DE3422219A1 - Optical data transmission system in the access network - Google Patents

Abstract

For a transmission system serving to transmit information between a central station and a plurality of subscriber stations and vice versa, in particular for transmitting the narrowband signals in the access network of a broadband communications system, a system is proposed according to the invention in which the subscriber stations (1 to 6) are inserted in an optical loop (7) which runs from an optical transmitter (8) in the central station via these subscriber stations to an optical receiver (9) in the central station. The central station transmits information blocks in succession via the loop to the individual subscriber stations, said information blocks if necessary containing a message for the subscriber station as well as the subscriber address. So that the subscriber stations can transmit their messages to the central station in the simplest fashion, i.e. without the need for an optical transmitter, they receive constant light of a pre-defined duration (KL, Fig. 2a) in the information block addressed to them, modulate their message onto this constant light by means of a simple optical switch and forward this signal via the optical loop. If a subscriber station detects that it is addressed in the message block, it receives the message from this information block and then begins to modulate and forward the constant light. Otherwise, as soon as it receives the address, it switches to through-connection and thus forwards the remainder of the information block ... Original abstract incomplete. <IMAGE>

Description

Optical communication system im

Subscriber Line Area The invention relates to an optical communication system for digital transmission between a control center and a group of subscriber stations and vice versa.

From DE-OS 32 14 277 and also from "telecom report" 6 (1983), supplement "Light Communication", pages 212-215, is one such system known.

It is there in the subscriber line area of a broadband optical communication system used and is used to transmit the digital narrowband signals that either on its own or in conjunction with broadband signals in such a broadband communication system, that is designed for a variety of communication services are to be transmitted.

This system, as far as narrowband signals are concerned, has individual ones Subscriber lines in the form of optical fibers, which are star-shaped from the control center are led to the subscriber stations and by wavelength division multiplexing can be operated in both transmission directions.

This means that in the center there is an optical one for each participant Receiver and an optical transmitter and an optical transmitter for each participant must be present.

It is therefore the object of the invention to provide a system of the type mentioned indicate that is cheaper than the known.

The object is achieved as specified in claim 1. Advanced training can be found in the subclaims.

Transmission systems with optical ring lines are widely known, e.g. from DE-OS 30 45 315, but do not have these in every subscriber station only an optical receiver, but also an optical transmitter in the form of a light emitting diode or a laser diode.

In contrast, the invention has the advantage that the subscriber stations do not optical transmitter and still contain signals to the control center via the loop transfer by modulating and forwarding constant light received from the control center. The optical switch with modulator used for this in the subscriber stations is a simple and inexpensive integrated optical component.

The invention will now be explained in more detail with reference to the drawings, for example explained: FIG. 1 shows the principle of the transmission system according to the invention according to claim 1 with the optical ring line, Fig. 2 an example of an information block of the system according to claim 1 and for its switching through in the subscriber stations the optical ring line, and FIG. 3 shows the basic structure of an inventive Broadband communication system according to claim 2, wherein for the narrowband services an optical ring line according to FIG. 1 is provided.

In the system according to FIG. 1, there are several subscriber stations 1 to 6 inserted in a row in an optical ring line 7, which is from a transmitter 8, which is located in a central office, to one also located in the central office Receiver 9 leads. The optical ring line is preferably a single-mode optical waveguide.

From each participant point, only that facility is shown, which takes care of the optical connection of the subscriber station in the ring line. This device essentially consists of one optical switch and the two States: the shown state of readiness to receive, in which he has the optical signal received from the ring line branches off from the ring line and leads to a photo receiver and the through state, not shown, in which he forwards the incoming light from the ring line to the ring line, that is the ring line closes at this point. Such optical switches are in themselves known, e.g. from "Elektronik", 4 / 24.2.1984. These are simple integrated optical components.

A message directed from the central office to a subscriber station is sent to this subscriber station by the control center in individual blocks of information are addressed, transmitted via the ring line 7. Such a block of information is shown in Fig. 2, line a, by way of example. It consists of a first part, in which the address of the subscriber station for which the information block is intended is, is transmitted n times in succession, a second part (shown hatched), that contains the message intended for this subscriber station and one third part, the constant light or unmodulated light with a fixed Contains duration. The frequency n with which the subscriber address repeats one after the other is sent out is equal to the number of subscriber stations in the loop, so that each of the subscriber stations has a chance to recognize the address, what else will be explained in detail.

The constant light component of an information block offers a subscriber station to whom this information block is addressed, the possibility of sending their message to to send out the central unit by modulating this constant light and turning it on the ring line forwards.

