JP2667315B2 - Optical matrix switch - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical matrix switch.

[0002]

2. Description of the Related Art An optical matrix switch is configured by arranging a plurality of optical switch elements for selectively switching a transmission path of an input optical signal in a matrix.
As such a matrix switch, for example, Reference 1:
Optical FiberCommunicatio
n 1989 OSA Technical Di-g
est (Optical Fiber Communication 1989 OSA Technical Digest) vol. 2 THB2.

FIG. 4 is a plan view schematically showing the structure of this conventional optical matrix switch. The optical matrix switch shown in FIG. 1 has two 4 × 4 matrix units 10, eight 1 × 2 input-side optical switch elements 12, and eight 2 × 1 output-side optical switch elements 14 on a substrate 16. Consisting of Each matrix unit 10 has 2 × 2 optical switching elements 18 in 4 rows and 4 units.
Arranged in rows.

This conventional optical matrix switch is a rearrangement non-blocking type, and an optical switch through which an optical signal passes while an optical signal whose transmission path is to be switched is input to the optical matrix switch and output from the optical matrix switch. The number of elements can be reduced, and when a plurality of optical signals are input to an optical switch matrix switch, these optical signals are transmitted through different optical switch elements and output from the optical switch matrix switch, thereby transmitting these optical signals. It has the feature that the path can be switched, and has the advantage that crosstalk can be reduced by these features.

[0005]

However, the above-mentioned conventional optical matrix switch has a problem that the number of optical switch elements required for forming the matrix section is large, and the configuration is complicated.

An object of the present invention is to provide an optical matrix switch capable of reducing the number of optical switch elements required for forming an optical matrix switch in order to solve the above-mentioned conventional problems.

[0007]

In order to achieve this object, an optical matrix switch according to the present invention comprises two 4 × 4 switches.
It includes a matrix section, eight 1 × 2 input-side optical switch elements, and eight 2 × 1 output-side optical switch elements.

In the optical matrix switch of the present invention, two input-side optical switch elements are individually associated with the inputs of one matrix unit, and the inputs of one matrix unit and the inputs corresponding to the inputs of the matrix unit are connected. One output of the side optical switch element is connected, and two input side optical switch elements are individually associated with the inputs of the other matrix section, corresponding to the inputs of the other matrix section and the inputs of the matrix section. The input side optical switch element is connected to the other output of the input side optical switch element.

Further, in the optical matrix switch according to the present invention, two output-side optical switch elements are individually associated with the output of one of the matrix sections, and the output of one of the matrix sections and the output corresponding to the output of the matrix section are provided. One input of the side optical switch element is connected, and two output side optical switch elements are individually associated with the output of the other matrix unit, and the output of the other matrix unit corresponds to the output of the matrix unit. It has a configuration in which the other input of the output side optical switch element is connected.

Further, the matrix section has a plurality of 2 × 2 optical switch elements constituting a banyan network.

[0011]

According to this structure, the matrix section has a plurality of 2.times.2 optical switch elements forming a banyan network. The banyan net is composed of a plurality of optical switch elements arranged in 4 rows and 3 columns, and therefore, the number of optical switch elements required for forming the matrix section can be reduced.

Further, according to the consideration of the inventor of this application,
The number of optical signals to be input to the banyan network is set to four or less, two optical signals are not simultaneously input to the optical switch element of the input stage (first column) of the banyan network, and the output stage (the If two optical signals are not simultaneously input to the optical switch element in the third column), the banyan network can be operated without blocking. Therefore, even if an optical matrix switch is configured using a banyan network, an optical matrix switch that operates without blocking can be configured.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. The drawings are only schematically shown to the extent that the present invention can be understood.

FIG. 1 is a plan view schematically showing the configuration of an embodiment of the present invention. As shown in the figure, the optical matrix switch 17 of this embodiment has two 4 × 4 matrix units 18, eight 1 × 2 input-side optical switch elements 20, and eight 2 × 1 output-side optical switches. The matrix section 18, the input-side optical switch element 20, and the output-side optical switch element 22 are provided on a substrate 24.

