JPH0472939A - Packet exchange using optical switch - Google Patents

Abstract

PURPOSE:To avoid fluctuation of a DC level and malfunction of an AGC amplifier by using a dummy data addition circuit when a data to be sent is not in existence so as to send the dummy data in which 0 or 1 bit pattern is not consecutive for a prescribed time or over. CONSTITUTION:When a data to be sent is not in existence, dummy data addition circuits 102, 112 are controlled to add a dummy data. The dummy data added by the dummy data addition circuit has a bit pattern in which number of Os and 1s is the same and consists of a bit pattern in which Os or 1s are not consecutive for a prescribed time or over. Malfunction such as DC level fluctuation or amplification of a noise component is avoided and missing in the transmission data is eliminated by inputting the signal as above to photoelectric converters 104, 114.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a method for preventing loss of exchanged data in a packet switching device, particularly in a packet switching device using an optical switch.

[Prior Art 1] Various packet switching methods and devices have been known in the past, and Japanese Patent Laid-Open No. 1238248 discloses a switching device that uses an optical switch as a switching means. This uses a space-divided optical switch as a switching stage, and its input/output section includes an electrical/optical converter and an optical/electrical exchanger. In such a configuration, the optical/electrical exchanger generally has an AC coupling circuit configuration, and the level of 1 or O continues for a certain period of time, but if there is a time when there is no data to be exchanged, That data or the data immediately following it will be missing. [Problems to be Solved by the Invention] In the conventional circuit described above, when transmitting packet data from the transmitting side to a certain station on the receiving side, if there is no data to be transmitted, one packet of 0 or 1 is transmitted. It will continue for a period of time corresponding to the length. When a continuous O or 1 signal is input to the receiving optical/electrical converter for a certain period of time or more, the received data is lost as shown by the signal waveform 310 at the optical/electrical converter output 305 in FIG. arise. The reason for the above omission is that the preamplifier 603 and AGC amplifier 604 are AC-coupled amplifier circuits, and the third
In the section 307 with no data in the figure, as shown in the signal waveform 309 of the optical/electrical conversion analog signal 303, the DC level of the received signal changes or the noise component is greatly amplified by the AGC amplifier 604. As a result, the data immediately following the part where no packet data exists is lost. As described above, the conventional circuit has a problem in that when there is no packet data to be transmitted, part of the data immediately after it is lost. An object of the present invention is to prevent a dropout from occurring in immediately subsequent transmission data even when there is no packet data to be transmitted.

[Means to solve the problem]

In order to achieve the above objective, a dummy data addition circuit is provided between the transmission buffer and the electrical/optical converter on the transmission side, and the contention determination circuit between stations (channels) ensures that there is no packet data to be transmitted. If detected,
By sending dummy data to the receiving side, data loss is prevented. The added dummy data shall be a pattern consisting of at least one bit of 0 and the same number of 1s, and shall be either 0 or 1.
is configured so that it does not continue for more than a certain period of time. Furthermore, a specific code is added to the added dummy data so that it can be determined as dummy data. On the other hand, the receiving side is provided with a dummy data removal circuit for identifying and removing dummy data, and receives only necessary packet data.

[Effect]

A packet switching device using an optical switch of the present invention transmits dummy data to intervals where there is no transmission data using a dummy data adding circuit provided on the transmitting side, and a dummy data removing circuit provided on the receiving side. By operating to remove the added dummy data, the time when there is no transmission data or zero
Alternatively, 1s will not continue for more than a certain period of time, and malfunctions such as data loss in the optical/electrical converter will no longer occur. Destination station (channel) from the contents of multiple transmit buffers
When the contention judgment circuit that selects and determines detects that there is no packet data to be transmitted, the dummy data adding circuit provided on the transmitting side outputs dummy data having a code indicating that it is dummy data. Operate. At this time, the bit pattern of the dummy data to be added is 0 or 1, as shown by data 209 in FIG.
is data that does not continue for more than a certain period of time. This dummy data passes through the electrical/optical converter and a replacement optical switch and is input to the optical/electrical converter. In this way, even if there is no data to send,
By transmitting dummy data in which 0 or l does not continue for a certain period of time. Malfunctions such as fluctuations in the DC level such as in the analog signal waveform 309 of the optical/electrical converter and amplification of only noise components by the AGC amplifier 604 are eliminated. On the other hand, when the dummy data removing circuit on the receiving side detects a code indicating dummy data from among the received data including dummy data added by the dummy data adding circuit on the transmitting side, it removes the dummy data. , operates to store only necessary packet data in the receiving buffer. By providing a dummy data adding circuit and a dummy data removing circuit that operate in this manner on the transmitting side and the receiving side, respectively, it is possible to prevent packet data from being lost in a switching device using an optical switch.

【Example】

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of an embodiment of a switching device using an optical switch, which has a dummy data addition circuit and a dummy data removal circuit according to the present invention. FIG. 1 is a diagram showing a case where there are two stations (channels) on the transmitting side and two stations (channels) on the receiving side, where transmission data A is stored in the transmission buffer 101 and transmission data B is stored in the transmission buffer 111. . The transmission data A and B are subjected to destination identification and competition determination by the competition determination circuit 109, and the optical switch drive circuit 110 switches the optical switch 100, which is an exchange means, to transmit the data to the receiving section. Get D. The conflict determination circuit 109 refers to the data in the transmission buffers 101 and 111 to determine a conflict, and if there is no data to be transmitted, the dummy data addition circuits 102 and 11
Dummy data is added by controlling 2. The packet data that has passed through the dummy data addition circuit or the dummy data added by the dummy data addition circuit is converted into serial data by a parallel/serial conversion circuit 103.113 and input to an electrical/optical converter 104.114. The electrical/optical converters 104 and 114 convert the serial data to be transmitted into optical signals, perform an exchange operation using an optical switch 1°O, and are connected to the receiving station 1 or 2. Alternatively, it is input to 115 as an optical signal. On the other hand, in the receiving section, the optical/electrical converters 105 and 115 convert the optical signal into an electrical signal, and the serial/parallel converter circuit 10 converts the optical signal into an electrical signal.
6 and 116, the added dummy data is deleted by dummy data removal circuits 107 and 117, and only necessary packet data is stored in the reception buffer 108 or 118. Generally, data used in a switching device is packetized as shown in FIG. 4, and a plurality of packet data 401 to 404 are transmitted in time series. One packet data includes header information 407 and data 4
08, and the header information 407 is composed of forward light information 409 and header attribute information 410. The competition determination circuit 109 identifies the optical information 409 and determines to which station the data is to be sent. Furthermore, when a plurality of transmitting stations simultaneously send data to one receiving station, the contention is checked and it is determined which transmitted data should be output first. For example, suppose that when transmitting stations 1 and 2 both try to transmit data to receiving station 1, the optical switch is set so that the data of transmitting station 1 is sent to receiving station 1 first as a result of the competition determination. At this time, there is no data to be transmitted to the receiving station 2. Therefore, the conflict determination circuit 109 uses the dummy data addition circuit 1
12 to output dummy packet data. Furthermore, the conflict determination circuit includes the optical switch drive circuit 1.
10, the optical switch 100 controls to connect the transmitting station 2 and the receiving station 2, and transmits the data of the transmitting station 1 to the receiving station 1 and the dummy data of the transmitting station 2 to the receiving station 2, respectively. FIG. 3 is a diagram showing a data waveform when dummy data is not added. Here, data 301 passing through the optical switch indicates that there is a section 307 in which no data exists between data 306 and data 308, and a signal such as the input waveform 302 of the electrical/optical conversion circuit is converted into light. Convert and send. The above signal passes through an optical switch and is input to an optical/electrical converter on the receiving side, which converts the optical signal into an electrical signal. Here, the analog signal 303 inside the optical/electrical converter has a waveform like 309 in a section where no data exists. The optical/electrical conversion analog signal 303 is binarized by a threshold level 311 and sampled by a clock signal 304 to obtain an optical/electrical conversion signal 305. Here, since the signal 309 in the section where no data exists is one in which O or 1 continues for more than a certain period of time, its DC level fluctuates and noise components are amplified.
The data becomes uncertain in the part 310, resulting in a dropout. This is because the preamplifier or AGC amplifier of the optical/electrical converter described below has an AC coupling circuit configuration. FIG. 6 is a diagram showing the circuit configuration of the optical/electrical converter. The optical signal 600 is connected by an optical fiber 601, converted into an electrical signal by a photodetector 602, and then sent to a preamplifier 603,
The signal is amplified by an AGC amplifier 604 and a main amplifier 605, binarized by a comparator 607, and then output as a digital signal. In the above circuit, the preamplifier 603 and the AGC amplifier 6
Since 04 is an amplification circuit using AC coupling, if 1 or O is continuously input for a certain period of time or more, the DC level of the signal changes, and the converter 11 = -ta 607 obtains a correct binary signal. I can't. Also, if 1 or O are consecutive as above,
The AGC amplifier 604 also does not operate correctly, and only the noise component is greatly amplified. Therefore, in the section 307 where no data exists, the optical/electrical conversion analog signal has a waveform like 309, resulting in data loss 310. FIG. 2 is a diagram showing signal waveforms in a switching device having a dummy data addition circuit. The dummy data added by the dummy data addition circuit has a bit pattern in which the number of 0s and 1s is the same, as shown in the signal waveform 209, and is composed of a pattern of 1 to 1 in which O's or 1's do not continue for a certain period of time. are doing. By inputting such a signal to the optical/electrical converter, malfunctions such as fluctuations in the DC level and amplification of noise components as shown in FIG. No more missing data. FIG. 5 is an example diagram in which packet data is transmitted from two transmitting stations to two receiving stations. H1 and H2 represent receiving station numbers, and packet data 501 and the like are transmitted to receiving station 1, and packet data 502 and the like are transmitted to receiving station 2, respectively. Each transmitting station data undergoes a conflict determination circuit, and the packet data 510 of receiving stations 1 and 2 is determined by a conflict determination circuit.
．． The data shown in 511 is transmitted. Here, the data 503, 504, and 505 are dummy data added because there was no data to be transmitted as a result of the conflict determination. FIG. 7 is a diagram showing an example of packet data. The packet data is composed of header information consisting of information 702 indicating the destination, that is, the connection destination of the optical switch, a flag 701 indicating whether the data is dummy data, and data information 703. As the bit pattern used as dummy data, a bit pattern that is impossible in the system is used as header information, or a flag indicating that it is dummy data is added to the header information. For example, when the flag 701 indicating whether or not the packet is dummy data is 0, it is assumed to be correct packet information, and when it is 1, it is assumed to be dummy data. The dummy data removal circuits 107 and 117 on the receiving side detect this impossible bit pattern or set the flag 701.
, to control whether or not to store packet data in the receive buffer.

【Effect of the invention】

According to the present invention, in a switching device using an optical switch, when there is no data to be transmitted, the dummy data adding circuit of the transmitting section creates a dummy data in which the bit pattern of O or 1 does not continue for more than a certain period of time. By transmitting data, it is possible to eliminate fluctuations in the DC level and malfunctions of the AGC amplifier in the optical/electrical converter of the receiving section. Further, since the dummy data removal circuit of the receiving section removes the dummy data added by the transmitting section, only necessary packet data can be received. As described above, by providing a dummy data adding circuit in the transmitting section and a dummy data removing circuit in the receiving section, in a packet switching device using an optical switch, when there is no transmitted data, the data that occurs immediately after that This has the effect of being able to prevent omissions.

[Brief explanation of the drawing]

Fig. 1 is a block diagram of a packet switching device using an optical switch which is an embodiment of the present invention, Fig. 2 is a signal waveform diagram when dummy data is added, and Fig. 3 is a diagram of signal waveforms when dummy data is not added. Signal waveform diagram, Figure 4 is a configuration diagram of packet data in the switching device, Figure 5 is one side port when packet data is transmitted to two transmitting/receiving stations, and Figure 6 is a circuit configuration diagram of an optical/electrical converter. , FIG. 7 is a diagram showing a configuration of packet data in a switching device using an optical switch. Explanation of symbols

Claims (1)

[Claims] 1. A plurality of transmitting devices each including a transmission buffer means, a parallel/serial conversion means, and an electrical/optical conversion means, an exchange destination conflict determination means for controlling an exchange destination, and an optical/electric A dummy device for adding dummy data when there is no data to be transmitted in a device that uses an optical switch to exchange data between a plurality of receiving devices each including a converting means, a serial/parallel converting means, and a receiving buffer means. A data addition circuit is provided between the transmission buffer means and the parallel/serial conversion means, and a circuit for removing the dummy data is provided between the serial/parallel conversion means and the reception buffer means. A packet switching device using an optical switch. 2. A dummy data generation circuit is provided which has a function of generating dummy data when it is determined that there is no data to be transmitted in the exchange destination conflict determination means that controls the exchange destinations of a plurality of transmitting devices. A packet switching device using the optical switch according to claim 1. 3. A packet switching device using an optical switch according to claim 1, further comprising a dummy data adding circuit configured to output dummy data to unselected stations (channels). 4. A packet switching device using an optical switch according to claim 1, further comprising a dummy data adding circuit having a function of generating at least one bit of 0 and the same number of 1 bits as a dummy data pattern. 5. A packet switching device using an optical switch according to claim 1, further comprising a dummy data addition circuit that generates data as dummy data so that more than a certain number of 0's or 1's are not consecutive. 6. The packet switching device using an optical switch according to claim 1, wherein the bit pattern used for the dummy data is a pattern that is impossible in the system. 7. The switching device using an optical switch according to claim 1, wherein the dummy data has a data pattern having a code indicating that the data is dummy data.