JP3304026B2 - Wavelength division type optical communication path - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wavelength division type optical communication path for exchanging wavelength multiplexed optical signals. In particular,
The present invention relates to a wavelength division type optical communication path having a transmission / reception function for an input / output optical highway.

[0002]

2. Description of the Related Art FIG. 6 shows a first configuration example of a conventional wavelength division type optical communication path. In this configuration, the number of input / output optical highways N ₁ = 3, the number of wavelength multiplexes M = 4, and the number of input / output links N ₂ ×
The case where M = 8 is shown. Also, each signal channel is assumed to be connected with the same wavelength.

In the figure, three input optical highways 10
-1 to 10-3 each have a maximum of four waves (wavelengths λ ₁ to
The optical signal of λ ₄ ) is wavelength-multiplexed as a signal channel. Optical signals input from each input optical highway are separated into respective wavelengths by the corresponding optical demultiplexers 12-1 to 12-3, and the corresponding four-input / five-output optical switches 31 are provided.
-1 to 31-3. The four-input and five-output optical switches 31-1 to 31-3 correspond to the input signal channels to the output ports a, b, and c corresponding to the output optical highways 11-1 to 11-3 or the optical signal receiving unit 33, respectively. To output ports d and e. The optical signals output from the output ports a, b, and c of the four-input, five-output optical switches 31-1 to 31-3 are respectively output by optical couplers 32-1 to 32-3 provided for the output optical highway. They are merged and output to each output optical highway.

[0004] 4-input, 5-output optical switches 31-1 to 31-31
The optical signals output from the three output ports d and e are combined by the optical combiners 37-1 and 37-2 corresponding to the respective output ports. Since the optical signals output from the optical multiplexers 37-1 and 37-2 are optical signals in which a maximum of four wavelengths are multiplexed, the optical demultiplexers 38-1 and 38-2 respectively output the respective wavelengths. And received by the optical signal receiving unit 33 via the eight output links 39.

On the other hand, each of the eight input links 35 connected to the optical signal transmitting unit 34 has one signal channel of a predetermined wavelength which is determined so as not to have the same wavelength on each output optical highway. Exists, 4 inputs, 4 inputs 3
The output light switches 36-1 and 36-2 are input. The four-input three-output optical switches 36-1 and 36-2 switch the input signal channels to the output optical highways 11-1 to 11-1.
Assigned to output ports a, b, c corresponding to 1-3.
The outputs are respectively combined by the optical combiners 32-1 to 32-3 and output to each output optical highway. This transmission signal channel is a 4-input, 5-output optical switch 31-1 to 31-31.
3 is replaced with the reception signal channel allocated to the output ports d and e.

In this configuration, there are a total of 12 channels in the three input / output optical highways, and up to eight of them can be transmitted / received via the input / output links 35 and 39. This indicates that signal channels of the same wavelength can be transmitted / received to / from two of the three input / output optical highways. With such a configuration, three input optical highways 1
The optical signals input from 0-1 to 10-3 are switched between signal channels of the same wavelength, and can be wavelength-multiplexed and output to three output optical highways 11-1 to 11-3, respectively. . In addition, a predetermined signal channel of each input optical highway is received by the optical signal receiving unit 33, and a signal channel to be replaced with the predetermined signal channel can be transmitted from the optical signal transmitting unit 34 to a predetermined output optical highway.

FIG. 7 shows a second example of a conventional wavelength division type optical communication path.
An example of the configuration will be described. In this configuration, the number of input / output optical highways N ₁ = 3, the number of wavelength multiplexes M = 4, and the number of input / output links N ₂ ×
The case where M = 8 is shown. Also, each signal channel is assumed to be connected with the same wavelength. In the figure, a maximum of four optical signals (wavelengths λ _{1 to} λ ₄ ) are wavelength-multiplexed as signal channels on three input optical highways 10-1 to 10-3. The optical signal input from each input optical highway is transmitted to the corresponding optical demultiplexer 12-1.
The optical signals are separated into respective wavelengths at 12-3 and input to the corresponding four-input four-output optical switches 41-1 to 41-3.
The four-input four-output optical switches 41-1 to 41-3 switch the input signal channels to the output optical highway 11-1.
11-3 or output ports d corresponding to the optical signal receiving unit 33. 4
The optical signals output from the output ports a, b, and c of the input 4 output optical switches 41-1 to 41-3 are respectively combined by the optical combiners 32-1 to 32-3 corresponding to the output optical highway. Output to the output optical highway.

[0008] Four-input four-output optical switches 41-1 to 41-
The optical signal output from the output port d of the optical demultiplexer 4 is an optical signal in which a maximum of four wavelengths are multiplexed.
2-1 to 42-3 separate each signal channel
The 12-input 8-output optical space switch 43 is input. Up to eight channels are input to the 12-input 8-output optical space switch 43. Each signal channel is output from a 12-input 8-output optical space switch 43 to one of eight output links 39,
The signal is received by the optical signal receiving unit 33.

On the other hand, each signal channel of the eight input links 35 connected to the optical signal transmitting section 34 is input to the four-input three-output optical switches 36-1 and 36-2 every four. 4
The input three-output optical switches 36-1 and 36-2 switch the input signal channels to the output optical highways 11-1 to 11-1.
Assigned to output ports a, b, and c corresponding to 11-3. The outputs are respectively combined by the optical combiners 32-1 to 32-3 and output to each output optical highway.

With such a configuration, it is possible to exchange signal channels and transmit and receive signals in the same manner as in the first configuration example shown in FIG. Further, since the four-input five-output optical switch 31 becomes the four-input four-output optical switch 41, the circuit scale can be reduced. Here, 4-input 5-output optical switches 31-1 to 31-3, 4-input 4-output optical switches 41-1 to 41-3, 4-input 3-output optical switches 36-
1, 36-2 has a switching function between input and output and a wavelength multiplexing function. The following is an example of the configuration.

FIG. 8 shows an example of the configuration of a 4-input / 3-output optical switch. In the figure, 12 1-input and 2-output optical switches 2
., 23-41 to 23-43 are arranged on a 4 × 3 matrix, respectively, and input port 2
The optical signal input from 1-1 to 21-4 is output to output port 2
In this configuration, optical signals output to the same output port are distributed to 2-1 to 22-3 and multiplexed by optical multiplexers 24-1 to 24-4.

When a four-input five-output optical switch is configured, twenty one-input two-output optical switches are arranged on a 4 × 5 matrix, and five optical multiplexers are further provided for each output port. Deploy. When a four-input four-output optical switch is configured, sixteen one-input two-output optical switches are arranged on a 4 × 4 matrix, and four optical multiplexers are arranged for each output port.

FIG. 9 shows a configuration example of a 4-input / 4-output optical switch. This configuration has a feature that the loss of each switching path is equalized. In the figure, input ports 21-1 to 21-1
21-4 each have one input and four output optical switches 25-1 to 25-1.
25-4, the optical signals input from the respective input ports are distributed to the output ports 22-1 to 22-4, and the optical signals to be output to the same output port are optical multiplexers 24-1 to 24-4.
Are combined. 1-input 4-output optical switch 25-
1 to 25-4 are three one-input and two-output optical switches 23-11 to 23-13,.
3 is connected in a tree shape. The crosstalk can be reduced by providing an optical gate switch capable of controlling passage and blocking of an optical signal to each output line of the 1-input 4-output optical switches 25-1 to 25-4.

When a four-input five-output optical switch is constructed, one-input four-output optical switches 25-1 to 25-4 are used.
Instead, a one-input eight-output optical switch using seven one-input two-output optical switches is used, and five optical multiplexers are arranged for each output port. When a four-input three-output optical switch is configured, three optical multiplexers are arranged corresponding to each output port, and the one-input four-output optical switches 25-1 to 25-4.
One output port is made empty.

Here, an optical multiplexer can be used instead of the optical multiplexer 24. However, the optical multiplexer has a configuration in which an optical signal is coupled to one output port by using, for example, a difference in reflection angle for each wavelength due to the grating, and has a lower insertion loss than an optical multiplexer using an optical coupler or the like. There are small features.

[0016]

A first configuration example of a conventional wavelength division type optical communication path is composed of N ₂ optical multiplexers and optical demultiplexers when the number of input / output links is N ₂ × M. A predetermined signal channel is allocated to the optical signal receiving unit using a device. However, since the optical demultiplexer was used, only N ₂ signal channels could be received. Here, to be able to receive K number of signal channels to the optical signal receiving unit, K-number of the light converging device and an optical demultiplexer (or N ₁ input M-output optical switch) is required.

In the second example of the conventional wavelength division type optical communication path, when the number of input / output optical highways is N ₁ , the number of wavelength multiplexing is M, and the number of input / output links is N ₂ × M, (N ₁ x M) input
An (N ₂ × M) output optical space switch is used, and signal channels for reception can be collectively distributed regardless of the sequence. However, an optical space switch according to the scale of the wavelength division type optical communication path is required from the time of introduction, and the flexibility to expand the number of input / output optical highways and the number of input / output links is low.

In the conventional wavelength division type optical communication path, an input link connecting an optical signal transmitting unit and an optical switch has a predetermined wavelength of 1 such that each output optical highway does not have the same wavelength. One signal channel is fixedly assigned. Therefore, the degree of freedom in setting the path and wavelength of the signal channel is low, and the degree of freedom in switching the path of the signal channel due to failure of the optical highway or the like is low.

The present invention has a function of exchanging wavelength-multiplexed optical signals and a function of transmitting and receiving each signal channel, further enhances flexibility in expanding the number of input / output optical highways and the number of input / output links, and increases the number of signal channels. It is an object of the present invention to provide a wavelength division type optical communication path that can easily cope with path switching.

[0020]

Wavelength division type optical communication path SUMMARY OF THE INVENTION The present invention, N ₁ for separating the M wavelength as the signal channels of wavelength-multiplexed N ₁ sequence optical signal into M signal channels, respectively a number of one-input M-output optical demultiplexer, or in distributed N ₁ pieces of M inputs of the receiver of the M signal channels N ₁ sequence of destination or N ₂ sequence (N ₁ + N ₂₎ output light A switch, N ₂ M-input N ₁ -output optical switches for distributing each of the M signal channels of the N ₂ sequence transmitted from the optical signal transmitting unit to any of the output destinations of the N ₁ sequence, and N ₁ M input (N ₁ + N ₂ ) output optical switch and N ₂ M
And an input N ₁ output optical switch outputs N ₁ pieces of which merge into each output destination of N ₁ sequence (N ₁ + N ₂₎ inputs and one output optical combiners, further optical signal transmitting unit and the N ₂ pieces of M between the input N ₁ output optical switch, (N ₂ × M) pieces of signal channels respectively converted to a predetermined wavelength (N ₂ × M) pieces of placing the wavelength converting circuit, N ₁ pieces of M input (N ₁ + N ₂ ) N ₂ N ₁ input M output wavelength selection lights to which N ₂ sequence signal channels output from an optical switch are input and distributed to any of M reception destinations by wavelength selection. It has a switch.

Further, as a light source corresponding to each signal channel of the optical signal transmitting unit, a configuration using a wavelength variable light source having a function of a wavelength conversion circuit may be adopted. In addition, a 1-input M-output optical demultiplexer of each system and M inputs (N ₁ +
N ₂ ) Between the output optical switches, M reproduction repeater circuits for performing reproduction processing of M signal channels may be connected (claim 3).

The output of the (N ₁ + N ₂ ) input one-output optical coupler of each stream is provided with a one-input M-output optical demultiplexer for separating into M signal channels, and a demultiplexer for each of the separated signal channels. The M number of regenerative repeater circuits for performing the regenerative processing may be connected to the M-input / one-output optical multiplexer for multiplexing the reproduced signal channels (claim 4).

[0023]

[Action] In the wavelength division type optical communication path of the present invention, an optical signal of N ₁ sequence input by the wavelength-multiplexed after separation into each signal channel, N ₁ pieces of M inputs (N ₁ + N ₂₎ output optical switch using, distributed to the reception destination of the output destination or N ₂ sequence of N ₁ sequence. The N ₂ sequence optical signal to be transmitted is subjected to wavelength conversion processing by a wavelength conversion circuit for each signal channel, and then N ₁
Distribute to the output destination of the series. Signal channel allocated to the destination of the N ₁ sequence respectively are merged for each output destination. At this time, since the wavelength of the signal channel to be transmitted can be arbitrarily set, the path of the signal channel can be easily switched.

Further, N ₁ pieces of M inputs (N ₁ + N ₂₎ from the output optical switch signal channel allocated to the reception destination of N ₂ series, the wavelength selected by the N ₁ input M-output wavelength-selective optical switch, any A signal channel of an arbitrary wavelength on the input optical highway can be output to an arbitrary output link without causing a wavelength collision. This eliminates the need to consider the wavelength dependence of the output link when setting the wavelength of the signal channel.

In this manner, the switching of the signal channel between the input and the output and the switching of the signal channel to be received and the signal channel to be transmitted can be performed simultaneously. In addition, by using the reproduction relay circuit, each input / output signal channel can be reproduced.

[0026]

FIG. 1 shows an embodiment of a wavelength division type optical communication channel according to the present invention. In this embodiment, the number of input / output optical highways N ₁ = 3, the number of wavelength multiplexes M = 4, and the number of input / output links N ₂ ×
The case where M = 8 is shown. Here, N ₂ is the input and output optical highway number N ₁ an integer. Also, each signal channel is assumed to be connected with the same wavelength.

In the figure, three input optical highways 10
-1 to 10-3 each have a maximum of four waves (wavelengths λ ₁ to
The optical signal of λ ₄ ) is wavelength-multiplexed as a signal channel. The optical signal input from each input optical highway is separated into optical signals (signal channels) of each wavelength by the corresponding optical demultiplexers 12-1 to 12-3, and each of the four optical signals corresponding to each input optical highway. Output optical switches 31-1 to 31-3
Is input to 4 input 5 output optical switches 31-1 to 31
-3 designates the input signal channels as output ports a, a corresponding to the output optical highways 11-1 to 11-3.
b, c or output ports d, e corresponding to the optical signal receiving unit 33. 4-input / 5-output optical switch 31-1
The optical signals output from the output ports a, b, and c of the optical couplers 31 to 31-3 respectively correspond to the optical multiplexers 3 corresponding to the output optical highways.
The lights are merged at 2-1 to 32-3 and output to each output optical highway.

4-input / 5-output optical switches 31-1 to 31-31
The optical signals output from the three output ports d and e are connected to the three-input / four-output wavelength selective optical switch 52 corresponding to each output port.
-1 and 52-2. The three-input / four-output wavelength selection optical switches 52-1 and 52-2 output the input optical signal to an output port corresponding to the wavelength, and receive the optical signal by the optical signal receiving unit 33 via eight output links 39. Is done.

On the other hand, each of the eight input links 35 connected to the optical signal transmitting section 34 has one signal channel of an arbitrary wavelength, and each of the wavelength conversion circuits 51-1 to 51-1.
It is inputted to 51-8. Wavelength conversion circuits 51-1 to 51-
8 converts the input optical signal into a predetermined wavelength so as not to have the same wavelength on the output optical highway. By using a variable wavelength light source as a light source corresponding to each signal channel of the optical signal transmission unit 34, the function of the wavelength conversion circuit 51 can be added (claim 2).

The optical signal output from each wavelength conversion circuit is
The signals are input to the four-input three-output optical switches 36-1 and 36-2, respectively. Four-input three-output optical switches 36-1, 36-
Reference numeral 2 designates the input signal channels as output ports a, b, and corresponding to the output optical highways 11-1 to 11-3.
Distribute to c. The output is the optical combiner 32-1
３２32-3 and output to each output optical highway. This transmission signal channel is replaced with the reception signal channel allocated to the output ports d and e of the 4-input 5-output optical switches 31-1 to 31-3.

The four-input five-output optical switch 31-
1-31-3 and 4-input 3-output optical switches 36-1,
At the output of 36-2, there may be multiple signal channels going to the same output optical highway. However, it is assumed that the signal channels from the input optical highway are connected at the same wavelength, and that the signal channels from the optical signal transmitting unit 34 have the same wavelength on the output optical highway by the wavelength conversion circuits 51-1 to 51-8. Therefore, a plurality of optical signals of the same wavelength are not connected to the same output optical highway.

With such a configuration, for the optical signals input from the three input optical highways 10-1 to 10-3, switching between signal channels of the same wavelength is performed, and the three output optical highways 11-1 are used. To 11-3, respectively, and can output. In addition, a predetermined signal channel of each input optical highway is received by the optical signal receiving unit 33, and a signal channel to be replaced with the predetermined signal channel can be transmitted from the optical signal transmitting unit 34 to a predetermined output optical highway.

The four-input five-output optical switch 31 and the four-input three-output optical switch 36 can be manufactured based on the configuration of the optical matrix switch shown in FIG. 8 or the optical switch shown in FIG. Here, a configuration example of the three-input four-output wavelength selection optical switch 52 and a configuration example of the four-input four-output wavelength selection optical switch 52 that becomes the three-input four-output wavelength selection optical switch 52 by leaving one input port empty. explain.

FIG. 2 shows a configuration example of the three-input / four-output wavelength selective optical switch 52. In the figure, input port 61-1
To the optical distributors 62-1 to 62-3, respectively.
Distribute. The distributed optical signals are twelve 2-input / 1-output optical switches 63-11 arranged on a 3 × 4 matrix.
63-13,..., 63-41 to 63-43, and optical signals from predetermined input ports are respectively tunable to variable wavelength filters 64-1 to 64-64 corresponding to output ports 65-1 to 65-4. -4 is input. Each variable wavelength filter selects only an optical signal of a predetermined wavelength and outputs it to output ports 65-1 to 65-4.

FIG. 3 shows a configuration example of a 4-input / 4-output wavelength selective optical switch. In the figure, input ports 61-1 to 6-1
Optical distributors 62-1 to 62-4 are connected to 1-4, respectively, and the optical signals input from the respective input ports are distributed into four. The divided optical signals are output from ports 65-1 to 65-6.
4 four-input one-output optical switches 66 corresponding to 5-4
1 to 66-4, and optical signals from respective predetermined input ports are selected. 4 input 1 output optical switch 66
-1 to 66-4 are three 2-input 1-output optical switches 63-11 to 63-13,..., 63-41 to 63-, respectively.
43 are connected in a tree shape. The output of each 4-input / 1-output optical switch is tunable wavelength filters 64-1 to 64-
4, and selects an optical signal of a predetermined wavelength and outputs it to output ports 65-1 to 65-4. In this configuration, 1
By leaving one input port empty, the three-input four-output wavelength selective optical switch 52 is obtained.

As the optical coupler 32 in the configuration of the embodiment shown in FIG. 1, a selective optical coupler described in Japanese Patent Application No. 5-325140 can be used. This selective type optical coupler is configured by connecting selective type two-input optical couplers in multiple stages. Here, the configuration of the selective two-input optical coupler will be described with reference to FIG. Input ports 71-1 and 7
Optical signals input from 1-2 are input to corresponding one-input / two-output optical switches 72-1 and 72-2, respectively.
Each one-input, two-output optical switch has input ports 71-1, 7
Each optical signal is set to be transmitted to the two-input optical combiner 73 when an optical signal is input from 1-2.
The two-input optical combiner 73 combines the optical signals from the respective input ports and sends them to the three-input one-output optical switch 74. Also,
Each one-input, two-output optical switch has input ports 71-1, 7
When an optical signal is input from one of the optical signals 1-2, the optical signal is transmitted to the three-input one-output optical switch 74. The three-input one-output optical switch 74 is connected to the input port 7
In accordance with the number of optical signals input to 1-1 and 71-2 and the input port of the optical signal, one of the three inputs is selected so as to be transmitted to the output port 75.

With such a configuration, the path through the optical coupler is set only when there is an optical signal to be coupled, and in other cases, the signal passes through the optical switch with small loss. The optical merging operation becomes possible due to the loss. In the wavelength division type optical communication path described above, the optical signals input from the three input optical highways 10-1 to 10-3 are switched between signal channels of the same wavelength, and the three output optical highways 11 are switched. -1 to 11-3 are wavelength-multiplexed and output. here,
If the intensity of the input / output optical signal is low, a regenerative repeater circuit is provided for each signal channel to perform amplification, wavelength shaping, and other processing of the optical signal.

FIG. 5 shows a connection example of the regenerative relay circuit in the configuration of the embodiment shown in FIG. 1 (claims 3 and 4). Here, a part of the wavelength division type optical communication path is shown. As shown in FIG. 5 (a), regenerative repeaters 81-1 to 81-4 corresponding to each signal channel are arranged between the optical demultiplexer 12-1 and the four-input five-output optical switch 31-1. . Between the optical splitter 12-2 and the 4-input 5-output optical switch 31-2, between the optical splitter 12-3 and the 4-input 5-output optical switch 31-.
The same applies to the case of No. 3.