The matrix section 18 has a plurality of 2 × 2 optical switch elements 26 constituting a banyan network, and these optical switch elements 26 are arranged in four rows and three columns. The matrix section 18 includes element groups a and b. The two optical switch elements 26 in the first column and the two optical switch elements 26 in the second column of the matrix section 18 are composed of the element group a and the first column. The remaining two other optical switch elements 26 and the other two
The optical switching elements constitute an element group b. One and the other optical switch elements 26 in the first row of the element group a are connected to two optical switch elements 26 in the second row of the element group a, respectively. The other two optical switch elements 26 in the third column of the matrix section 18 are connected to the two optical switch elements 26 in the third row of the matrix section 18 and the other optical switch elements 26 in the second row of the element group a. Connect with Similarly, one and the other optical switch elements 26 of the first row of the element group b are connected to the two optical switch elements 26 of the second row of the element group b, respectively, and one optical switch of the second row of the element group b is further connected. The element 26 is connected to the two optical switch elements 26 in the third column of the matrix section 18 and the element group b
The other optical switch element 26 in the second column is the matrix section 18
It is connected to the other two optical switch elements 26 in the third row.

4 of the input stage (first column) of the matrix section 18
Each of the two optical switch elements 26 is a two-input two-output optical switch and four optical switch elements 2 in an output stage (third column).
Reference numerals 6 denote optical switches each having two inputs and two outputs. Therefore, the Banyan network of the matrix unit 18 can be used as eight inputs and eight outputs. However, in order to operate the Banyan network without blocking, two optical signals are not simultaneously input to the optical switch elements 26 in the input stage and the output stage.
The Banyan network of the matrix section 18 is used as 4 inputs and 4 outputs.

Then, one of the matrix portions 18 (18
Two input optical switch elements 20 are individually associated with the input of 1), and the input of one matrix unit 181 and one output of the input optical switch element 20 corresponding to the input of the matrix unit 181 are associated with each other. Connecting. More specifically, the optical switch element 2 at the input stage of the matrix section 181
Input side optical switch elements 20 each of which is 6
, And one output of the corresponding input-side optical switch element 20 is connected to one input of the optical switch element 26 of the input stage.

The input of the other matrix section 18 (182) is individually and two-input optical switch elements 2 each.
The input of the other matrix unit 182 is connected to the other output of the input side optical switch element 20 corresponding to the input of the matrix unit 182. More specifically,
Two input-side optical switch elements 20 are individually associated with the input-stage optical switch elements 26 of the matrix section 182, and the corresponding input-side optical switch element 20 is associated with the other input of the input-stage optical switch element 26. Connect the other output of. Therefore, the optical switch element 26 at the input stage of one matrix unit 181 and the optical switch element 26 at the input stage of the other matrix unit 182 are connected to one input side optical switch element 20.

Further, two output-side optical switch elements 22 are individually associated with the output of one matrix section 181 respectively, and the output of one matrix section 181 and the output-side optical switch element corresponding to the output of the matrix section 181 are provided. 2
2 is connected to one input. More specifically, two output-side optical switch elements 22 are individually associated with the optical switch elements 26 at the output stage of the matrix unit 181, respectively.
One input of the corresponding output-side optical switch element 22 is connected to one output of the optical switch element 26 in the output stage.

The output of the other matrix section 182 is individually associated with two output-side optical switch elements 22, and the output of the other matrix section 182 and the output-side optical switch element corresponding to the output of the matrix section 182. 22
To the other input of More specifically, two output-side optical switch elements 22 are individually associated with the output-stage optical switch elements 26 of the matrix unit 182, and correspond to the other output of the output-stage optical switch elements 26. The other input of the output side optical switch element 22 is connected.
Therefore, for one output-side optical switch element 20, the optical switch element 26 at the output stage of one matrix unit 181 and the optical switch element 26 at the output stage of the other matrix unit 182 are provided.
And connect.

The optical matrix switch 17 of this embodiment having the above configuration is an 8 × 8 optical matrix switch. In this optical matrix switch 17, when eight optical signals are input to the optical matrix switch 17, four optical signals are input to one matrix unit 181 and the remaining four optical signals are input to the other matrix unit 182. As shown in FIG.
They are distributed to the matrix units 181 and 182 one by one. Then, by operating the matrix units 181 and 182 in a non-blocking state, the optical matrix switch 17 can be operated in a non-blocking state.

While the total number of optical switch elements required to construct the conventional 8 × 8 optical matrix switch is 48, it is necessary to construct the 8 × 8 optical matrix switch of this embodiment. The total number of optical switching elements is 40, so that the total number of optical switching elements can be reduced as compared with the conventional case.

