FI70353C - LOCAL DATA NETWORK WITH ET FLERTAL STATIONER - Google Patents

Description

70353

Multi-station local area network -Local data network with a stationary station

The invention relates to a multi-station local data network in which an optical cable is used as a transmission line and in which there are at least two interconnected bidirectional multi-point lines to which the stations of the network are connected.

A previously known data network based on the use of an optical cable is disclosed in DE patent 2400491. The data network is a star network in which the branches are performed by means of a passive, light-transmitting, optical splitter. A separate fiber optic cable is brought from each station to the end of the splitter. Correspondingly, a separate optical cable is routed to each station from the other end of the splitter. Such a network structure is characterized in that the attenuation of the transmission connection is small. However, the amount of fiber optic cable required is large, which results in high cabling costs. Because a free connection point is required in the star splitter for each new station, it is difficult to expand the star grid unless the star splitter is oversized.

Other previously known data network structures based on the use of optical cable have been presented e.g. G. Vtfinzer and H.

Witte in the article "Comparison of Fiber-Optic Data Bus Networks", Siemens Forsch.- u. Entwickl.-Ber. Bd 10 (1981)

No. 1, pp. 9 - 15, Terrence L. Casto in "The Data Bus Goes Fiber Optic," Optical Spectra, Sept. 1980 pp. 48-54 and Larry L. Campbell in "Fiber Optics for Telecommunications", Microwave Journal, Vol. 7, July 1979, pp. 24, 26, 30, 32, 34, 84. A data network can be a straight multipoint line or it can be connected as a loop. In a multipoint network, each station is connected separately to optical cables that circulate the stations in the network, which may be one or more, by means of passive, light-transmitting, optical splitters. Such a network structure is characterized by a small amount of optical cable required. Network expansion is easy to accomplish by connecting an optical splitter to the arbitrary 70353 2-point optical cabinet for a new station. However, the attenuation of the network is high because each splitter takes up some of the light output and the splitters are connected in series. When the transmission distances are not long (e.g., the data network of a factory or office building), the attenuation of the optical cable is small in the total attenuation of the transmission connection. In this case, the attenuation of the transmission link is almost exclusively dependent on the number of branches, i.e. stations.

Branching can also be performed electronically as Eric G. Rawson and Robert M. Metcalfe have presented in the article “Fibernet: Multimode Optical Fibers for Local Computer

Networks ", IEEE Transactions on Communications, Vol. COM-26,

Well. 7, July 1978, pp. 981-990. The light signal coming to the branch is converted into an electrical signal at the receiver part of the branch, after which it is amplified, directed to the station and the transmitter part of the branch, where it and the electrical signals transmitted by the station are converted back to light signals and sent to the next branch. The attenuation of a transmission link in a multipoint network with electrical splitters is small because the signal is amplified by each splitter. However, the network is more unreliable than networks based on the passive, optical branching method.

The data network structure according to the invention provides significant improvements to the above-mentioned drawbacks. To achieve this, the data network structure according to the invention is characterized in that the network comprises at least two bi-directional multipoint lines, in which light signal transmission in different directions is implemented in different optical fibers and network stations are connected by connecting transmitters of stations to be connected to each multipoint. one of the two optical fibers 4a, 4b in the multipoint line, which are connected by means of a passive, light-transmitting optical splitter 11 to the other two optical fibers 5a, 5b in the multipoint line, to which the receivers of the multiplexed stations , as well as a connecting line connecting multipoint lines, where the transmission of the light signal in different directions is realized in different optical fibers, which are connected to the multipoint lines by optical fiber and passive, light-transmitting, optical branches. by means that the transmitters of the stations of each multi-point line connecting the two optical fibers 4a, 4b are connected to the two optical fibers 5a, 5b connecting the receiver of the stations of all other multi-point lines.

The data network according to the invention has the same characteristics as a passive star network and a passive multipoint network. The amount of optical cable required in the data network according to the invention is small, it is slightly larger than in the multi-point network but considerably smaller than in the star network. Network extensibility is good; the new station can be connected to the network in the same way as in a multipoint network. In the data network according to the invention, the attenuation of the transmission connection is significantly lower than in the multipoint network, which makes it possible to connect several stations to the network without repeaters.

