JPH08149526A - Optical cross connect switch - Google Patents

Abstract

PURPOSE: To realize the optical cross connect switch in which each optical connect switch adopting the distribution control system makes management of route autonomously. CONSTITUTION: This switch is provided with a branch section 11 branching plural input optical path wavelength multiplex optical signals, a wavelength selection section 12 selecting an optical signal of a prescribed channel from a wavelength multiplex optical signal, a spatial switch section 13 switching each channel optical signal to a corresponding output terminal, a line concentration section 14 concentrating each optical signal and sending the result to a corresponding optical path, a wavelength control circuit 15 superimposing information to control the wavelength selection section 12 and the spatial switch section 13 onto a data signal, sending the result with a control signal of a subcarrier frequency, extracting a control signal of a subcarrier frequency corresponding to each channel from the wavelength multiplex optical signal and setting a transmission wavelength corresponding to each channel to the wavelength selection section 12, and a switch control circuit 16 extracting the control signal of the subcarrier frequency corresponding to each channel from the wavelength multiplex optical signal to set a switching path corresponding to each channel to the spatial switch section 13.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical cross-connect switch for switching between channels in a wavelength division multiplexing communication network for multiplexing and transmitting different information for each wavelength using a plurality of wavelengths.

[0002]

2. Description of the Related Art FIG. 6 shows an example of an optical path network. In the figure, an optical cross-connect switch is arranged at a node 42 connecting each optical path 41. The optical path 41 is a bundle of channels through which information is transmitted, and is switched by an optical cross connect switch. This channel is the wavelength of the optical carrier, and a plurality of pieces of information are multiplexed and transmitted using different wavelengths (channels) (wavelength multiplexing system).

FIG. 7 shows a configuration example of a conventional optical cross connect switch in a wavelength division multiplexing communication network. In the figure,
The wavelength-multiplexed optical signals of the wavelengths λ ₁ , λ ₂ , and λ ₃ of the input optical path 51-1 are branched into three by the optical coupler 52-1 and input to the variable wavelength filters 53-1, 53-3, 53-5, respectively. To be done. The wavelength-multiplexed optical signals of the wavelengths λ ₄ and λ ₅ of the input optical path 51-2 are branched into three by the optical coupler 52-2 and input to the tunable wavelength filters 53-2, 53-4, 53-6, respectively. Each tunable filter selects one of the input wavelengths.
The outputs of the tunable wavelength filters 53-1 and 53-2 are passed through the 2 × 2 optical switch 54-1 and tunable wavelength filter 53
The outputs of the variable wavelength filters 53-5 and 53-6 are 2 through the 2 × 2 optical switch 54-2.
Output optical paths 56-1 and 56-2 are distributed to either one of the optical couplers 55-1 and 55-2 via the × 2 optical switch 54-3 and are concentrated by the respective optical couplers.
Sent to

On the other hand, variable wavelength filters 53-1 to 53-
The wavelength selected in 6 and the switching pattern of the optical switches 54-1 to 54-3 are collectively controlled by the operation management center 57. Here, the variable wavelength filter 53-1
To 53-5, transmission wavelengths λ ₂ , λ ₄ , λ ₁ , λ, respectively.
Set ₅ and λ ₃ . Moreover, the optical switches 54-1 to 54
-3 switching patterns are set to the bar state, the cross state, and the cross state, respectively. Thereby, for example, the channel 1 (λ ₁ ) of the input optical path 51-1 is switched to the output optical path 56-2 via the variable wavelength filter 53-3 and the optical switch 54-2. Also, the input optical path 51
-Channel 4 (λ ₄ ) of -2 is tunable wavelength filter 53-
2. Output optical path 56-2 via the optical switch 54-1
Is switched to.

[0005]

Conventionally, when it is necessary to switch the path in the network, the operation management center of the network determines the path to be switched. The operation management center generates a command for the optical cross connect switch that executes switching between physical transmission lines, and sends the control signal to the optical cross connect switch. In each optical cross-connect switch, the transmission wavelength of the variable wavelength filter is set according to this control signal, and the optical path of the optical switch is switched.