FIG. 2 is a plan view schematically showing a configuration of an application example of the present invention, and shows a configuration of a 16 × 16 optical matrix switch configured using the 8 × 8 optical matrix switch 17 of FIG. . The components corresponding to the components of the optical matrix switch 17 described above are denoted by the same reference numerals, and detailed description thereof will be omitted.

The 16 × 16 optical matrix switch 28 shown in FIG. 2 has 16 1 × 2 input side optical switch elements 30,
It comprises two optical matrix switches 17 and 16 2 × 1 output side optical switch elements 32, and these input side optical switch elements 30, optical matrix switch 17 and output side optical switch elements 32 are provided on a substrate 24.

In this example, the input optical switch element 20 and the output optical switch element 2 of the optical matrix switch 17 are used.
2 is a 2 × 2 optical switch element. In this case, the optical matrix switch 17 can be used as a 16-input, 16-output optical matrix switch.
The two optical signals are not simultaneously input to the input side optical switch element 20 and the two optical signals are not simultaneously input to the 2 × 2 output side optical switch element 22, and the optical matrix switch 17 is used as eight inputs and eight outputs. . Otherwise, the configuration of the optical matrix switch 17 in FIG. 2 is the same as the configuration of the optical matrix switch 17 in FIG.

Then, one of the optical matrix switches 17
Two input optical switch elements 30 are individually associated with the input optical switch element 20 of (171), and one input of the input optical switch element 20 of one optical matrix switch 171 and the input optical switch A switch is connected to one output of the input side optical switch element 30 corresponding to the switch element 20. The other optical matrix switch 17 (17
Two input optical switch elements 30 are individually associated with the input optical switch element 20 of 2), and the other input of the input optical switch element 20 of the other optical matrix switch 172 and the input optical switch The other output of the input side optical switch element 30 corresponding to the element 20 is connected. Accordingly, one input side optical switch element 30 is connected to one input side optical switch element 20 of one optical matrix switch 171 and one input side optical switch element 20 of the other optical matrix switch 172.

Further, one of the optical matrix switches 17
One output-side optical switch element 22 is individually associated with two output-side optical switch elements 32, and one output of one output-side optical switch element 22 of one optical matrix switch 171 and the output-side optical switch element 22 is connected to one input of the output side optical switch element 32.
Also, two output-side optical switch elements 32 are individually associated with the output-side optical switch elements 22 of the other optical matrix switch 172, respectively.
The other output of the output side optical switch element 22 of 72 is connected to the other input of the output side optical switch element 32 corresponding to the output side optical switch element 22. Therefore, one output-side optical switch element 22 is connected to one output-side optical switch element 22 of one optical matrix switch 171 and one output-side optical switch element 22 of the other optical matrix switch 172.

The 16 × 16 optical matrix switch 28 of this application example can also be operated without blocking, and the number of optical switch elements required to configure the optical matrix switch 28 can be reduced.

FIG. 3 is a plan view schematically showing a configuration of another application example of the present invention. The configuration of the 32 × 32 optical matrix switch constituted by using the 16 × 16 optical matrix switch 28 of FIG. Is shown. The components corresponding to the components of the optical matrix switch 28 described above are denoted by the same reference numerals, and detailed description thereof will be omitted.

The 32 × 32 optical matrix switch 33 shown in FIG. 3 has 32 1 × 2 input side optical switch elements 34,
It comprises two optical matrix switches 28 and 32 2 × 1 output side optical switch elements 36, and these input side optical switch elements 34, optical matrix switch 28 and output side optical switch elements 36 are provided on the substrate 24.

In this example, the input side optical switch element 30 and the output side optical switch element 3 of the optical matrix switch 28
2 is a 2 × 2 optical switch element. In this case, the optical matrix switch 28 can be used as a 32-input, 32-output optical matrix switch.
The input side optical switch element 30 is prevented from simultaneously inputting two optical signals, and the 2 × 2 output side optical switch element 32 is prevented from simultaneously inputting two optical signals, and the optical matrix switch 28 is used as 16 inputs and 16 outputs. . Other than this, the configuration of the optical matrix switch 28 of FIG. 3 is shown in FIG.
The configuration is the same as that of the optical matrix switch 28.

The one optical matrix switch 28
Two input-side optical switch elements 34 are respectively associated with the input-side optical switch elements 30 of (281), and one input of the input-side optical switch element 30 of one optical matrix switch 281 and the input-side light One output of the input side optical switch element 34 corresponding to the switch element 30 is connected. The other optical matrix switch 28 (28
2) Input optical switch elements 34 are individually associated with the input optical switch elements 30 of 2), and the other input of the input optical switch element 30 of the other optical matrix switch 282 and the input optical switch 30 The other output of the input side optical switch element 34 corresponding to the element 30 is connected. Therefore, one input side optical switch element 34 is connected to one input side optical switch element 30 of one optical matrix switch 281 and one input side optical switch element 30 of the other optical matrix switch 282.

Further, one of the optical matrix switches 28
One output-side optical switch element 32 is individually associated with two output-side optical switch elements 36, and one output of the output-side optical switch element 32 of one optical matrix switch 281 and the output-side optical switch element 32 is connected to one input of the output side optical switch element 36 corresponding to 32.
Also, two output-side optical switch elements 36 are individually associated with the output-side optical switch elements 32 of the other optical matrix switch 282, respectively.
The other output of the output-side optical switch element 82 and the other input of the output-side optical switch element 36 corresponding to the output-side optical switch element 32 are connected. Therefore, one output-side optical switch element 36 is connected to one output-side optical switch element 32 of one optical matrix switch 281 and one output-side optical switch element 32 of the other optical matrix switch 282.

The 32 × 32 optical matrix switch 33 of this application example can also be operated without blocking, and the number of optical switch elements required to configure the optical matrix switch 33 can be reduced.

As can be understood from the application examples of FIGS. 2 and 3, a non-blocking type N × N optical matrix switch (where N is a multiple of 8) is used by using the optical matrix switch 17 of the embodiment of the present invention. Can be configured. In addition, the total number Z of optical switch elements required to constitute this N × N optical matrix switch is Z = −N + 2 · N · log ₂ N.

The present invention is not limited to the above-described embodiment, and accordingly, the arrangement position, shape,
The connection relationship and others can be arbitrarily changed.

[0037]

As is apparent from the above description, according to the optical matrix switch of the present invention, the matrix section has a plurality of 2.times.2 optical switch elements constituting a banyan network. The banyan net is composed of a plurality of optical switch elements arranged in 4 rows and 3 columns, and therefore, the number of optical switch elements required for forming the matrix section can be reduced.

Furthermore, the number of optical signals input to the banyan network is set to four or less, and two optical signals are not simultaneously input to the optical switch element at the input stage (first column) of the banyan network. If two optical signals are not simultaneously input to the optical switch element in the output stage (third column), the banyan network can be operated without blocking. Therefore, even if an optical matrix switch is configured using a banyan network, an optical matrix switch that operates without blocking can be configured.

[Brief description of the drawings]

FIG. 1 is a plan view schematically showing a configuration of an embodiment of the present invention.

FIG. 2 is a plan view schematically showing a configuration of an application example of the present invention.

FIG. 3 is a plan view schematically showing a configuration of another application example of the present invention.

FIG. 4 is a plan view schematically showing a configuration of a conventional optical matrix switch.

[Explanation of symbols]

 18, 181 and 182: matrix section 20: input side optical switch element 22: output side optical switch element 24: substrate 26: optical switch element

Claims (1)

(57) [Claims] 1. Two 4 × 4 matrix parts, eight 1 ×
It has two input-side optical switch elements and eight 2 × 1 output-side optical switch elements, and two input-side optical switch elements are individually associated with the input of one matrix unit, respectively. One output of the input-side optical switch element corresponding to the input of the matrix unit is connected, and two input-side optical switch elements are individually associated with the input of the other matrix unit, and the input of the other matrix unit is input. And the other output of the input side optical switch element corresponding to the input of the matrix section, and two output side optical switch elements are individually associated with the output of one matrix section, respectively. The output is connected to one input of an output-side optical switch element corresponding to the output of the matrix unit, and two outputs are individually connected to the output of the other matrix unit. In an optical matrix switch in which switch elements are associated with each other and the output of the other matrix unit is connected to the other input of the output side optical switch element corresponding to the output of the matrix unit, the matrix unit constitutes a banyan network Multiple 2x
An optical matrix switch comprising two optical switch elements.