JP2000244951A - Optical cross connect device - Google Patents

Abstract

(57) [Problem] To provide an optical XC device excellent in scalability by reducing the initial hardware amount when the number of input / output ports or the number of wavelengths is small. SOLUTION: N M (M ≧ N) consecutive 1 × 2 switches, N first M × M switches, M second M × M switches M, and N third M × M switches N switches and
N M 2 × 1 switches are provided with N switches. Of the M input terminals of each M-series 1 × 2 switch, a signal is input to up to M / 2 input terminals, and M output terminals are M second input terminals of the first M × M switch. Connected to. M output terminals of each third M × M switch are M
An output signal is output from a maximum of M / 2 output terminals of the M-series 2 × 1 switch.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to an optical cross-connect device, and more particularly to an expansion of an optical switch circuit.

[0002]

2. Description of the Related Art As the speed and capacity of information increase, the bandwidth and capacity of networks and transmission systems have been demanded. Construction of an optical network using optical technology has been desired as one means for realizing it. An optical cross-connect device (optical XC device) is a core device for constructing an optical network.

FIG. 16 is a diagram showing a configuration example of an optical XC system and an optical network. The optical XC device 6 houses a plurality of input / output optical transmission lines 4, 5, 10, and 11, and routes an optical signal coming from the input optical transmission lines 4, 10 to a desired output optical transmission line 5, 11. It is a device that performs

In the case of long-distance transmission, the optical amplifier 2 is inserted into the inter-station transmission line 7 of the optical XC, and another communication device (for example, an electric cross-connect (electric XC)) is transmitted through the intra-station optical transmission line 11. ). These devices are controlled by the operation system 12.

On the other hand, the key to realizing the optical XC device is a large-capacity optical switch circuit, which is scalable (that is, the processing capacity can be increased without cutting off the optical signal in operation. It is desirable to increase the amount of hardware in proportion to the additional capacity from the initial stage to the maximum capacity accommodation as much as possible.)

[0006] In optical networks, wavelength multiplexing (WDM) technology is being introduced as traffic increases. FIG.
Are the optical XCs without wavelength multiplexing and with wavelength multiplexing.
It is a block diagram of a system.

As shown in FIG. 17A, the optical XC device 14 without wavelength multiplexing outputs an optical signal having a wavelength λ0 input from the inter-station optical transmission line 4 or the intra-station optical transmission line 10 to a desired output. This is for routing to the inter-station optical transmission line 5 or the intra-station optical transmission line 11, and is configured by an optical switch network. In the optical XC device 14, switching based on space division is performed instead of processing based on time division (processing in units of time slots or cells).

As shown in FIG. 17B, when wavelength division multiplexing is introduced, a wavelength division multiplexed optical signal flows through the inter-station optical transmission line 4, and the optical XC device 16 performs switching in wavelength units. I do. FIG. 18 is a diagram illustrating a basic configuration of the wavelength division multiplexing light XC. The wavelength multiplexed light XC is divided into
Optical switch network 20, wavelength converter (output wavelength is fixed)
22 and a multiplexer 24.

[0009] By controlling the optical switch network 20 by a controller (not shown) designated by the operation system 12 in FIG. 16, each signal light of wavelengths λ1 to λn output from the demultiplexer 18 is Are routed to a desired output terminal to be connected, and the input wavelength is converted to a desired output wavelength by the wavelength converter 22.

In general, as a capacity expansion method in a space switch, a multistage configuration represented by a three-stage configuration of Clos is employed. Naturally, the technique is also used in the optical switch network.

FIG. 19 is a diagram showing a basic configuration of a three-stage optical switch network. In this configuration, M × M is used as the size of the basic switch module, and these are connected in three stages to realize an optical switch network having the number of input / output channels M ² . Here, the first stage has M M × 2M optical switches 30 # 1 to 30 # M, and the middle stage has 2M M × 2M switches.
M optical switches 38 # 1 to 38 # 2M, and M
2M × M optical switches 40 # 1 to 40 # M are used.

The number of switches required for the intermediate stage is as follows:
This is the sum of the number of channels (input M and output M) input / output to each switch of the first and third stages. The M × 1M optical switch 30 # i (i = 1 to M) includes an M-series 1 × 2 switch 32
#I and two M × M switches 34 # i and 36 # i are used. The 2M × M optical switch 40 # i has two M
× M switches 42 # i and 44 # i and M-series 2 × 1 switches 46 # i are used.

FIG. 20 is a diagram showing an example of an optical space switch. For example, when the number of inputs and outputs is four of # 0 to # 3, 4 × 4 switch elements Sij (i = 0 to
3, j = 0 to 3) are arranged in a matrix, and the corresponding switch element Sij is set to the Bar state, and the other switch elements are set to the Cross state, whereby a signal input from an arbitrary input terminal #i can be changed. Output to an arbitrary output terminal #j.

FIG. 21 shows that M = 8 and the number of input / output ports = 16
FIG. 3 is a diagram showing a conventional three-stage optical switch network in the case of FIG.
As shown in FIG. 21, when the number of input / output ports is set to 16, two 1 × 2 switches 50 # 1 and 50 # 2, 8
4 × 8 switches 52 # 1 to 52 # 4, 16 8 × 8 switches 54 # 1 to 54 # 16, 8 × 8 switch 56
# 1 to 56 # 4, 8 stations 2 × 1 switch 58 # 1,
Use two 58 # 2.

Each of the eight 1 × 2 switches 50 # 1, 50 # 2
An input transmission line is connected to each of the eight input terminals, and two 8 × 8 switches 52 # 1 and 52 # are connected to each of the 16 output terminals.
2, 52 # 3 and 52 # 4 are connected.

The input terminals of the intermediate 8 × 8 switches 54 # 1 to 54 # 8 are connected to the output terminals of the 8 × 8 switches 52 # 1 and 52 # 3, and the 8 × 8 switches 52 # 2 and 52 # 4 8 × 8 switches 54 # 9 to 54 # 1 at the output terminals of
6 input terminals.

An output transmission line is connected to each of eight output terminals of each of the 8 × 2 2 × 1 switches 58 # 1 and 58 # 2, and two 8 × 8 switches 56 # 1 and 56 are connected to each of 16 input terminals. # 2
The output terminals of 56 # 3 and 56 # 4 are connected.