In the conventional configuration in which the operation management center performs such control, a signal line from the operation management center to each node is required. Moreover, since the operation management center is configured to centrally manage the paths of the entire network, it is vulnerable to the occurrence of a failure. It is an object of the present invention to provide an optical cross connect switch in which individual optical cross connect switches can autonomously perform route management by a distributed control method.

[0007]

According to the present invention, a branching unit for branching wavelength-division-multiplexed optical signals of a plurality of input optical paths into a number of channels or more, and a transmission wavelength selected from the wavelength-division-multiplexed optical signals branched by the branching unit. The wavelength selection unit that selects the optical signal of a predetermined channel by doing so, the space switch unit that switches the optical signal of each channel to the corresponding output end, and the output optical path that collects the optical signal of each output end In an optical cross-connect switch equipped with a concentrating unit for transmitting to a channel, the information for controlling the wavelength selecting unit and the space switching unit is superimposed on the data signal and transmitted by the control signal of the subcarrier frequency, and each channel is transmitted from the wavelength multiplexed optical signal. A wavelength control circuit that extracts the control signal of the corresponding subcarrier frequency and sets the transmission wavelength corresponding to each channel in the wavelength selection unit, and each channel pair from the wavelength multiplexed optical signal. Of extracting the control signal of the sub-carrier frequency, and a switch control circuit which sets the space switch section each channel corresponding switching path.

The wavelength control circuit and the switch control circuit include a photodetector for converting an input wavelength-multiplexed optical signal into an electric signal, and a subcarrier reception for extracting and demodulating a subcarrier component corresponding to each channel from the electric signal. And a control processor that generates, from the demodulated signal, transmission wavelength information corresponding to the channel set in the wavelength selection unit and optical path information set in the spatial switch unit.

[0009]

In the optical cross-connect switch, the wavelength-multiplexed optical signal of each input optical path is branched into more than the number of channels, the predetermined wavelength is selected by the wavelength selection unit, and the optical path of each channel is switched by the spatial switch unit. By concentrating the optical signals of the channels output to the same output optical path of
Switching between predetermined optical paths is performed.

In the optical cross connect switch of the present invention,
Information for controlling the wavelength selection unit and the space switch unit is superimposed on the data signal and transmitted as a control signal of the subcarrier frequency. Therefore, the wavelength control circuit and the switch control circuit extract the control signal of the subcarrier frequency corresponding to each channel to control the wavelength selection unit and the space switch unit, so that each optical cross-connect switch autonomously switches the channel. Can be routed.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows the principle configuration of an optical cross connect switch of the present invention. In the figure, the optical cross-connect switch includes a branching unit 11 for branching the wavelength-multiplexed optical signals of the input optical paths 51-1 to 51-n to the number of wavelengths (the number of channels) or more, and each channel by selecting a transmission wavelength. A wavelength selecting unit 12 for selecting a signal, a space switch unit 13 for switching an optical signal of each channel to a corresponding output end,
Output optical path 56-
1 to 56-n.

A feature of the present invention is that the information for controlling the wavelength selecting unit 12 and the space switching unit 13 is transmitted simultaneously with the data signal by the control signal of the subcarrier frequency. The wavelength control circuit 15 extracts the control signal of the subcarrier frequency and sets the transmission wavelength corresponding to each channel in the wavelength selection unit 12.
The switch control circuit 16 extracts the control signal of the subcarrier frequency and sets the switching path corresponding to each channel in the space switch unit 13.

FIG. 2 shows the configuration of an embodiment of the optical cross connect switch of the present invention. In the figure, a branching unit is an optical coupler 52-1 corresponding to the input optical paths 51-1 and 51-2.
52-2. The wavelength selection unit includes variable wavelength filters 53-1 to 53-6. The space switch unit is composed of 2 × 2 optical switches 54-1 to 54-3. The concentrator has output optical paths 56-1 and 56-.
It is composed of optical couplers 55-1 and 55-2 corresponding to 2.

The wavelength-multiplexed optical signals (ch.1 to ch.3) of the wavelengths λ ₁ , λ ₂ , and λ ₃ of the input optical path 51-1 are sent to the optical amplifiers 17-1,
It is input to the optical coupler 52-1 via the optical tap 18-1, and is branched into three at the variable wavelength filter 53-.
1, 53-3, 53-5. Input optical path 51
-2 wavelength multiplexed optical signals with wavelengths λ ₄ and λ ₅ (ch.1, ch.4)
Is input to the optical coupler 52-2 via the optical amplifier 17-2 and the optical tap 18-2, and then branched into three and input to the variable wavelength filters 53-2, 53-4, 53-6, respectively.

The optical signals split by the optical taps 18-1 and 18-2 are input to the wavelength control circuit 15 and the switch control circuit 16. Each variable wavelength filter 53-1
The transmission wavelength of 53-6 is set to any one of λ ₁ to λ ₅ by the control of the wavelength control circuit 15. The outputs of the variable wavelength filters 53-1 and 53-2 are 2 × 2 optical switches 54.
-1 is input. Variable wavelength filters 53-3, 53-
The output of No. 4 is input to the 2 × 2 optical switch 54-2.
The outputs of the variable wavelength filters 53-5 and 53-6 are input to the 2 × 2 optical switch 54-3. Each optical switch is set to the bar state or the cross state by the control of the switch control circuit 16. The two outputs of each optical switch are input to the optical couplers 55-1 and 55-2, respectively, concentrated by each optical coupler and sent to the corresponding output optical paths 56-1 and 56-2.

Each of the variable wavelength filters 53-1 to 53-6 has a subcarrier frequency fi as an address.
(i = 1, 2, ..., 6) is assigned. Optical switch 54
In -1 to 54-3, subcarrier frequencies fjb and fjc (j = 1, 1) for setting the bar state or the cross state, respectively.
2, 3) are assigned. It should be noted that these subcarrier frequencies are changed at any time according to the increase or decrease in the number of channels.

The spectrum of the optical signal is as shown in FIG.
It is divided into baseband data of frequency f ₀ and control signals of the above subcarrier frequencies fi, fjb, fjc. The subcarriers are respectively modulated with wavelength information for controlling the variable wavelength filter and optical path information for controlling the optical switch and superimposed on the baseband payload data and input to the optical cross connect switch.

When an optical signal is input to the optical cross connect switch, the wavelength control circuit 15 and the switch control circuit 1
At 6, the modulated signal of the subcarrier frequency is demodulated. Based on the information, the wavelength control circuit 15 sets the transmission wavelength corresponding to the channel in the variable wavelength filter corresponding to the subcarrier frequency, and transmits the optical signal of the predetermined channel. The switch control circuit 16 sets the optical path of the optical switch according to the subcarrier frequency based on the information, and guides the optical signal to a predetermined output terminal.

In this embodiment, channels 1 and 3 of the input optical path 51-1 are connected to the output optical path 56-2, channel 2 of the input optical path 51-1 is connected to the output optical path 56-1,
Channel 4 of the input optical path 51-2 is output to the output optical path 56-2
, And the channel 5 of the input optical path 51-2 is connected to the output optical path 56-1. In this case, the subcarrier frequencies of the optical signals of channel 1 (λ ₁ ) to channel 5 (λ ₅ ) are set as shown in Table 1.

[0020]

[Table 1]

For example, in the case of channel 1 (λ ₁ ) of the input optical path 51-1, subcarriers of frequencies f3 and f2c are superposed on the optical signal, and the transmission wavelengths of the variable wavelength filter 53-3 are respectively It is set to λ _1, light switch 54 -
Set 2 to the cross state. This allows the output optical path 5
6-2 is routed to channel 8 (λ ₁ ). Also,
In the case of channel 4 (λ ₄ ) of the input optical path 51-2, subcarriers of frequencies f2 and f1b are superimposed on the optical signal, and the transmission wavelength of the tunable wavelength filter 53-2 is λ.
₄ and the optical switch 54-1 is set to the bar state. This causes channel 10 of output optical path 56-2 to
It is routed to (λ ₄ ).

At this time, routing is required so that channels forming the same optical path do not collide at the output end of the optical switch. The optical signal for controlling the cross-connect is generated based on the control information from the operation management center in the node close to the optical cross-connect switch, unlike the conventional centralized management method by the operation management center.
It is transmitted to the optical cross connect switch.