Further, as shown in FIG.
Between 2-1 and the output optical highway 11-1, an optical demultiplexer 82 for demultiplexing each signal channel, regenerative repeaters 81-1 to 81-4 corresponding to each signal channel, and multiplexing of each signal channel. And an optical multiplexer 83 for outputting to the output optical highway. The same is true between the optical coupler 32-2 and the output optical highway 11-2 and between the optical coupler 32-3 and the output optical highway 11-3.

Note that an optical multiplexer may be used instead of the optical multiplexer 83. However, the optical multiplexer has a configuration in which an optical signal is coupled to one output port by using, for example, a difference in reflection angle for each wavelength due to the grating, and has a lower insertion loss than an optical multiplexer using an optical coupler or the like. There are small features.
Further, a selective optical multiplexer may be used instead of the optical multiplexer 83 shown in FIG.

[0041]

As described above, the wavelength division type optical communication path according to the present invention simultaneously switches signal channels between a plurality of streams of input and output, and switches signal channels to be received and signals to be transmitted. Can be. At this time, since the optical signal transmitted from the optical signal transmitting unit can be set to a predetermined wavelength by the wavelength conversion circuit, the optical signal transmitting unit can arbitrarily set the wavelength of each signal channel. For a signal channel received by the optical signal receiving unit, a signal channel of an arbitrary wavelength can be received by using a wavelength selective optical switch.

Therefore, the required number of optical switches to which the signal channel from the optical signal transmitting unit is input and the required number of wavelength selective optical switches to which the received optical signal is input are determined by the optical signal transmitting unit and the optical signal receiving unit. When the number of transmission / reception channels is determined, it can be uniquely determined regardless of the wavelength assigned to the signal channel. In a conventional wavelength division type optical communication channel, the number of optical switches and the required number of optical components (optical multiplexers and optical demultiplexers) for processing a signal channel to an optical signal receiver depend on the wavelength allocated to the signal channel. Was.

Here, it is assumed that the number of input optical highways of the wavelength division type optical communication path is N ₁ , the number of wavelength multiplexing is M, and K signal channels are received by the optical signal receiving unit. However, for simplicity, K is a constant multiple of M (K ≧ M). In the conventional wavelength division type optical communication path, when all signal channels are allocated to the same wavelength, the number of optical components is K, the number of output links is K × M, and the utilization rate of the output link is (1 / M). )
× 100%. On the other hand, in the wavelength division type optical communication path of the present invention, N ₁ input M-output wavelength-selective optical switch number (K /
M), and the utilization rate of the output link becomes 100%, indicating that the network resources can be used effectively.

Further, in the conventional configuration, in order to improve the utilization rate of the output link, it is necessary to solve a complicated optimization problem in consideration of the wavelength on the input / output link in the setting of the path / wavelength of the signal channel. On the other hand, according to the configuration of the present invention, it is not necessary to consider the wavelength on the input / output link, so that the assignment of the signal channel path and the wavelength becomes easy. further,
It is possible to flexibly cope with expansion of the number of input / output optical highways and the number of input / output links.

Further, by reproducing each input / output signal channel by using a regenerative repeater circuit, the present invention can be applied to a large-scale system in which wavelength division type optical communication paths of the present invention are connected in multiple stages. .

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of a wavelength division type optical communication path according to the present invention.

FIG. 2 is a block diagram showing a configuration example of a three-input four-output wavelength selection optical switch 52.

FIG. 3 is a block diagram showing a configuration example of a 4-input / 4-output wavelength selection optical switch.

FIG. 4 is a block diagram showing a configuration of a selective type two-input optical coupler.

FIG. 5 is a block diagram showing a connection example of a reproduction relay circuit.

FIG. 6 is a block diagram showing a first configuration example of a conventional wavelength division type optical communication path.

FIG. 7 is a block diagram showing a second configuration example of a conventional wavelength division type optical communication path.

FIG. 8 is a block diagram showing a configuration example of a four-input three-output optical switch.

FIG. 9 is a block diagram showing a configuration example of a four-input four-output optical switch.