The input terminals of the switches 56 # 1 and 56 # 3 are connected to the output terminals of 8 × 8 switches 54 # 1 to 54 # 8 in the intermediate stage, and the input terminals of the switches 56 # 2 and 56 # 4 are connected to the input terminals of the switches 56 # 2 and 56 # 4. The output terminals of the intermediate stage 8 × 8 switches 54 # 9 to 54 # 16 are connected.

FIG. 22 shows that M = 8 and the number of input / output ports = 32
FIG. 3 is a configuration diagram of a conventional three-stage optical switch network in the case of FIG.
When the number of input / output ports is 32, 8 stations 1 × 2 switch 50
Four # 1 to # 4 # 4, 8 × 8 switches 52 # 1 to 52
Eight # 8, one 8x8 switch 54 # 1-54 # 16
Six 8 × 8 switches 56 # 1 to 56 # 8 are used, and eight 2 × 1 switches 58 # 1 to 58 # 4 are used.

FIG. 23 shows that M = 8 and the number of input / output ports = 64
FIG. 3 is a configuration diagram of a conventional three-stage optical switch network in the case of FIG.
When the number of input / output ports is 64, 8 stations 1 × 2 switch 50
Eight # 1 to 50 # 8, 8 × 8 switches 52 # 1 to 52
8 # 16, 16 8 × 8 switches 54 # 1 to 54 # 16, 16 8 × 8 switches 56 # 1 to 56 # 16
8 × 2 × 1 switches 58 # 1 to 58 # 8.

FIG. 24 shows that M = 8 and the number of input / output channels = 1.
6 is a configuration diagram of a wavelength multiplexing type optical XC using a conventional three-stage optical switch network in the case of No. 6. FIG. The first stage 8-unit 1 × 2 switch 50 # 1 of the three-stage optical switch network configured in the same manner as in FIG. 21 is connected to the output terminals of the demultiplexers 60 and 62 for outputting the wavelength-multiplexed signal light of eight channels of wavelengths λ1 to λ8. , 50 # 2.

Two 8 × 2 × 1 switches 58 # 1, 58
The input terminals of the wavelength converters 64 and 66 are connected to the output terminal of # 2, and the multiplexers 68 and 66 are connected to the output terminals of the wavelength converters 64 and 66.
70 input terminals are connected.

FIG. 25 shows that M = 8 and the number of input / output channels = 3
2 is a configuration diagram of a wavelength multiplexing type optical XC using a conventional three-stage optical switch network in the case of 2. FIG. The first stage 8-unit 1 × 2 switch 50 # 1 of the three-stage optical switch network configured in the same manner as in FIG. 22 is connected to the output terminals of the demultiplexers 60 and 62 for outputting the wavelength multiplexed signal light of 16 channels of wavelengths λ1 to λ16. To # 4 input terminals.

Four 8-unit 2.times.1 switches 58 # 1-58
The input terminals of the wavelength converters 72 and 74 are connected to the output terminal of # 4, and the multiplexers 68 and 74 are connected to the output terminals of the wavelength converters 72 and 74.
70 input terminals are connected.

FIG. 26 shows that M = 8 and the number of input / output channels = 6
4 is a configuration diagram of a wavelength multiplexing type optical XC using a conventional three-stage optical switch network in the case of No. 4. The first-stage eight-unit 1 × 2 switch 50 # 1 of the three-stage optical switch network configured in the same manner as in FIG. 23 is connected to the output terminals of the duplexers 60 and 62 for outputting the wavelength-multiplexed signal light of 32 channels of wavelengths λ1 to λ32. To # 8 input terminals.

Eight eight 2 × 1 switches 58 # 1 to 58
The input terminals of the wavelength converters 76 and 78 are connected to the output terminal of # 8, and the multiplexers 68 and 78 are connected to the output terminals of the wavelength converters 76 and 78.
70 input terminals are connected.

[0027]

In the conventional optical XC, as shown in FIGS. 21 and 22, when there are no wavelength multiplexing, if the number of input / output ports is M or more, even if the number of input / output ports is small, Since it is necessary to prepare all the switches 54 # 1 to 54 # 8 in the intermediate stage, the amount of hardware at the initial stage becomes large, and there is a problem in terms of expandability.

When wavelength multiplexing is used, FIGS.
As shown in (1), even when the number of wavelengths is small, it is necessary to prepare all the switches 54 # 1 to 54 # 8 in the intermediate stage, so that there is the same problem as in the case without wavelength multiplexing.

The present invention has been made in view of such a point, and when the number of input / output ports or the number of wavelengths is small,
It is an object of the present invention to provide an optical XC device which has a small initial hardware amount and is excellent in expandability.

[0030]

FIG. 1 is a diagram illustrating the principle of the present invention. As shown in FIG. 1, according to the present invention, one input terminal and two first output terminals are provided, and the first input terminal is input to the first input terminal based on a first control signal. An M-series 1 × 2 switch 82 # i (i) including M (M ≧ 2) 1 × 2 switches 80 # i (i = 1 to M) for outputting a signal to any one of the first output terminals = 1 to N) is N (2 ≦ N ≦
M), M second input terminals, and M second output terminals. Based on a second control signal, a signal input to any one of the second input terminals can be A first M × M switch 84 # i (i = 1 to M) that outputs to two output terminals has N, M third input terminals, and M third output terminals, and a third control signal , A signal input to an arbitrary third input terminal is output to an arbitrary third output terminal.
M switches 86 # i (= 1 to M) and M fourth switches
A third M × M switch 88 having an input terminal and M fourth output terminals and outputting a signal input to an arbitrary fourth input terminal to an arbitrary fourth output terminal based on a fourth control signal; #
i (i = 1 to N) has N, two fifth input terminals and one fifth output terminal, and is connected to one of the fifth input terminals based on the fifth control signal. The input signal is
M (M ≧ 2) 2 × 1 switches 9 output to output terminals
M × 2 2 × 1 switch 92 composed of 0 # i (i = 1 to N)
#I (i = 1 to N) is N.

For each M-series 1 × 2 switch 82 # i,
A signal is input to a maximum of M / 2 first input terminals, and M
First output terminals are connected to the M second input terminals of the first M × M switch 84 # i.