The interconnection of such an information block is described below explained about the loop using an example with four subscriber stations. It is assumed for this that the message block, as shown in Fig. 1, line a, is shown, is addressed to the subscriber station 3. The one from the transmitter at the headquarters The transmitted information block receives the first subscriber station 1, as how shown, their optical switch is in the ready-to-receive state and at the same time directs the information block to the photo recipient of this subscriber station. Based the subscriber station recognizes the subscriber address contained in the information block, that the information block is not addressed to you and then switches yours optical switch on passage. A timing circuit (not shown) in each subscriber station ensures that after a specified time, approximately the duration of an information block corresponds, the optical switch from the state of passage back to the state the readiness to receive is switched. The duration of the connection in the Subscriber station 1 in the present example shows line b of FIG Line c shows that subscriber station 1 switches after receiving the first in the information block contained address signal through the rest of the information block, in which then still contains three address signals.

The subscriber station proceeds with this remaining information block 2 in the same way as subscriber station 1, since it also recognizes that the information block is not addressed to them. Line d shows the duration of the Switching through at subscriber station 2, and line e shows that of the subscriber station 2 through-connected remainder of the information block.

This by two address signals compared to the original information block The subscriber station 3 now receives the reduced information block (line e), processed then the message section of the information block following the addresses and only then switches to continuity. In case they just got a message then has to send out, it does so in such a way that it does so because of the connection forwarded constant light modulated with your message.

In addition to this modulation for the transmission of useful information the subscriber station 3 modulates the address of the forwarded constant light the head office and then their own address, so that the following Subscriber stations can recognize that this message is not addressed to them and so that the control center can recognize from which subscriber station it is sending this message received. As shown in line f with the four address blocks, the address of the center in turn is sent n times, so that each subsequent subscriber station as well as the recipient of the headquarters has a chance to receive a recipient address to check. The sender address following the recipient addresses is in line f not shown separately. It can be used as part of the recipient addresses subsequent parts of the message.

No additional component is required for modulation, but rather it becomes the optical switch that puts the light on the further part of the loop forwards, according to the message to be modulated between the two Switched states. So that your own optical receiver does not respond, becomes its optical input during the duration of the constant light and its modulation locked.

The, as described, modulated constant light from the exit of the subscriber station 3 (line f in Fig. 2) now arrives at the optical receiver of the subscriber station 4, which recognizes that the address contained therein is not her own, but that of the And then, as line g shows, for a duration that is the duration of the Corresponds to constant light, switches to continuity and thereby the rest of the modulated Constant light, as line h shows, passes on via the ring line.

After an information block has run through the loop, it sends the transmitter 8 of the control center sends the next information block over the ring line, which is addressed to another subscriber station (line i). It is now beginning new cycle, and all subscriber stations are, as shown in Fig. 1, in the state of readiness to receive. Some of them follow Considerations of the transmission capacity and the power requirements of the above Systems.

This means that low-power logic circuits in the subscriber stations can be used, a maximum transmission bit rate is used for the optical ring line of 34 Mbit / s assumed. The power of the used in the control center as a transmitter Laser is +3 dBm. A sensitivity can be determined for the optical receiver of -53 dBm. Does the attenuation of the fiber optic link (length of the feed 5 km) 12 dB and if the total reserve should be 8 dB, then remain for the switches 36 dB. If the insertion loss of the switch is assumed to be 3 dB, leave it twelve participants are provided with a ring line.

Is within an information block for each direction of transmission a message length of 1 kbit is provided, because of the additional to The addresses required for the messages have a total length of about 3.2 kbit per information block needed. Around ten thousand blocks per second can therefore be transmitted.

With twelve subscriber stations, this corresponds to 825 information blocks per participant and second, i.e. for each transmission direction of a transmission capacity of 825 kbit / s of user information per subscriber. If you put a basic requirement of 144 kbit / s, corresponding to a normal ISDN channel, is around 80 times that The system's transmission capacity is still free available. In this In this case, the access time is around 6 ms. For example, four Participants each occupy one PCM 30 channel and the remaining eight participants a 144 kbit / s ISDN channel each.

The power required to perform the logical functions in a Subscriber station is very low with C-MOS technology because it is in standby mode without message traffic only every 500 ms the decoding of an address and every 6 ms the receipt of an "empty" message occurs. With regard to the power requirement only the operation of the optical receiver matters, which is about 0.1 Watts consumed. The electricity costs and the scope of the emergency power supply are therefore minimal in the system described.

The transmission system described can be used advantageously for transmitting the narrowband signals of a broadband communication system which, as known from the publication cited above, the narrowband signals and the broadband signals are transmitted over separate optical fibers. the end Reasons for clear cable routing and the use of existing ones The ring line 7 for the transmission of the narrowband signals runs through cable routes proceeding from the control center 10 to a subscriber-near apron device VFE, from there to the first participant (not shown), from this back to the apron facility VFE, then from there to the second participant 2, from there back again and on the appropriate Over several participants until they are field setup VFE reached the receiver of the system located in the control center 10. The ring line thus includes the subscriber stations, of which only the subscriber station 2 and the Subscriber station 4 are indicated, in a star shape to the apron device VFE. The shown course of the light path within the apron device VFE is there through appropriate splice connections of the incoming and outgoing fiber optic cables achieved. The complete signaling is carried out via the transmission system with the ring line of the broadband communication system and also handled telephone operations.

