JPH05130048A - Access control method in local area network system and its node equipment - Google Patents

Abstract

PURPOSE:To prevent the deterioration in communication quality by implementing access processing while not modifying an optical signal without use of optical electric conversion, allowing each node to receive only a required packet and not to receive an undesired packet but to pass through it. CONSTITUTION:Let number of accommodated nodes be 4, then address wavelengths lambda1-lambda4 of each node equipment 1 are allocated. Then a node requesting transmission of data to a node whose wavelength is lambda1 applies modulation to a light whose wavelength is lambda1 coming always to its own node and sends the result again to an optical fiber transmission line 31 as a data packet. On the other hand, each node receives a light with a wavelength specific to its own node coming to its own node while separating it into each carrier component. Thus, the node whose wavelength is lambda1 discriminates it that a node sending a data packet to its own node is a node whose wavelength is lambda3 by identifying the carrier component of the data packet reaching its own node.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an access control system in a loop type optical local area network (LAN) system and a node device in the loop type optical LAN system.

[0002]

2. Description of the Related Art Considering the case where the number of nodes accommodated in the system is four in the medium access system of the token passing system in the conventional loop type optical local area network (LAN), the address of each node is a 2-bit code. , And "0,0", "0,1", "1,0", "1," for each node as shown in FIG.
1 ”is assigned. The node which is going to send the data pulls the token packet into its own node, then writes the address code of the receiving node in the header part of the data packet and sends it. After that, the other nodes arrive. The address code in the header of the data packet is read, and if it matches the address of its own node, the data packet is received, and if it does not match, it is sent as it is. For more information on media access methods, see the magazine Proceed
ings of IEEE ", Vol. 77, 1988, 238-256.

A node device 20 for a loop type optical LAN system adopting the conventional token passing system.
As shown in FIG. 4, each of the node devices 2 comprises an opto-electric converter 8, an access processing circuit 11, and an electro-optical converter 21.
0 indicates that all optical signals received from the optical fiber transmission line 22 are converted into electrical signals by the opto-electric converter 8 and processed by the access processing circuit 11, and then converted into optical signals by the electro-optical converter 21 again. It was transmitted to the optical fiber transmission line 22.

[0004]

When the above-mentioned medium access system of the token passing system and the node device are adopted, all the optical signals sent by all the nodes are sent regardless of the transmission / reception request. After receiving and photoelectrically converting, access processing of the token passing system is performed by an electric circuit, and then electrical-optical conversion is performed and transmitted. For this reason, the token packet undergoes photoelectric conversion, access processing, and electro-optical conversion even at nodes that do not request transmission.
Similar to the token packet, the data packet undergoes the three processes of opto-electrical conversion, access processing, and electro-optical conversion in nodes other than the receiving node.

Therefore, when there are a large number of nodes requesting transmission, it takes a long time for a node to acquire a token packet, and the system loop deteriorates. In addition, when an optical signal packet passes through a node, jitter is generated by an electric circuit, and as the number of passed nodes increases, the amount of jitter increases and the bit error rate deteriorates. Therefore, the number of nodes that the LAN system can accommodate is limited. There are drawbacks. Furthermore, if a failure occurs in any of the opto-electric converter, electro-optic converter, or access processing path in a node, all optical signal packets cannot pass through that node, and one node fails. It also has the drawback of affecting the entire system.

[0006]

In order to solve the above-mentioned problems, the present invention provides the following system and apparatus. (1) A plurality of nodes to which unique optical wavelengths are given are connected by an optical fiber transmission line, and DC light having the specific optical wavelengths of the plurality of nodes is constantly transmitted on the optical fiber transmission line, Each of the plurality of nodes transmits the light that has been transmitted through the optical fiber transmission line as it is when there is no data transmission request, and when there is a data transmission request, the destination of the light that has arrived After modulating the wavelength component corresponding to the node with a predetermined signal, it is sent to the optical fiber transmission line, other wavelength components are transmitted as it is, and each of the plurality of nodes is given to the own node in advance. An access control method in a local area network system characterized in that when light of a certain wavelength arrives, it pulls it into its own node and receives it.