The M second output terminals of each first M × M switch 84 # i are M second M × M switches 86 # k (k
= 1 to M), and the M fourth input terminals of each third M × M switch 88 # i have M second M inputs.
It is connected to the third output terminal of the × M switch 86 #k (k = 1 to M).

The M fourth output terminals of each third M × M switch 88 # i are connected to the fifth input terminal of an M-series 2 × 1 switch 92 # i, and the M-series 2 × 1 switches 92 # i are connected to the fifth input terminal. Max M
An optical XC device is provided, wherein an output signal is output from two fifth output terminals.

According to such a configuration, for example, without wavelength division multiplexing, (M / 2) × (N-1) + k (k = 1 to
When accommodating an input / output transmission line in N) input / output ports,
The first up to the maximum M / 2 of each M-series 1 × 2 switch 82 # i
An input terminal is connected to each input transmission line, and a fifth output terminal up to a maximum M / 2 of each M-series 2 × 1 switch 92 # i is connected to each output transmission line.

The M first output terminals of the M × 1 switches 82 # i are connected to the second input terminals of the M × M switches 84 # i, and input transmission is performed based on the first control signal. The first input terminal connected to the path and the second of the M × M switch 84 # i
The first output terminal connected to the input terminal is connected.

Based on the second control signal, the signal input to the second input terminal of the first M × M switch 84 # i is output to a desired second M × M switch 86 # k. Based on the fifth control signal, the fifth output terminal of each of the M-series 2 × 1 switches 92 # i connected to the output transmission path and the third M × M switch 88
#I is connected to the fifth input terminal connected to the fourth output terminal.

Based on the third and fourth control signals, the signal input to the third input terminal of the desired second M × M switch 86 # i is converted to the fourth output of the desired third M × M switch 88 # i. Output from the terminal. Thus, a signal input from each input transmission line can be routed to a desired output transmission line. At this time, the second M × M switch 86 # i (i =
1 to N), the number of switch elements to be used can be reduced, and the expandability of the optical XC device can be improved.

[0038]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First Embodiment FIG. 2 is a block diagram of an optical XC device according to the first embodiment of the present invention. The optical XC device shown in FIG. 2 has a basic switch configuration of M × M and the number of input / output ports = ((M / 2) × (N−1).
+ I) (any number from I = 1 to M / 2) without wavelength division multiplexing.

As shown in this figure, the optical XC apparatus comprises N M-series 1 × 2 switches 100 # 1 to 100 # N and N M
× M switch 102 # (2i-1) (i = 1 to N), M
M × M switches 104 # 1 to 104 # M, N M
× M switch 106 # (2i−1) (i = 1 to N), N
M × 2 2 × 1 switches 108 # 1 to 108 # N and a controller (not shown) are provided.

Each M-series 1 × 2 switch 100 # i (i = 1
To N), each M × M switch 102 # (2i-1) (i =
1 to N), each M × M switch 104 # i (i = 1 to
M), each M × M switch 106 # (2i-1) (i = 1
To N) and each M-series 2 × 1 switch 108 # i (i = 1 to
N) has a module configuration.

These switches 100 # i (i = 1 to 1)
N), 102 # (2i-1) (i = 1 to N), 104 #
i (i = 1 to M), 106 # (2i-1) (i = 1 to
N), 108 # i (i = 1 to N) and various mounting methods of the controller are conceivable. For example, each switch is mounted on a plurality of printed circuit boards for each expansion unit.
The controller is mounted on one printed circuit board. The printed circuit boards of the optical switches are connected by optical cables.

For example, if the number of input / output ports in the extension unit is (M
/ 2) × L, N is a multiple of L, and when the number of input / output ports is (M / 2) × N, the optical XC device uses L M × 1 × 2 switches and L for the first stage. L printed circuit boards on which M × M switches are mounted, M M for intermediate stages
M printed circuit boards with × M switches, L printed circuit boards with L M × M switches for the last stage and L M × 2 × 1 switches, and prints with controllers The substrate is composed of one sheet. Each printed circuit board is housed in a shelf of the optical XC device. still,
The shelf can accommodate maximum input / output ports.

(M−N) 101 # j (j = N + 1 to 101)
M) is an unused M-series 1 × 2 switch. M 10
3 # 2j (j = 1 to M) and (M−N) 103 #
(2j-1) (j = N + 1 to M) is the unused M × in the first stage.
M switch. M 105 # j (j = M + 1 to 2
M) is an unused M × M switch in the middle stage.

M 107 # 2j (j = 1 to M) and (M−N) 107 # (2j−1) (j = N + 1 to 1)
M) is an unused M × M switch at the last stage. (M-
N) 109 # j (j = N + 1 to M) are unused M-series 2 × 1 switches.

Here, the unused M-series 1 × 2 switch 101
#J, unused M × M switch 103 # j in the first stage, unused M × M switch 105 # j in the middle stage, unused M in the last stage
× M switch 107 # j, unused M stations 2 × 1 switch 1
07 # j generally refers to one that is not mounted on the optical XC device and does not house a printed circuit board corresponding to a shelf. In addition, the broken line to the input / output terminal of the unused switch in FIG. 2 indicates no connection.

FIG. 3 is a configuration diagram of the M-series 1 × 2 switch in FIG. Each M-series 1 × 2 switch 100 # i (i = 1
To N) are connected to the input ports of the optical XC device by optical fibers. M of the 2 × M output terminals are connected to the M × M switch 102 # (2
i-1) are connected to the input terminals, and the remaining M are connected to the input terminals of the currently unused M × M switch 103 # 2i when the optical XC device of this configuration is expanded. (Hereinafter, this is described as being connected to the input terminal of the unused M × M switch 103 # 2i.) The M-series 1 × 2 switch 100 # i has M 1 × 2 switches 116 # 1 to 116 # M. . The input terminal of each 1 × 2 switch 116 # i (i = 1 to M) is connected to an input port, and among these M input terminals, (M / 2)
Are connected to the input transmission line 110.

Further, each 1 × 2 switch 116 # i (i =
1-M) is an M × M switch 102 #
It is connected to the input terminal of (2i-1). The other output terminal is connected to the input terminal of the unused M × M switch 103 # 2i.

Each M × M switch 102 # (2i-1)
(I = 1 to N) output terminal and unused switch 103 #
The output terminal of (2j-1) (j = N + 1 to M) is connected to the input terminal of the middle stage M × M switch 104 # i (i = 1 to M).