FIG. 4 shows a configuration example of the wavelength control circuit 15. In the figure, an optical signal is converted into an electric signal by a light receiver 21 and received by a subcarrier receiver 22. The subcarrier receiver 22 includes a local oscillator 23, a mixer 24, a bandpass filter (BPF) 25, and a subcarrier demodulator 26. Here, only the subcarrier component is extracted and demodulated. The demodulated signal is input to the control processor 27, and each variable wavelength filter 53-1 to 5-3 is input.
The transmission wavelength corresponding to 53-5 is set. The switch control circuit 16 has a similar configuration, and each optical switch 5
Optical paths corresponding to 4-1 to 54-3 are set.

By the way, in the optical cross-connect switch of the present invention, it is easy to set a detour when a network failure occurs or when traffic is congested. FIG. 5 shows how the path is changed when a failure occurs in the transmission path.
Node 3 via optical cross-connect switch 31-1
When a failure occurs in the path A from 2-1 to the node 32-2, a new optical cross connect switch 31-1,
It is possible to easily change to the path B passing through 31-2.

[0025]

As described above, the optical cross-connect switch of the present invention receives the control signal of the sub-carrier frequency including the information necessary for routing, so that each optical cross-connect switch autonomously performs the optical operation. You can switch between paths. Therefore, unlike the conventional centralized management method by the operation management center, it is possible to easily perform detour control when a network failure occurs or traffic congestion occurs.

[Brief description of drawings]

FIG. 1 is a diagram showing a principle configuration of an optical cross-connect switch of the present invention.

FIG. 2 is a diagram showing a configuration of an optical cross connect switch according to an embodiment of the present invention.

FIG. 3 is a diagram showing an arrangement example of main carriers and subcarriers.

FIG. 4 is a diagram showing a configuration example of a wavelength control circuit 15.

FIG. 5 is a diagram for explaining how a path is changed when a failure occurs in a transmission path.

FIG. 6 is a diagram showing an example of an optical path network.

FIG. 7 is a diagram showing a configuration example of a conventional optical cross connect switch in a wavelength division multiplexing communication network.

[Explanation of Codes] 11 Branching Section 12 Wavelength Selection Section 13 Spatial Switching Section 14 Concentrating Section 15 Wavelength Control Circuit 16 Switch Control Circuit 17 Optical Amplifier 18 Optical Tap 21 Photoreceptor 22 Subcarrier Receiver 23 Local Oscillator 24 Mixer 25 Bandpass Filter (BPF) 26 Subcarrier demodulator 31 Optical cross-connect switch 32, 42 Node 41 Optical path 51 Input optical path 52, 55 Optical coupler 53 Variable wavelength filter 54 Optical switch 56 Output optical path 57 Operation management center

Claims (2)

[Claims] 1. A branching unit for branching wavelength-multiplexed optical signals of a plurality of input optical paths into a number of channels or more, and a predetermined channel by selecting a transmission wavelength from the wavelength-multiplexed optical signals branched by the branching unit. A wavelength selecting unit that selects an optical signal of the optical signal, a space switch unit that switches the optical signal of each channel selected by the wavelength selecting unit to a corresponding output end, and the optical signal of each output end is concentrated to correspond. In an optical cross-connect switch having a concentrating unit for sending to an output optical path, information for controlling the wavelength selecting unit and the space switching unit is superimposed on a data signal and transmitted by a control signal of a subcarrier frequency, A wavelength control circuit for extracting a control signal of a subcarrier frequency corresponding to each channel from an optical signal and setting a transmission wavelength corresponding to each channel in a wavelength selection unit, and the wavelength An optical cross-connect switch, comprising: a switch control circuit that extracts a control signal of a subcarrier frequency corresponding to each channel from a multiplexed optical signal and sets a switching path corresponding to each channel in a space switch unit. 2. The optical cross-connect switch according to claim 1, wherein the wavelength control circuit and the switch control circuit include a photodetector for converting an input wavelength-multiplexed optical signal into an electric signal and a channel corresponding to each channel from the electric signal. A subcarrier receiver that extracts and demodulates a subcarrier component, and a control processor that generates from the demodulated signal the transmission wavelength information corresponding to the channel set in the wavelength selection unit and the optical path information set in the spatial switch unit are provided. An optical cross-connect switch characterized by that.