[Explanation of symbols]

 Reference Signs List 10 input optical highway 11 output optical highway 12 optical demultiplexer 21 input port 22 output port 23 1 input 2 output optical switch 24 optical multiplexer 25 1 input 4 output optical switch 31 4 input 5 output optical switch 32 optical combiner (5 Input) 33 Optical signal receiving unit 34 Optical signal transmitting unit 35 Input link 36 4-input 3-output optical switch 37 Optical combiner (3 inputs) 38 Optical splitter 39 Output link 41 4-input 4-output optical switch 42 Optical splitter 43 12 input 8 output optical space switch 51 wavelength conversion circuit 52 3 input 4 output wavelength selection optical switch 61 71 input port 62 optical distributor 63 2 input 1 output optical switch 64 variable wavelength filter 65 75 output port 66 4 input 1 Output optical switch 72 1-input 2-output optical switch 73 2-input optical combiner 74 3-input 1-output optical switch 8 1 Regenerative repeater circuit 82 Optical demultiplexer 83 Optical multiplexer

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-8-79806 (JP, A) JP-A-8-65241 (JP, A) Atsushi Watanabe, Satoshi Okamoto, Optical path cross-connect using a merge type switch System Configuration, Proc. Of the 1994 IEICE Autumn Meeting, Japan Society of Electronics, Information and Communication Engineers, September 5, 1994, 3rd Volume, 335 Satoshi Okamoto, Atsushi Watanabe, Optical Path Cross-Connect System Configuration Examination of Law, Proc. Of the 1994 IEICE Spring Conference, Japan, The Institute of Electronics, Information and Communication Engineers, March 10, 1994, 3, 3-333, B-838 (58) .Cl. ⁷ , DB name) H04J 14/00-14/08 H04B 10/00-10/28 H04Q 3/52 JICST file (JOIS)

Claims (4)

(57) [Claims] And 1. A M number of N ₁ pieces of 1-input M-output optical demultiplexer wavelength separating optical signals of wavelength-multiplexed N ₁ sequence as a signal channel into M signal channels respectively, separated the M distributes the signal channel to one of the reception destination of the output destination or N ₂ sequence of N ₁ sequence N ₁ pieces of M
An input (N ₁ + N ₂ ) output optical switch; and N ₂ for distributing each of the M signal channels of the N ₂ sequence transmitted from the optical signal transmission unit to one of the output destinations of the N ₁ sequence.
Outputs of the M input N ₁ output optical switches, the N ₁ M input (N ₁ + N ₂ ) output optical switches and the N ₂ M input N ₁ output optical switches for each N ₁ series output destination merging is to N ₁ pieces of the (N ₁ + N ₂₎ wavelength division optical communication path having an input 1 output optical combiners, and the optical signal transmission section and the N ₂ pieces of M input N ₁ output optical switch In between, (N ₂ × M) wavelength conversion circuits for converting (N ₂ × M) signal channels into respective predetermined wavelengths are arranged, and the N ₁ M inputs (N ₁ + N ₂ ) outputs are provided. characterized in that the signal channel of the N ₂ sequence outputted from the optical switch respectively input, equipped with a N ₂ pieces of N ₁ input M-output wavelength-selective optical switch allocation to one of the M destination respectively by the wavelength selective Wavelength division type optical communication path. 2. The wavelength division type optical communication path according to claim 1, wherein the light source corresponding to each signal channel of the optical signal transmission unit is:
A wavelength division type optical communication path characterized by using a wavelength variable light source having a function of a wavelength conversion circuit. 3. The wavelength division type optical communication path according to claim 1, wherein a one-input M-output optical demultiplexer of each system and an M-input (N ₁ + N ₂ ) output optical switch are provided. A wavelength division type optical communication path, characterized in that it is configured to connect M reproduction relay circuits for performing reproduction processing of M signal channels, respectively. 4. The wavelength division type optical communication path according to claim 1, wherein each of the (N ₁ + N ₂ ) input and one output optical combiners is separated into M signal channels. 1-input M-output optical demultiplexer, and M for performing reproduction processing of each separated signal channel
A wavelength division type optical communication path, comprising: a plurality of regenerative repeaters connected to an M-input / one-output optical multiplexer for multiplexing reproduced signal channels.