Unused M × M switch 103 # 2j (j =
1 to M) are connected to the input terminals of unused M × M switches 105 # j (j = M + 1 to 2M) in the middle stage.

Each M × M switch 104 # i (i = 1 to 1)
M) N output terminals are the final stage M × M switch 10
6 # (2i−1) (i = 1 to N), and the remaining (M−N) output terminals are unused M × M switches 10
7 # (2j-1) (j = N + 1 to M). Each unused M × M switch 105 # j (j = M +
1 to 2M) are connected to the input terminals of the last unused M × M switch 107 # 2j (j = 1 to M).

FIG. 4 is a block diagram of the M-series 2.times.1 switch shown in FIG. Each M-series 2 × 1 switch 108 # i (i = 1
To N) are connected to the M output terminals of the M × M switch 106 # (2i-1) by, for example, an optical fiber, and the remaining M input terminals are unused M × M switches. Connected to M output terminals of M switch 107 # 2i.

The M output terminals of the M-series 2.times.1 switch 108 # i are connected to output ports by optical fibers, and the M / 2 output terminals are output transmission lines between or within stations by optical fibers. 112.

Each M-series 2 × 1 switch 108 # i has M 2 × 1 switches 118 # 1 to 118 # M. One input terminal of each 2 × 1 switch 118 # i (i = 1 to M) is connected to an M × M switch 106 # (2j−1) (j =
i) is connected to the output terminal. The other input terminal is
It is connected to the output terminal of the unused M × M switch 107 # 2i. Also, M / 2 2 × 1 switches 118 # i (i
= 1 to M / 2) are connected to the output transmission line 112.

A controller (not shown) operates in accordance with an instruction from an operation system having the same configuration as the operation system 12 shown in FIG.
0 # i, M × M switch 102 # i, 104 # i, 10
The electrodes of the switch elements constituting the 6 # i and M-series 2 × 1 switches 108 # i have the Cross state and the Ba
A control signal for setting any one of the r states is output through the electric wiring.

(A) A method of constructing an optical XC device at the initial stage or a method of constructing an optical XC device at the time of extension Generally, the extension is performed by a multiple of the extension unit. / 2) × L, the number of input / output ports = (M / 2) × N (N is a multiple of L). For example,
A printed circuit board on which L M-series 1 × 2 switches and L first-stage M × M switches are mounted is accommodated in an L shelf, and N M-series 1 × 2 switches 100 # i (i = 1 to
N) and N M × M switches 102 # (2i-1)
(I = 1 to N) are mounted on the optical XC device.

Each M-series 1 × 2 switch 100 # i (M /
2) connect the input terminals to the input transmission line 110; The M output terminals of the M × 1 switch 100 # i and the M input terminals of the M × M switch 102 # (2i-1) are connected by an optical cable.

The M printed circuit boards on which the M M × M switches are mounted are stored in the shelf, and the M intermediate stage M
The × M switch 104 # i (i = 1 to M) is mounted on the optical XC device. Each M × M switch 102 # (2i-
1) M output terminals and an intermediate stage M × M switch 104
The input terminals of #k (k = 1 to M) are connected by an optical cable.

L printed circuit boards on which L last stage M × M switches and L M series 2 × 1 switches are mounted,
N final stage M × M switches 1 stored in shelf
06 # (2i-1) (i = 1 to N) and N M reams 2 ×
One switch 108 # i (i = 1 to N) is mounted on the optical XC device.

The middle stage M × M switch 104 #k (k =
1 to M) and the final stage M × M switch 106 #
The M input terminals of (2i-1) are connected by an optical cable. The M input terminals of the M × 2 switch 108 # i are connected to the M output terminals of each of the M × M switches 106 # i in the final stage by optical fibers. M-series 2 × 1 switch 1
08 # i (M / 2) output terminals to the output transmission line 112
Connect.

Incidentally, for example, the number of input / output ports = (M / 2)
In the case of extending from × (N / 2) to (M / 2) × N, the printed circuit board on which the switch module to be extended is mounted is stored in a shelf by the above-described method, and the printed circuit boards are connected by an optical cable. Good.

(B) Operation of FIG. 2 at the time of operation In accordance with the instruction of the operation system, the controller sets the 1 × 2 switch 116 # j (j = 1 to M) in each M × 1 1 × 2 switch 100 # i to Bar. State, the optical signal input from the input transmission line 110 is switched to the M × M switch 1
02 # (2i-1). Thereby, (M / 2) × N input transmission lines 100
The optical signal input from the
02 # (2i-1) (i = 1 to N).

The controller is a M × 2 switch 1
2 # 1 switch 118 # j in 08 # i (j = 1 to M)
To the Bar state, and the final stage M × M switch 106 #
The signal light output from the output terminal (2i-1) is controlled to be output to the output transmission line 112.

Further, the controller includes the first-stage M × M switches 102 # (2i-1) (i = 1 to N), the middle-stage M × M switches 104 # i (i = 1 to M), and the final stage. M × M switches 106 # (2i-1) of the stages (i = 1 to
N) Switch element in Cross state or Bar
State, and set each input transmission line 110 to the desired output transmission line 1
12 is controlled.

(C) M-series 1 × 2 switch to be used, M
× Number of M switches and 2 × 1 switches of M stations Number of 1 × 2 switches of M stations used = N, M × M of first stage
Number of switches = N, number of M × M switches in intermediate stage =
M, the number of M × M switches in the final stage = N, and the number of M × 2 switches = N. The total number of 1 × 2 (or 2 × 1) switch elements used is 2N × M +
(2N + M) × M ² .

FIG. 5 is a diagram showing a configuration example of the first embodiment when M = 8 and the number of input / output ports = 16. As shown in FIG. 5, in this case, the 8-unit 1 × 2 switch 120 # i
(I = 1 to 4), the first 8 × 8 switch 122 #
(2i-1) 4 (i = 1 to 4), 8 intermediate 8 × 8 switches 124 # i (i = 1 to 8), 8 × 8
Four 8 switches 126 # (2i-1) (i = 1 to 4) and four 8 × 2 2 × 1 switches 128 # i (i = 1 to 4)
Use

For example, an 8-unit 1 × 2 switch 120 # i
(I = 1 to 4) and the first stage 8 × 8 switch 122 # (2
i-1) A printed circuit board on which each of (i = 1 to 4) is mounted is connected to an 8 × 8 switch 124 # i (i = 1 to 8) of an intermediate stage.
And the final stage of 8x8
A printed circuit board on which switches 126 # (2i-1) (i = 1 to 4) and 8 × 2 × 1 switches 128 # i (i = 1 to 4) are mounted is prepared.