The connections for the broadband signals are according to another Embodiment of the invention set up as follows: From the control center 10 leads a Optical fiber 11, via which the broadband signals for the to the front-end device connected subscribers in wavelength division multiplex are transmitted to the front-end facility VFE, arrives there on a wavelength demultiplexer 12, which distributes the broadband signals on subscriber-specific fiber optic cables L 2 and L 4 to the subscriber stations, of which the subscriber stations 2 and 4 are shown. This is where the broadband signals arrive on specially provided optical receivers BBE, which convert them into electrical multiplex signals then implement them in a manner that is not of interest here to the broadband Terminal devices (e.g. television receivers) are distributed.

If the subscriber station also has to send broadband signals, if if it is set up for video telephony, for example, the broadband signals in a manner not of interest here to a broadband transmitter BBS in the subscriber station out, which converts it into an optical signal and via a further subscriber-specific Sends fiber optic cable L2S to the apron facility. Holds in the apron a wavelength division multiplexer 13 the broadband signals sent by the subscriber stations into a wavelength division multiplexed optical output signal and transmits it via a single optical fiber 14 to the control center. If on a fiber optic cable, either in one or in the other direction of transmission between the control center 10 and the front-end device VFE not all broadband signals to be transmitted in the Wavelength division multiplex can be transmitted, so can for the transmission instead of one also several optical fibers, i.e. a combination of wavelength division multiplex and fiber multiplex can be provided.

The distance between the control center and the apron facility is typically 2 km, the subscriber stations weigh on average only about 100 m are removed from the apron facility. It can be shown that in the case of spatial Structure according to FIG. 3, a total of a shorter length of optical waveguides is necessary is than in a system in which each subscriber station has a star shape over each a fiber optic cable is connected to the control center. Another benefit of the The present new transmission system consists in its modular expandability.

It is true that all of the cables have to be laid for the final expansion maximum necessary fiber optic connections can be provided, however the installation of the transmission equipment was delayed until it was actually needed so that initially only low costs arise and the equipment effort is problem-free can be adapted to the respective existing communication needs.

Claims (5)

Claims 1. Optical communication system for digital transmission between a control center and a group of subscriber stations and vice versa, d u r c h e k e n n n z e i c h n e t that the subscriber stations (1, 2, 3, 4, 5, 6) are connected in series in an optical ring line (7), which is from a Transmitter (8) of the control center to a receiver (9) of the control center that leads the control center successively sends out information blocks (Fig. 2a) over the ring line (7), wherein the information blocks the address of a subscriber station, possibly messages for this subscriber station and constant light (KL) of a fixed duration, and that a subscriber station transmits its messages to the central office in that it modulates the constant light (KL) of the information block addressed to it (Fig. 2f) and forwards via the ring line (7). 2. System according to claim 1, characterized in that it is in a Broadband communication system in which the broadband signals and the narrowband signals Via separate fiber optic cables between a control center and a group of subscriber stations are transmitted, is used to transmit the narrowband signals that the Broadband signals from the control center (10) via one or more optical fibers (11) in wavelength division multiplex with subscriber-specific wavelengths to one Apron facility (VFE) and from there via subscriber-specific fiber optic cables (Z2E, L4E) are transmitted to the subscriber stations (2, 4), and that the broadband signals from the subscriber stations (2) via individual fiber optic cables (L2S) to the apron facility (VFE) and from there via one or more optical waveguides (14) in wavelength division multiplex to the control center (10). 3. System according to claim 1 or 2, characterized in that the Central in each information block the address of the subscriber station n times in a row sends out, where n is the number of subscriber stations in the loop that each subscriber station contains an optical switch that is in standby mode the incoming light from the ring line branches off the ring line and onto one Photoreceiver sets up and, - if the received address is a Information block is its own address, is operated so that it is after receipt of the message switches to continuity and then the constant light (KL) of this information block modulated with the message to be sent to the control center and onto the ring line forwards (Fig. 2f), and - if the received address of an information block is not its own address, it is operated so that after receiving the address immediately switches to continuity and then the rest of this information block unchanged forwards to the ring line (Fig. 2c). 4. System according to claim 3, characterized in that the optical Switches in every subscriber station are permanently switched to continuity in the event of a power failure is. 5. System according to claim 3 or 4, characterized in that the optical ring line (7) from the control center (10) to the apron facility (VFE), from there one after the other to the subscriber stations (2, 4) and back again to The apron facility (VFE) and from there back to the control center (10) in such a way that that the subscriber stations (2, 4) are connected in a star shape to the apron facility are.