For example, when the number of stations in the network is 12, the light signal in a multipoint network has to pass through a 10 to 12 optical splitter in the worst case, depending on the structure of the network, which attenuates the light signal to a very small size. In the data network according to the invention, the light signal has to pass through only 6 optical splitters in the worst case, whereby its level is considerably higher compared to the previous case.

The invention will now be described in detail with reference to the accompanying drawings, in which Fig. 1 shows the structure of a data network according to the invention, Fig. 2 shows the structure of a multipoint line belonging to a data network according to the invention, Fig. 3 shows the structure of a data network connection line.

Figure 1 shows the structure of a data network according to the invention. The number of stations A in the network is 12, but it can be larger or smaller. The network consists of two or more bidirectional multipoint lines to which the stations of the network are connected so that the number of stations in each multipoint station is approximately equal. Figure 1 shows the structure of the network when the number of multipoint lines 1, 2 is two. The multipoint lines are connected to each other by means of a connecting line 3. Distribution of the light signal received by the network station V when the leftmost transmitter station L is in operation, is in Figure 1 shown in an arrow.

Figure 2 shows the structure of a multipoint line. The multipoint line is a two-way line. Light signals transmitted in different directions are transmitted in different optical fibers. Passive in a multi-point line, based on light power distribution, translucent. the branch 11 is placed as centered as possible in the multipoint line, so that the number of stations remaining on both sides of it is approximately equal. The transmitter of the station furthest to the left of the branch 11 is connected to one of the input ports of the branch 11 by means of an optical cable 4a. The transmitters of the other stations to the left of the splitter 11 are connected to the same optical cable 4a by means of passive optical splitters 7, 9. The splitter 9, by means of which the transmitter of the station closest to the splitter 11 is connected to the optical cable 4a, has two input ports and at least two output ports. One input port and one output port 12a are reserved for the optical cable 4a. One of the input ports is reserved for that transmitter. The transmitters of the other stations are connected to the optical cable 4a by means of splitters 7. The branch 7 has two input ports and one output port, of which one input port and one output port are reserved for the optical cable 4a and the other of the input ports for the transmitter connection. The transmitters are connected to the junctions using short sections of optical cable.

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The transmitters of the stations on the right side of the branch 11 are connected to the optical cable 4b in the same way.

The branch 11 has two input ports to which the optical cables 4a, 4b are connected. The light power entering the branch is distributed according to the branching ratio, which is usually 1: 1, to the optical cables 5a, 5b in the output ports.

The optical cable 5a from the branch 11 is connected to the receiver of the station on the far left. The connection from the optical cable 5a to the receivers of the other stations is made by means of passive optical splitters 8, 10. The connection from the optical cable 5a to the receiver of the station closest to the branch 11 is made by means of at least a four-port branch 10. One input port 13a and one output port are reserved for the optical cable 5a and one of the output ports for the station receiver. The optical cable 5a is connected to the receivers of other stations by means of three-port splitters 8. The input port of the branch 8 and one of the output ports is reserved for the optical cable 5a and the other of the output ports for the station receiver. The receivers of the stations on the right side of the branch 11 are connected to the optical cable 5b in the same way.

Some of the stations in the network may be structured in such a way that they can only receive light signals moving in the network (station M in Figure 2). In this case, it is sufficient for them to be connected to the optical cable 5a or 5b (in Fig. 2 to the optical cable 5a) by means of a passive optical splitter 8. There may also be stations in the network that can only transmit light signals (station N in Figure 2). In this case, it is sufficient for them to be connected to the optical cable 4a or 4b (in Fig. 2 to the optical cable 4b) by means of a passive optical splitter 7.

Figure 3 shows the structure of the connecting line 3. The connecting line 3 consists of optical cables 6a, 6b connecting three-point lines, three-port, passive, optical splitters 16a, 16b, 17a, 17b and short optical cables 14, 15.

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Figure 3 also shows, for the sake of clarity, the junctions of the multi-point lines 1,2 and the stations located closest to the junctions 11.

The input ports of the branch 16a are connected to the output ports 12b of the branches 9 in the multipoint line 1 by short optical cables 14. The optical cable 6a from the output port of the branch 16a is connected to the input port of the branch 17a near the second multipoint line 2. The short optical cables 15 from the output ports of the branch 17a are connected to the input ports 13b of the branch branches 10. The transmission connection from the multipoint line 2 to the multipoint line 1 is carried out in the same way by means of the taps 16b, 17b and the optical cables 14, 6b, .15.

The connecting line 3 can also be implemented by replacing the splitters 16a, 17a and the optical cable 6a with one at least four-port (2 input and 2 output ports), passive, optical splitter, to the input ports of which the optical cables 14 and the output ports of the optical cables 15 are connected. In the same way, the splitters 16b, 17b and the optical cable 6b can also be replaced by one at least four-port, passive, optical splitter.

The monofilament optical cables 6a, 6b can be replaced by a single optical fiber containing two optical fibers. In the same way, a monofilament fiber optic cable can be made. 4a, 5a and light games 4b, 5b.

The transmitters mentioned in the description generally include an electrically implemented light source controller as well as a light source, which may be an LED or a laser diode. Receivers generally include a light emitting diode, which may be a PIN diode or an APD diode, and an electrically implemented amplifier.

When the number of stations is large, repeaters not mentioned in the description may also be needed on the network. Typically, a repeater consists of a receiver, an amplifier, and a transmitter. The light signal coming into the receiver is converted into an electrical signal, after which it is amplified. The amplified electrical signal controls a light source located at the transmitter, which converts the electrical signal back into a light signal.

Both digital and analog signals can be transmitted in the data network according to the invention. A network station can be, for example, a video transmitter or receiver, a computer terminal, a line printer, etc. The transmitter of each station has a direct transmission connection to all receivers in the network. Multiple signals can be transmitted simultaneously in a network using time division multiplexing, frequency division multiplexing, or wavelength division multiplexing. If wavelength division multiplexing is used, the stations have their own light source placed on the transmitters and the receivers have their own light emitting diode for each wavelength. In this case, a wavelength multiplexer is also required for the transmitter and a wavelength demultiplexer for the receiver.

Claims (2)

70353 A multi-station local area network using optical fibers as a transmission line and having at least two interconnected bidirectional multipoint lines (1, 2) to which network stations (A) are connected and in which the transmission of a light signal in different directions is performed in different optical fibers (4a, 5a; 4b, 5b) and to which the stations of the network are connected by connecting the transmitters (L) of the stations to be connected to each multipoint line by means of passive, light-transmitting optical splitters (7, 9) to one of the two fiber optics (4a, 4b) in the multi-point line. (11) to two other optical fibers (5a, 5b) in the multipoint line, to which the receivers (V) of the stations to be connected to the multipoint line are connected by passive, light-transmitting optical splitters (8, 10), and in the light signal connecting line (3) transmission in different directions is carried out in different optical fibers (6a, 6b), characterized in that the optical fibers (6a, 6b) of the connecting line (3) are connected to a multi-point line (1, 2) of optical fibers (14, 15) and two passive light-transmitting optical splitters (16a, 17b) for each multi-point line; 17a, 16b) so that the transmitters (L) of the stations (A) of each multi-point line connecting the two optical fibers (4a, 4b) are connected to the two optical fibers (5a, 5b) connecting the receivers (V) of the stations (V) of the other multi-point lines. Data network according to claim 1, characterized in that the network comprises two bi-directional multipoint lines connected by a connecting line such that the two optical fibers (4a, 4b) connecting the transmitters of the second multipoint line are connected to the two optical fibers (5a) connecting the receivers of the second multipoint line. 5b) by means of optical splitters (9), optical fibers (14), optical splitter, optical fibers (15) and optical splitters (10).