The printed circuit board on which these switches are mounted is housed in the shelf of the optical XC device. Then, the printed circuit boards are connected by an optical cable, and the light X shown in FIG.
Build the C device.

In FIG. 5, 121 # j (j = 5 to 8) is an unused 8-unit 1 × 2 switch, and 123 # (2j-1) (j = 5 to 8).
8), 123 # 2j (j = 1 to 8) are unused 8 ×
8 switches, 125 # j (j = 9 to 16) are unused 8 × 8 switches in the middle stage, 127 # (2j−1) (j = 5
9), 127 # 2j (j = 1 to 8) are unused 8 in the last stage
The × 8 switches and 127 # j (j = 5 to 8) are unused 8 × 2 × 1 switches.

FIG. 6 is a diagram showing a configuration example of the first embodiment when M = 8 and the number of input / output ports = 32. For example,
When the number of input / output ports shown in FIG. 5 is expanded from 16 to 32, the number of input / output ports shown in FIG.
Four 8 × 1 × 2 switches 120 # i (i = 5 to 8),
First stage 8 × 8 switch 122 # i (2i-1) (i = 5
To 8), and the final stage 8 × 8 switch 126 # (2i
-1) 4 (i = 5 to 8), 8-unit 2 × 1 switch 12
By further using four 8 # i (i = 5 to 8), the printed circuit board on which these switches are mounted is housed in the shelf. Then, the printed circuit boards are connected by an optical cable.

When M = 8 and the number of input / output ports = 64, the configuration is the same as that of the conventional optical XC apparatus shown in FIG.

FIG. 7 is an explanatory diagram of the effect of the optical XC device of the first embodiment. In the case where M = 8, the number of input / output ports is 16, and
32 and 64 compare the number of 2 × 2 switch elements used in the conventional and the first embodiment. (/) In FIG. 7 is (8 × 8 number of switches / 8 stations 1 × 2 (2 × 1)
Number of switches).

Conventionally, when the number of input / output ports = 16,
Two 8 × 1 × 2 switches and two 8 × 2 × 1 switches
, 8 x 8 switches in the first stage, 16 8 x 8 switches in the middle stage, 4 8 x 8 switches in the last stage,
As shown in FIG. 7, there are 1568 switch elements.

On the other hand, in the first embodiment, when the number of input / output ports = 16, four 8 × 1 × 2 switches and 8 × 2 × 1
4 switches, 4 initial stage 8 × 8 switches, 8 intermediate stage 8 × 8 switches, 4 final stage 8 × 8 switches
As shown in FIG.
The number is 88, and the number of switch elements is smaller than that of the conventional 1568. When N = (M / 2),
The ratio of the number of switch elements between the prior art and the first embodiment is the same as in the case where M = 8 and the number of input / output ports = 16.

Conventionally, when the number of input / output ports = 32,
Four 8 × 1 × 2 switches, 4 × 8 × 2 × 1 switches
8 × 8 switches in the first stage, 16 × 8 × 8 switches in the middle stage, 8 × 8 × 8 switches in the last stage,
As shown in FIG. 7, the number of switch elements is 2112.

On the other hand, in the first embodiment, when the number of input / output ports = 32, there are eight 8 × 1 × 2 switches and 8 × 2 × 1 switches.
8 switches, 8 8 × 8 switches in the first stage, 8 8 × 8 switches in the middle stage, 8 8 × 8 switches in the last stage
And the number of switch elements is 1 as shown in FIG.
This is 664, and the number of switch elements is smaller than that of the conventional 2112. Even when N = M, the ratio of the number of switch elements between the prior art and the first embodiment is M
= 8 and the number of input / output ports = 32.

When the number of input / output ports is 64, the number of switch elements in the conventional and the first embodiments is equal.

Second Embodiment FIG. 8 is a block diagram of an optical XC apparatus according to a second embodiment of the present invention. Elements that are substantially the same as those in FIG. 2 are given the same reference numerals. .

The optical XC device of FIG. 8 differs from the optical XC device of FIG. 2 in the following points.

Instead of using the M × 1 switch module, the (M / 2) × 1 switch module is used.

Instead of using the M-line 2 × 1 switch module, the (M / 2) -line 2 × 1 switch module is used.

In the optical XC apparatus shown in FIG. 8, the basic switch configuration is an M × M switch, and the number of input / output ports = (M /
2) In the case of × N, instead of the M-series 1 × 2 switch, (M
/ 2) 1 × 2 switches 130 # (2i-1) (i = 1
To N), instead of the M 2 × 1 switches, (M /
2) 2 × 1 switch 132 # (2i-1) (i = 1 to 2)
N) are used.

For example, the number of input / output ports in the extension unit = (M
/ 2) × L, L printed circuit boards on which L (M / 2) 1 × 2 switches and L first-stage M × M switches are mounted, and L M × M switches in the final stage M switch and L
L printed circuit boards on which (M / 2) consecutive 2 × 1 switches are mounted are housed in the respective shelves, and N (M)
/ 2) 1 × 2 switches 130 # (2i-1) (i = 1
To N), N M × M switches 102 # (2i-1)
(I = 1 to N) and N (M / 2) 2 × 1 switches 132 # (2i-1) (i = 1 to N), N M × M switches 106 # (2i-1) (I = 1 to N) are mounted on the optical XC device.

Each (M / 2) station 1 × 2 switch 130 #
(2i-1) The input transmission line 110 is connected to (M / 2) input terminals of (i = 1 to N), and M × 2 output terminals are connected to (M / 2) output terminals of the M output terminals. M switch 102 # (2
i-1) Connect the input terminals (i = 1 to N).

(M / 2) 2 × 1 switches 132 #
(2i-1) The output transmission line 112 is connected to (M / 2) output terminals of (i = 1 to N), and (M / 2) input terminals of the M input terminals are M × M switch 106 # (2
i-1) Connect the output terminals (i = 1 to N).