(2) A node device in a loop type optical local area network system in which a plurality of node devices to which respective unique optical wavelengths are given are connected in a ring shape by an optical fiber transmission line. And an optical demultiplexer that demultiplexes the unique optical wavelengths of the plurality of node devices, and an output of the demultiplexer that modulates each wavelength component other than the wavelength unique to the own node device. A plurality of arranged optical modulators, a laser device that oscillates at the peculiar optical wavelength, the outputs of the plurality of optical modulators and the laser device output light are multiplexed, and the output is transmitted to the optical fiber transmission line. A connected optical multiplexer, an opto-electric converter that converts a wavelength component unique to the node device of the output of the optical demultiplexer into an electric signal, and a modulation signal is supplied to each of the plurality of optical modulators. Access processing times When a node in the loop-type optical local area network system, comprising the apparatus.

(3) The modulation signal applied to the plurality of optical modulators is a signal obtained by modulating a carrier signal having a frequency unique to each node device with a data signal to be transmitted, and the opto-electric converter converts each carrier signal. The node device in the loop type optical local area network system according to (2), which has a function of receiving signal components separated from each other.

(4) The modulation signal applied to the plurality of optical modulators is converted into a CDMA code by using a code unique to each node as a data signal to be transmitted, and the opto-electric converter converts the data into C code.
A DMA decoder is provided (2)
A node device in the loop type optical local area network system according to claim 1.

(5) A node device in a bus-type optical local area network system in which a plurality of node devices to which respective unique optical wavelengths are given are connected in a bus shape by an optical fiber transmission line. An optical demultiplexer connected to the optical path for demultiplexing the optical wavelengths peculiar to the plurality of node devices, and each of the wavelength components other than the wavelength peculiar to the own node device among the outputs of the optical demultiplexers. A plurality of optical modulators arranged so as to combine the outputs of the plurality of optical modulators, the output of the optical multiplexer connected to the optical fiber transmission line, and the output of the optical demultiplexer A bus-type optical local area comprising an opto-electric converter for converting a wavelength component specific to the own node device into an electric signal and an access processing circuit for supplying a modulation signal to each of the plurality of optical modulators. network Node devices in a system.

(6) A modulation signal applied to the plurality of optical modulators is a signal obtained by modulating a carrier signal having a frequency unique to each node device with a data signal to be transmitted, and the opto-electric converter converts each carrier signal. The node device in the bus type optical local area network system according to (5), which has a function of separating and receiving the signal components from each other.

(7) The modulation signal applied to the plurality of optical modulators is converted into a CDMA code by using a code unique to each node as a data signal to be transmitted, and the opto-electric converter converts the modulated signal into C code.
It is equipped with a decoder for DMA (5)
A node device in the bus type optical local area network system described in 1.

As described above, in the present invention, photoelectric conversion is performed only when it is finally received by the destination node, and all optical signals other than the optical signal addressed to the own node are processed as they are, Send again. Therefore, the problem that occurs when the electric signal is once converted does not occur.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an operation principle diagram showing an access control system in a loop type optical local area network (LAN) system of the present invention, and FIG. 3 shows a first embodiment of an optical LAN system using a node device of the present invention. It is a figure.

An access control system in the loop type optical LAN system of the present invention will be described with reference to FIG. Here, as an example, the number of accommodated nodes is 4, and λ ₁ to λ ₄ are assigned as the address wavelength of each node device 1.

Each node always sends out the CW light of the wavelength assigned to itself to the optical fiber transmission line 31.
In FIG. 1, as an example, the case of transmitting from the node of λ _{3 to} the node of λ ₁ is shown. The node requesting to send data to the node of λ ₁ (here, the node of λ ₃ ) is
The light of the wavelength λ ₁ that always arrives at the own node is modulated, and the data packet is sent again to the optical fiber transmission line 31. The modulation signal used at this time is a sine wave of frequencies f _{1 to} f ₄ assigned to each node as a carrier, which is modulated with a data signal to be transmitted.

On the other hand, at each node, the wavelength light peculiar to the own node, which arrives at the own node, is separated into respective carrier components (f _{1 to} f ₄ ) and received. Therefore, by identifying that the carrier component of the data packet arriving at the node of λ ₁ is f ₃ , it can be seen that the node that sent the data packet to itself is the node of λ ₃ .

Next, a first embodiment of the node device according to the present invention will be described with reference to FIG. The wavelength division multiplexed light (λ ₁ , λ ₂ , λ ₃ , λ ₄ ) arriving at the node device 1 is first divided into respective wavelength components by the optical demultiplexer 301. The structure and principle of the optical demultiplexer 301 are described in, for example, "Coherent Optical Communication Engineering" by Ohkoshi and Kikuchi (Ohmsha, 1989). Also, as the optical multiplexer 305,
The same optical demultiplexer 301 is used with the input and output reversed. Of the outputs of the optical demultiplexer 301, the wavelength lights of λ ₁ , λ ₂ and λ ₄ are respectively the _first , _second and third optical intensity modulators 302 and 3
03 and 304 are input. Wavelength λ of interest here
_Since the node ₃ has a transmission request to the node of wavelength λ ₁ , the first optical intensity modulator 302 is driven by the signal obtained by modulating the carrier of frequency f _{3 with} the data to be transmitted. , Modulates light of wavelength λ ₁ . The second and third light intensity modulators 303 and 304 are not driven, and light of wavelengths λ ₂ and λ ₄ is let through. First, second and third light intensity modulators 302, 3
The outputs of 03 and 304 are combined with the CW light which is the output of the semiconductor laser 306 that oscillates at the wavelength λ ₃ by the optical combiner 305 and sent out again to the optical fiber transmission line 31.

Of the output of the optical demultiplexer 301, the light of wavelength λ ₃ is converted into an electric signal by the opto-electric converter 307, and then the band pass filter 30 having the center frequencies f ₁ , f ₂ , f _4.
8, 309 and 310 are input. Bandpass filter 3
The access processing circuit 311 monitoring the outputs of 08, 309, and 310 can recognize the transmission source of the data depending on which filter the data is detected from.

Next, a second embodiment of the node device according to the present invention will be described with reference to FIG. Here, only the differences from the first embodiment shown in FIG. 3 will be described. Further, as in the first embodiment, it is assumed that a transmission request is made from the node of λ _{3 to} the node of λ ₁ . Optical demultiplexer 30
Only the light of wavelength λ ₁ out of the output of ₁ is the light intensity modulator 3
The access processing circuit 311 uses a signal CDMA-encoded by a code peculiar to the node of λ ₃ as a modulation symbol at this time.

Meanwhile, the signal addressed to lambda ₃ of the node, after the output of the wavelength lambda ₃ of the optical demultiplexer 301 and an optical-electrical conversion, CDMA
The decoder 312 decodes it into a signal corresponding to each code and inputs it to the access processing circuit 311. Since the code and the node using the code have a one-to-one correspondence, the transmission source node of the data can be known from the code of the transmitted data.

Next, a third embodiment of the node device according to the present invention will be described with reference to FIG. In this embodiment, the DC light having the light wavelength peculiar to each node is supplied from the wavelength multiplex light sources 60 and 601 which are composed of four laser devices having different wavelengths. The wavelength-division-multiplexed lights output from the wavelength-division-multiplexed light sources 60 and 601 are respectively the nodes λ ₁ to λ ₄
Through the nodes λ ₄ to λ ₁ . Each node extracts and receives only the wavelength light peculiar to its own node among the wavelength-multiplexed light that has arrived. In addition, at the node that is requesting transmission, of the demultiplexed wavelength division multiplexed light, the light of the wavelength corresponding to the destination node is modulated with transmission data and then multiplexed with other wavelength light, and then It is sent again on the transmission path. In the above-mentioned modulation, the frequencies (f _{1 to} f ₄ ) peculiar to each node are used as carriers as in the first embodiment, and this is modulated with transmission data to obtain signals as modulated signals. In this embodiment, within one node, the node shown in the first embodiment is down (signal from node λ ₁ to node λ ₄ ) and up (signal from node λ ₄ to node λ ₁ ).
2 systems are prepared. Further, unlike the first embodiment, a laser device for sending DC light is not required in each node.
Further, in this embodiment, since all the required laser devices are integrated in two places, there is an advantage that the oscillation frequency interval of the laser device can be easily controlled.

[0023]

As described above, the access control method and the node device in the loop type optical local area network system of the present invention perform the access processing with the optical signal as it is without performing the photoelectric conversion. Since only necessary packets are pulled into the node and unnecessary packets are passed through without being pulled in, the time from when the packet leaves the sending node to when it arrives at the receiving node is shorter than in the conventional token loop optical LAN. The system loop is improved. Further, since the electric circuit does not generate jitter when the packet passes through the node, there is no limitation on the number of nodes accommodated in the system, which causes deterioration of transmission characteristics due to the jitter. Furthermore, even if a failure occurs in the node, the failure in the node does not spread to the entire system as long as the optical modulator operates normally.

Further, according to the present invention, even when a plurality of data packets are simultaneously sent to a certain node, they can be received at the same time without causing them to collide.

[Brief description of drawings]

FIG. 1 is an operation principle diagram showing an access control method in a loop type optical local area network system.

FIG. 2 is a diagram showing a token packet and a data packet.

FIG. 3 is a diagram showing an optical LAN system using a first embodiment of a node device according to the present invention.

FIG. 4 is a configuration diagram of an optical LAN system using a conventional node device.

FIG. 5 is a diagram showing an optical LAN system using a second embodiment of the node device according to the present invention.

FIG. 6 is a diagram showing an optical LAN system using a third embodiment of the node device according to the present invention.

[Explanation of symbols]

 1,20 Node device 2 Token packet 3 Data packet 31 Optical fiber transmission line 8,307 Optical-electrical converter 21 Electro-optical converter 11,311 Access processing circuit 301 Optical demultiplexer 302,303,304 Optical modulator 305 Optical multiplexing 306 Semiconductor lasers 308, 309, 310 Band pass filter 312 CDMA decoder

Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location 9077-5K H04L 11/00 330

Claims (7)

[Claims] 1. A specific light wavelength is given to each.
A plurality of nodes are connected by an optical fiber transmission line,
The optical wavelengths peculiar to the nodes are
DC light is constantly transmitted and transmitted through the optical fiber transmission line
Each of the plurality of nodes has no data transmission request.
In the case of transmission, the transmitted light is transmitted as it is, and a data transmission request is made.
If there is, it corresponds to the destination node of the incoming light
After modulating the wavelength component to be modulated with a predetermined signal,
It is sent to the fiber transmission line and other wavelength components are directly transmitted.
Furthermore, each of the plurality of nodes has its own node
When a light of a given wavelength arrives, it will
Local E-mail characterized by being pulled in and received
Access control method in network system. 2. A node device in a loop type optical local area network system in which a plurality of node devices each provided with a unique optical wavelength are connected in a ring shape by an optical fiber transmission line. An optical demultiplexer that is connected and demultiplexes the unique optical wavelengths of the plurality of node devices, and is arranged to modulate each wavelength component of the output of the demultiplexer other than the wavelength unique to the own node device. Multiple optical modulators, a laser device that oscillates at the specific optical wavelength, the outputs of the multiple optical modulators and the laser device output light are combined, and the outputs are connected to the optical fiber transmission line. An optical multiplexer, an opto-electric converter that converts a wavelength component specific to the own node device of the output of the optical demultiplexer into an electric signal, and an access that supplies a modulation signal to each of the plurality of optical modulators Processing circuit And a node device in a loop-type optical local area network system. 3. A modulation signal applied to the plurality of optical modulators is a signal obtained by modulating a carrier signal having a frequency unique to each node device with a data signal to be transmitted, and the opto-electric converter converts each carrier signal. The node device in the loop type optical local area network system according to claim 2, wherein the node device has a function of receiving the components separately from each other. 4. The modulation signal applied to the plurality of optical modulators is a CDMA code using a code unique to each node as a data signal to be transmitted, and the opto-electric converter is a CDM.
The node device in a loop type optical local area network system according to claim 2, further comprising an A decoder. 5. A node device in a bus-type optical local area network system in which a plurality of node devices each provided with a unique optical wavelength are connected in a bus shape by an optical fiber transmission line. Connected to the optical demultiplexer for demultiplexing the optical wavelengths peculiar to the plurality of node devices, and for modulating each of the wavelength components other than the wavelength peculiar to the own node device among the outputs of the optical demultiplexer. A plurality of optical modulators arranged in an appropriate manner, an optical multiplexer that multiplexes the outputs of the plurality of optical modulators, and the output is connected to the optical fiber transmission line; and an output of the optical demultiplexer, A bus type optical local area network comprising an opto-electric converter for converting a wavelength component specific to the own node device into an electric signal and an access processing circuit for supplying a modulation signal to each of the plurality of optical modulators. Shi Node device in Temu. 6. A modulation signal applied to the plurality of optical modulators is a signal obtained by modulating a carrier signal having a frequency unique to each node device with a data signal to be transmitted, and the opto-electric converter converts each carrier signal. The node device in a bus type optical local area network system according to claim 5, wherein the node device has a function of receiving the components separately from each other. 7. A modulation signal applied to the plurality of optical modulators is a CDMA code using a code unique to each node as a data signal to be transmitted, and the opto-electrical converter is a CDM.
The node device in the bus type optical local area network system according to claim 5, further comprising an A decoder.