL to the second switching multiplexer KM2. The delay line VL is implemented in the form of a delay line, that is, an optical waveguide, the length of which is so dimensioned as a function of the operating speed of the address recognition ADR that the gap in the useful data stream from the second coupling multiplexer resulting from reading the data for the first subscriber T1 KM2 data originating from the connected subscriber T1 or replacement signals can also be inserted. For this purpose, the electrodes EL5, EL6 of the second coupling multiplexer KM2 are also connected to the address recognition ADR, to which the laser diode LD2 contained in the second coupling multiplexer KM2 is also electrically connected. The coupling is controlled via electrical signals which are sent from the address recognition ADR to the electrodes EL5, EL6 of the second coupling multiplexer KM2.

In a simplified version of the first coupling multi plexer KM1 is on the control of the electrodes EL1, EL2 waived so that all of the first optical fiber LWL1 incoming optical signals also to the photodiode PD2 of the first switching multiplexer KM1 and thereby in the optical output to the second switching multiplexer KM2 Signals are weakened accordingly. This weakening must then by appropriate reinforcement using an active one Zone under the electrode EL5 of the second coupling multiplexer KM2 can be compensated.

Claims (9)

1. Optoelectronic coupling circuit for coupling in and out of optical signals in or out of a light waveguide, characterized in that a connection for the optical waveguide is provided that this connection, if necessary, via dielectric waveguides with a coupling constructed from dielectric waveguides ler (KS1, KS2) is connected, which is connected via further dielectric waveguides to two output connections to which a laser diode (LD), a photodiode (PD) or a further optical waveguide can be connected. 2. Optoelectronic coupling circuit according to claim 1, characterized, that as a coupler a Mach-Zehnder interferometer (MZI) featured see is a first and a second made of dielectric Waveguides formed coupling side (KS1, KS2) contains that over a first or second at a predetermined distance dielectric waveguides (L1, L2) arranged in relation to one another the two coupling sides (KS1, KS2) connected to each other are that on the first coupling side (KS1) via further dielek trical waveguide a photodiode (PD) and a laser diode (LD) are connected so that the second coupling side (KS2) via a third additional waveguide with that for the Transmission provided optical fiber (LWL) is connected and that optionally over the first and / or the second dielectric waveguide (L1, L2) an electrode EL with a Connection for an electrical signal is applied. 3. Optoelectronic coupling circuit according to claim 1, characterized, that a digital Y switch is provided as a coupler. 4. Optoelectronic coupling circuit according to claim 1, characterized,  that a directional coupling switch is provided as a coupler. 5. Optoelectronic coupling circuit according to claim 1, characterized thereby that as a coupler a combination of an optical half Head amplifier and twin waveguides is provided. 6. Optoelectronic coupling circuit according to claim 1, characterized thereby that as a coupler one made of dielectric waveguides constructor symmetrical 1: 2 coupler is provided. 7. Optoelectronic coupling circuit according to claim 5, characterized thereby that under at least one electrode (EL) an optically active Zone is arranged. 8. Optoelectronic coupling circuit according to claims 1, 5, 6 or 7, characterized, that a first switching multiplexer (KM1) is provided at with an optical fiber for an incoming signal a 1: 2- built up by means of dielectric waveguides Coupler is connected that the two outputs on conclusions of the dielectric waves forming 1: 2 coupler conduct a third or fourth over a predetermined length Electrode (EL3, EL4) are applied, which are electrical with one source for a packet frame clock (PCL) and with one Address recognition (ADR) that are connected to the by the third electrode (EL3) controlled dielectric waveguide ter another optical fiber as an optical delay line (VL) is connected to that through the fourth Electrode (EL4) controlled dielectric waveguide second photodiode (PD2) is connected, which is electrical either directly or via a photocurrent amplifier with the Address recognition (ADR) is connected and that the Adressener  identifier (ADR) with a participant (T1) or a participant mer group is electrically connected. 9. Optoelectronic coupling circuit according to claims 1, 5, 7 or 8, characterized, that a second switching multiplexer (KM2) is provided, the a 2: 1- constructed using dielectric waveguides Coupler contains, being over for a predetermined partial length the two dielek forming the inputs of the 2: 1 coupler optical fibers a fifth or sixth elec trode (EL5, EL6) is applied in electrical connection with the address link (ADR) that the opti cal delay line with that through the fifth electrode (EL5) controlled dielectric waveguide is connected, that to those controlled by the sixth electrode (EL6) dielectric waveguide to a second laser diode (LD2) is coupled that the second laser diode (LD2) electrically with a signal output of the address recognition (ADR) is connected and that the output port of the 2: 1 coupler with a Optical fiber (LWL2) connected for an outgoing signal is.