In FIG. 8, 131 # (2j-1) (j = N + 1)
To #), 131 # 2j (j = 1 to M) are unused (M /
2) 1 × 2 switches, 133 # (2j-1) (j = N
+1 to M) and 133 # 2j (j = 1 to M) are not used (M
/ 2) 2 × 1 switches.

Thus, the (M / 2) consecutive 1 × 2 switch 130 # (2i−2) used by the optical XC device of the second embodiment is used.
1) (i = 1 to N) and (M / 2) 2 × 1 switch 13
The total number of switch elements such as 2 # (2i-1) (i = 1 to N) is M × N, which is used for the M-series 1 × 2 switch and the M-series 2 × 1 switch in the first embodiment. It can be reduced to half of the number of switch elements (2 × M × N).

FIG. 9 is a diagram showing a configuration example of the second embodiment in the case where M = 8 and the number of input / output ports = 16, and the same elements as those in FIG. Signs are attached. As shown in FIG. 9, when the number of input / output ports = 16, the quadruple 1 × 2 switch 134 # (2i−1) (i = 1
To 4), four quadruple 2 × 1 switches 136 # (2i−
1) Four (i = 1 to 4) are used.

Each 4-unit 1 × 2 switch 134 # (2i-
1) Input transmission lines 11 are connected to four input terminals (i = 1 to 4).
0, and four of the eight output terminals are connected to the input terminals of the 8 × 8 switch 122 # (2i-1). 4 each
2 × 1 switch 136 # (2i-1) (i = 1 to 4)
Are connected to the output transmission line 112, and four of the eight input terminals are connected to the 8 × 8 switch 126 # (2i
-1) Connect to the input terminal.

FIG. 10 shows that M = 8 and the number of input / output ports = 32.
FIG. 10 is a diagram illustrating a configuration example of the second embodiment in the case of (a), and substantially the same components as those in FIG. 9 are denoted by the same reference numerals.

For example, when the number of input / output ports is expanded from 16 to 32, the 4-unit 1 × 2 switch 134 # (2i-1) (i =
5 to 8) and the first stage 8 × 8 switch 122 # i (2
i-1) 4 (i = 5 to 8), 4 final 8 × 8 switches 126 # (2i-1) (i = 5 to 8), quadruple 2
× 1 switch 136 # (2i-1) (i = 5 to 8)
Use more.

FIG. 11 is an explanatory diagram of the effect of the optical XC device of the second embodiment. When M = 8, the number of input / output ports is one.
6, 32, and 64 used in the conventional and the second embodiment.
This is a comparison of the number of 2 (or 1 × 2) switch elements. Description of the related art is omitted because it is the same as that in FIG. (/) In the column of the second embodiment in FIG.
Is (the number of 8 × 8 switches / 4 the number of 1 × 2 (2 × 1) switches).

In the second embodiment, the number of input / output ports = 16
, Four quadruple 1 × 2 switches, four quadruple 2 × 1 switches, four initial 8 × 8 switches, and an intermediate stage 8 ×
The number of eight switches is eight, and the number of final 8 × 8 switches is four. As shown in FIG.
, The conventional 1568, the 1088 of the first embodiment
The number of switch elements is smaller than the number of switch elements. N
= (M / 2), the ratio of the number of switch elements between the prior art and the second embodiment is M = 8, the number of input / output ports =
It becomes the same as the case of 16.

In the second embodiment, when the number of input / output ports is 32, there are eight 4-unit 1 × 2 switches and 4-unit 2 × 1 switches.
8 switches, 8 8 × 8 switches in the first stage, 8 8 × 8 switches in the middle stage, 8 8 × 8 switches in the last stage
As shown in FIG. 11, the number of switch elements is 1600, and the number of switch elements is smaller than 2112 in the related art and 1664 in the first embodiment. Also in the case of N = M, the ratio of the number of switch elements between the prior art and the first embodiment is the same as the case where M = 8 and the number of input / output ports = 32.

When the number of input / output ports is 64, the number of switch elements in the conventional and second embodiments is equal.

Third Embodiment FIG. 12 is a block diagram of an optical XC apparatus according to a third embodiment of the present invention. Elements that are substantially the same as those shown in FIG. I have. The optical XC device of FIG. 12 is a device to which the optical XC device of FIG. 5 is applied when the number of wavelengths is 8 and the number of input / output channels is 16.

The optical XC device shown in FIG. 12 is obtained by adding demultiplexers 140 and 142, wavelength converters 144 and 146, and multiplexers 148 and 150 to the optical XC device shown in FIG. Duplexer 14
Input terminals 0 and 142 are connected to the inter-station input transmission line 110. Output terminals of the multiplexers 148 and 150 are connected to the inter-station output transmission line 112.

The output terminals of the demultiplexers 140 and 142 are 8
1 × 2 switches 120 # 1, 120 # 2, 120 #
Of the eight input terminals of 5,120 # 6, they are connected to four input terminals. Here, optical signals input / output from the intra-station input / output transmission line are omitted, but optical signals input from the intra-station input transmission line are omitted.
As in FIGS. 2 to 4, the optical signal to be input to the input terminal of the M-series 1 × 2 switch via a wavelength converter (not shown) and to be output to the intra-station output transmission line is shown in FIGS. Similarly, an output terminal of the M × 2 switch may be output to the intra-station output transmission line.

Also, the number of 8-unit 1 × 2 switches used may be any four, and there is no particular limitation. Further, it is sufficient to input four wavelengths to the input terminal of each 8 × 1 × 2 switch, and input signal light of an arbitrary wavelength to the input terminal of an arbitrary 8 × 1 × 2 switch, for example, the same 8 × 1 × 2 switch. Switch 14 for switch
The output signal light of the output signals 0 and 142 may be input.

8 × 1 × 2 switches 120 # 1, 120
Eight of the 16 output terminals of each of # 2, 120 # 5, and 120 # 6 are connected to the initial stage 8 × 8 switch 122 #.
1, 122 # 3, 122 # 9 and 122 # 11.

8 × 2 × 1 switches 128 # 1,128
Of the eight output terminals # 2, 128 # 5, 128 # 6, four output terminals are connected to the input terminals of the wavelength converters 144,146. Output terminals of the wavelength converters 144 and 146 are connected to input terminals of the multiplexers 148 and 150. The other points are substantially the same as those in FIG.

The demultiplexers 140 and 142 demultiplex the input wavelength-division multiplexed light into signal light of each wavelength, and can demultiplex the maximum 32-wavelength multiplexed light. Here, since the number of multiplexed wavelengths is 8, the signal lights of wavelengths λ1 to λ4 are input to the 8-unit 1 × 2 switches 120 # 1 and 120 # 5, and the signal lights of wavelengths λ5 to λ8 are connected to 8-unit 1 × 2. The signals are input to switches 120 # 2 and 120 # 6.

Each of the wavelength converters 144 and 146 converts each of the eight input signal lights into signal light having a fixed wavelength of wavelengths λ1 to λ8. The multiplexers 148 and 150 multiplex the output signal lights of the wavelength converters 144 and 146 and output the multiplexed signals.
12 is output.

FIG. 13 is a block diagram of an optical XC device according to the third embodiment of the present invention. Elements that are substantially the same as those in FIG. 6 are given the same reference numerals. Light X in FIG.
The C apparatus is the one to which the optical XC apparatus of FIG. 4 is applied when the number of wavelengths is 16 and the number of input / output channels is 32.

For example, by expanding the number of wavelengths from eight to sixteen,
When the number of input / output channels is 32, the optical XC shown in FIG.
In the device, 8 stations 1 × 2 switches 120 # 3, 120 # 4
120 # 7, 120 # 8, 8 stations 2x1 switch 128 #
3,128 # 4,128 # 7,128 # 8 and wavelength λ9
Wavelength converters 152 and 15 for converting the wavelength into a fixed wavelength
4 is added.

8 × 1 × 2 switches 120 # 3, 120 #
The signal light of wavelengths λ9 to λ12 is input to the input terminal 7. Signal light of wavelengths λ13 to λ16 is input to the input terminals of the 8-unit 1 × 2 switches 120 # 4 and 120 # 8.

8 × 2 × 1 switches 128 # 3, 128 #
7 is converted into signal lights of wavelengths λ9 to λ12. Output signal lights of the 8-unit 2 × 1 switches 128 # 4 and 128 # 8 are converted into signal lights of wavelengths λ13 to λ16.

In the case of the wavelength multiplexed light XC, FIG.
2 and FIG. 13, the light X shown in FIG. 5 and FIG.
It can be seen that C is applicable. It should be noted that the optical XC apparatus of FIG. 2 can be applied to the wavelength multiplexing type optical XC even when the number of input / output channels = (M / 2) × N.

Fourth Embodiment FIG. 14 is a block diagram of an optical XC device according to a fourth embodiment of the present invention. Elements that are substantially the same as those in FIG. 12 are given the same reference numerals. . The optical XC device of FIG. 14 is obtained by applying the optical XC device of FIG. 9 to a wavelength multiplexing XC device having 8 wavelengths and 16 input / output channels.

The optical XC device of FIG. 14 is similar to the optical XC device shown in FIG. 9 except that four 4-unit 1 × 2 switches are replaced with four 4-unit 1 × 2 switches in the optical XC device of FIG. 8 stations 2
It is substantially the same as FIG. 12, except that four quadruple 2 × 1 switches are used instead of the × 1 switches.

FIG. 15 is a block diagram of an optical XC device according to the fourth embodiment of the present invention. Elements that are substantially the same as those in FIG. 12 are given the same reference numerals. Light X in FIG.
The C device is obtained by applying the optical XC device of FIG. 10 to a wavelength multiplexing type XC device having 16 wavelengths and 32 input / output channels.

In the optical XC device of FIG. 15, similarly to the optical XC device shown in FIG. 10, eight 4-unit 1 × 2 switches are used instead of the eight 8-unit 1 × 2 switches in the optical XC device of FIG. Eight eight
It is substantially the same as FIG. 13 except that eight 4 × 2 × 1 switches are used instead of the 2 × 1 switches.

As described above, the optical XC device shown in FIGS. 9 and 10 can be applied to the wavelength multiplexing type optical XC device.

[0113]

According to the present invention, N M-series 1 × 2 switches, N M-series 2 × 1 switches, N initial and final M × M switches, and M intermediate stages Since an optical XC device is constructed using M × M switches, the number of intermediate M × M switches to be used is reduced, and an optical XC device with excellent expandability can be provided.

[Brief description of the drawings]

FIG. 1 is a principle diagram of the present invention.

FIG. 2 is a configuration diagram of an optical XC device according to the first embodiment of the present invention.

FIG. 3 is a diagram showing an M-series 1 × 2 switch in FIG. 2;

FIG. 4 is a diagram showing an M-series 2 × 1 switch in FIG. 2;

FIG. 5 is a diagram illustrating a configuration example of the first embodiment when M = 8 and the number of input / output ports = 16.

FIG. 6 is a diagram illustrating a configuration example of the first embodiment when M = 8 and the number of input / output ports = 32;

FIG. 7 is an explanatory diagram of an effect of the optical XC device according to the first embodiment.

FIG. 8 is a configuration diagram of an optical XC device according to a second embodiment of the present invention.

FIG. 9 is a diagram illustrating a configuration example of a second embodiment when M = 8 and the number of input / output ports = 16.

FIG. 10 shows the second case where M = 8 and the number of input / output ports = 32
It is a figure showing the example of composition of an embodiment.

FIG. 11 is an explanatory diagram of an effect of the optical XC device according to the second embodiment.

FIG. 12 is a configuration diagram of an optical XC device according to a third embodiment of the present invention (part 1).

FIG. 13 is a configuration diagram of an optical XC device according to a third embodiment of the present invention (part 2).

FIG. 14 is a configuration diagram of an optical XC device according to a fourth embodiment of the present invention (part 1).

FIG. 15 is a configuration diagram of an optical XC device according to a fourth embodiment of the present invention (part 2).

FIG. 16 is a diagram showing an optical XC system and an optical network.

FIG. 17 is a diagram showing an optical XC system.

FIG. 18 is a basic configuration diagram of the wavelength multiplexing light XC.

FIG. 19 is a basic configuration diagram of a conventional three-stage optical switch network.

FIG. 20 is a diagram illustrating an example of an optical space switch.

FIG. 21 is a diagram showing a conventional three-stage optical switch network when M = 8 and the number of input / output ports = 16.

FIG. 22 is a diagram showing a conventional three-stage optical switch network when M = 8 and the number of input / output ports = 32.

FIG. 23 is a diagram showing a conventional three-stage optical switch network when M = 8 and the number of input / output ports = 64.

FIG. 24 is a diagram showing a wavelength multiplexing type optical XC using a conventional three-stage optical switch network (part 1).

FIG. 25 is a diagram showing a wavelength multiplexing type optical XC using a conventional three-stage optical switch network (part 2).

FIG. 26 is a diagram illustrating a wavelength multiplexing type optical XC using a conventional three-stage optical switch network (part 3).

[Explanation of symbols]

 80 # i (i = 1 to M) 1 × 2 switch 82 # i (i = 1 to N) M-series 1 × 2 switch 84 # i (i = 1 to N) 1st M × M switch 86 # i (i = 1 to M) Second M × M switch 88 # i (i = 1 to N) Third M × M switch 90 # i (i = 1 to M) 2 × 1 switch 92 # i (i = 1 to N) M 2x1 switch

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Isao Tsuyama 2-3-9 Shin-Yokohama, Kohoku-ku, Yokohama-shi, Kanagawa Prefecture In-house Fujitsu Digital Technology Co., Ltd. 1-chome No. 1 Fujitsu Limited F-term (reference) 5K069 AA13 BA01 BA09 CB04 CB10 DB01 DB31 DB53 EA24 EA26

Claims (5)

[Claims] 1. A first input terminal and two first output terminals, wherein a signal input to the first input terminal is supplied to an arbitrary first output terminal based on a first control signal. M-series 1 × 2 consisting of M (M ≧ 2) 1 × 2 switches output to terminals
N (2 ≦ N ≦ M) switches, M second input terminals and M second output terminals, and inputs to any of the second input terminals based on a second control signal 1M that outputs the output signal to any of the second output terminals.
× N M switches, M third input terminals and M third output terminals, and based on a third control signal, an arbitrary signal input to any of the third input terminals 2M output to the third output terminal of
× M switches, M fourth input terminals and M fourth output terminals, and based on a fourth control signal, any signal input to any of the fourth input terminals 3M output to the fourth output terminal of
An N number of × M switches, two fifth input terminals and one fifth output terminal, and an input input to one of the fifth input terminals based on a fifth control signal And N N M 2 × 1 switches each including M (M ≧ 2) 2 × 1 switches for outputting a signal to the fifth output terminal. For each of the M series 1 × 2 switches, a maximum of M A signal is input to up to / 2 of the first input terminals, and the M first
An output terminal is connected to M second input terminals of the first M × M switch, and M second output terminals of each of the first M × M switches are connected to M of each of the second M × M switches. Connected to a third input terminal, the M fourth input terminals of each of the third M × M switches are connected to the third output terminals of each of the M second M × M switches, and the third M × M switches The M fourth output terminals of the M switch are connected to the fifth input terminal of the M-series 2 × 1 switch, and a maximum of M / 2 fifth output terminals of each of the M-series 2 × 1 switches An optical cross-connect device that outputs an output signal. 2. A method according to claim 1, further comprising: a first input terminal and two first output terminals, wherein a signal input to the first input terminal is arbitrarily selected based on a first control signal. N (2 ≦ N ≦ M) and (M / 2) consecutive 1 × 2 switches composed of (M / 2) (M ≧ 2) 1 × 2 switches to be output to the first output terminal, and M A first M that has a second input terminal and M second output terminals, and outputs a signal input to any of the second input terminals to any of the second output terminals based on a second control signal;
× N M switches, M third input terminals and M third output terminals, and based on a third control signal, an arbitrary signal input to any of the third input terminals 2M output to the third output terminal of
× M switches, M fourth input terminals and M fourth output terminals, and based on a fourth control signal, any signal input to any of the fourth input terminals 3M output to the fourth output terminal of
An N number of × M switches, two fifth input terminals and one fifth output terminal, and an input input to one of the fifth input terminals based on a fifth control signal It is composed of (M / 2) (M ≧ 2) 2 × 1 switches for outputting a signal to the fifth output terminal (M
/ 2) N 2 × 1 switches and (M / 2) 1 × 2 switches (M /
2) the first output terminals are connected to the (M / 2) second input terminals of the first M × M switch, and the M second output terminals of each of the first M × M switches are M Connected to the third input terminal of each of the second M × M switches, and the M fourth input terminals of each of the third M × M switches are connected to the third input terminal of the M second M × M switches. (M / 2) number of the fourth output terminals of each of the third M × M switches are connected to an output terminal of the (M / 2) 2 × 1 switch (M / 2).
The optical cross-connect device is connected to the fifth input terminals, and an output signal is output from the fifth output terminal of each of the (M / 2) 2 × 1 switches. 3. A sixth input terminal to which an input signal having a wavelength multiplexing number K is input, and K sixth output terminals, wherein the input signal is demultiplexed into signals of respective wavelengths. Is output from the corresponding sixth output terminal by L (however, K
× L ≦ (M / 2) × N), a plurality of wavelength converters for wavelength conversion to a predetermined wavelength, and an optical multiplexer for multiplexing the output signal of the wavelength converter. Up to (M / 2) sixth output terminals are the same M
2. The optical cross-connect device according to claim 1, wherein the optical cross-connect device is connected to the first input terminal of a series 1 × 2 switch. 4. It has a sixth input terminal to which an input signal of the wavelength multiplexing number K is inputted, and K number of sixth output terminals. The input signal is demultiplexed into signals of respective wavelengths. Is output from the corresponding sixth output terminal by L (however, K
× L ≦ (M / 2) × N), a plurality of wavelength converters for performing wavelength conversion to a predetermined wavelength, and an optical multiplexer for multiplexing an output signal of the wavelength converter. M / 2) of the sixth output terminals are the same (M /
2) The optical cross-connect device according to claim 2, wherein the optical cross-connect device is connected to the first input terminal of the serial 1 × 2 switch. 5. A first control means for outputting the first control signal so as to output an input signal input to each of the first input terminals to a first output terminal connected to the second input terminal, A second control unit that outputs the fifth control signal so as to output a signal input from each fifth input terminal connected to the fourth output terminal to the fifth output terminal. The optical cross-connect device according to claim 1 or 2, wherein: