JPH0276497A - Light exchange - Google Patents

Abstract

PURPOSE:To attain the constitution of a large scale light exchange without using a large scale light matrix switch by combining plural star couplers, plural light matrix switches and a wavelength selecting filter. CONSTITUTION:When a transmitting receiving edge station 1a is made to be a transmitting side and a transmitting receiving edge 1e be a receiving side, light wavelengths lambda1 to lambdan transmitted by the edge station 1a are inputted respectively to a light matrix switch 3a. The output of the switch 3a is individually inputted to a star coupler 4, and a multiple signal to overlap light wavelengths lambda1 to lambdan are inputted from each coupler 4 to a switch 3b. The switch 3b selects either of the coupler 4 and outputs the signal to an edge station 1b. The selected signal is a multiple signal, and the edge station 1b selects and outputs an arbitrary wavelength component only in the multiple signal by a wavelength filter having a wavelength selecting function.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an optical switching system that electrically controls the connections of optical signal paths between a plurality of input ports and a plurality of output ports.

[Conventional technology]

Time-division multiplexing and frequency-division multiplexing are methods for efficiently transmitting multiple pieces of information over a single transmission path, but optical fiber transmission also uses space-division multiplexing, wavelength-division multiplexing, etc. new transmission formats are possible.

Space division multiplexing transmission is a transmission form obtained by laying a large number of optical fibers in a limited space by utilizing the small diameter of the optical fibers. An optical matrix switch is one of the replenishing TFLs used in this transmission form.

Furthermore, wavelength division multiplexing transmission is a transmission form in which a plurality of optical signals having different wavelengths are transmitted through a single optical fiber. As an optical switch of this type, for example, Japanese Patent Laid-Open No. 62
There is one disclosed in JP-206531. This optical switch consists of an optical distribution circuit that distributes optical signals of a plurality of different wavelengths to N optical waveguides, and an optical wavelength filter with a variable transmission wavelength that allows only arbitrary wavelength components of the distributed optical signals to pass through. , eight optical wavelength converters that convert the light that has passed through this optical wavelength filter into a specific wavelength, and an optical multiplexing circuit that combines the output signals of these optical wavelength converters and guides them to one output waveguide. It consists of.

[Problem to be solved by the invention]

However, in the space division multiplexing transmission, optical switching is performed using an optical matrix switch, which requires a large-scale optical matrix switch, and there is a problem in that it is difficult to manufacture such an optical matrix switch.

In addition, in the wavelength division multiplex transmission optical switch, optical signals multiplexed by the number of lines must be divided, and an optical wavelength filter that divides wavelengths at a high density is required. However, it is technically difficult to manufacture such an optical wavelength filter, and a practical element that performs wavelength switching between many wavelengths has not been obtained.

Therefore, the present invention has been made to solve the problems of the prior art as described above, and its purpose is to:
The purpose of the present invention is to provide a large-scale optical exchange with a simple configuration using a small-scale optical matrix switch and relatively low wavelength multiplexing.

[Means to solve the problem]

The optical switching device according to the present invention has a plurality of input terminals and a plurality of output terminals, and when an optical signal of a different wavelength is input to each of the plurality of input terminals, the A plurality of star couplers output multiplexed signals in which optical signals of different wavelengths are superimposed, and the multiplexed signals output from the plurality of star couplers are input one by one from each star coupler, and the multiplexed signals that are input are From among the signals, a plurality of optical matrix switches that select and output a plurality of multiplexed signals and a multiplexed signal that selects and outputs one of the plurality of optical matrix switches are input, and among the input multiplexed signals, It is characterized by having a plurality of wavelength selection filters that select and output only arbitrary wavelength components.

[For production]

In the present invention, the star coupler inputs optical signals of different wavelengths to each of its plurality of input terminals, and outputs a multiplexed signal in which the optical signals of different wavelengths are superimposed to each of its plurality of output terminals. It is equipped with multiple such star couplers.

The optical matrix switch inputs the multiplexed signals output from the star couplers one by one from each star coupler, and selects and outputs one or more multiplexed signals from these input multiplexed signals.

A plurality of such optical matrix switches are provided.

Further, the wavelength selection filter inputs the multiplexed signal output from the optical matrix switch, selects and outputs only an arbitrary wavelength component from the inputted multiplexed signal. Such wavelength selection filters are provided with c- the number of output ends of each optical matrix switch.

In this way, by combining multiple optical matrix switches, multiple star couplers, and wavelength selection filters, it is possible to use a smaller optical matrix switch than, for example, when an optical exchange is configured only with optical matrix switches. can do. This is because the combination of the star coupler and the wavelength selection filter in the above configuration can function similarly to an optical matrix switch (separate from the optical i-mix switch, which is the configuration of the present invention).

〔Example〕

The present invention will be explained below based on illustrated embodiments.

FIG. 1 is a block diagram showing an embodiment of an optical switching device according to the present invention. In the figure, 1a and 1b indicate transmitting/receiving terminal stations arranged in an input/output boat.

Further, 3a is an (mxr) optical matrix switch, 3b is an (rXJ) optical matrix switch, and 4 is an (nxn) star coupler. In this way, this embodiment is constructed in a bidirectional manner in which the transmitting side and the receiving side are not clearly separated.

Here, m is the number of input terminals of the optical matrix switch 3a,
1- is the number of output terminals of the optical matrix switch 3a (the number of input terminals of the optical matrix switch 3b, and also the number of star couplers 4), `` is the number of output terminals of the optical matrix switch 3b, and n is the number of output terminals of the optical matrix switch 3a. number (number of optical matrix switches 3b).

Therefore, if the (mX r ) optical matrix switch 3a is on the input side and the (rXj) optical matrix switch 3b is on the output side, an (rrtXn) x (j Xn) optical exchange will be configured.

In this embodiment, there are r star couplers 4, and each star coupler 4 has n input terminals and one output terminal. Lights of different wavelengths (B"'7 (for example, wavelengths λ1 to λn) are inputted to the 11 input terminals of the star coupler 4, respectively, and light of wavelengths λ1 to λn is inputted to each of the n output terminals. signal or multiplexed signal (for example, λ1+λ2-(-...10λn)
Output.

In addition, the light 71 to the RIX switch 3b (hereinafter, when individually indicated, reference numerals 3b-1 to 3b-n are attached) are connected to the star coupler 4 (hereinafter, when individually indicated, reference numeral 4-1 is attached). ~
The multiplexed signals output from 4-r are inputted one by one to each of the star couplers 4-1 to 4-4, and from among the r input multiplexed signals, one or more (1 ) is selected and output. Since this embodiment is of a bidirectional type, the optical matrix switch 3a has a similar configuration.

In addition, FIGS. 2(a) and 2(b) show the transmitting/receiving terminal station 1a, respectively.
and 1b. In the figure, 21 is a light emitting element such as a laser diode, 22 is a light receiving element,
23 is a transmission filter (wavelength selection filter) with variable transmission wavelength, and 24 is a beam splitter.

When the transmitter/receiver terminal station 1a in FIG. Output to 3a. When the transmitting/receiving terminal station 1b in FIG. and receive the light. As many transmitting/receiving terminal stations 1a, lb are provided for each optical matrix switch as there are output terminals thereof.

Therefore, in the above configuration, if the transmitting/receiving terminal station 1a is on the transmitting side and the transmitting/receiving terminal station 1b is on the receiving side, the present embodiment operates as follows. That is, optical wavelengths λ1 to λn transmitted by the transmitting/receiving terminal station 1a are respectively input to the optical matrix switch 3a. The output of the optical matrix switch 3a is inputted to each of the star couplers 4, and from each of the star couplers 4, a multiplexed signal of optical wavelengths λ1 to λn is inputted to the optical matrix switch 3b. The optical matrix switch 3b selects one of the star couplers 4 and outputs a signal to the transmitting/receiving terminal station 1b. This selected signal is a multiplexed signal, and the transmitter/receiver 1: j, e station lb selects and outputs only an arbitrary wavelength component from the multiplexed signal using a wavelength filter having a wavelength selection function.

As described above, when the transmitting/receiving terminal station 1a is the transmitting side and the transmitting/receiving terminal station 1b is the receiving side, a plurality of star couplers 4, a plurality of optical matrix switches 3b, and a transmitting/receiving terminal station 1b are used.
In combination with the wavelength selection filter 23, it is possible to use a smaller-scale optical matrix switch, for example, compared to a case where the optical exchanger is configured only with optical matrix switches. This is because the combination of the star coupler and the wavelength selection filter in the above configuration can function similarly to an optical matrix switch (separate from the optical matrix switch 3b). Star couplers can be manufactured much more easily with a large number of input/output ports than with optical matrix switches, so it is possible to easily create a switch with a large number of ports. Further, according to this embodiment, the wavelength multiplexing degree may be reduced by the number of input ports/n.

Further, when the transmitting/receiving terminal station 1b is on the transmitting side and the transmitting/receiving terminal station 1a is on the receiving side, a combination of a plurality of star couplers 4, a plurality of optical matrix switches 3a, and a wavelength selection filter 23 of the transmitting/receiving terminal station 1a is combined. 10 - Similar effect can be achieved by combining.

Figure 3 is a reference diagram that supplements the operation of the embodiment in Figure 1 (the combination of the star coupler and wavelength selection filter functions in the same way as an optical matrix switch), and shows a cross-type telephone. be. In the figure, the same reference numerals are used for components that can be considered equivalent to those in Figure 1.
vinegar. In this cross-type telephone, a variable wavelength transmission filter 23 of the input/output terminal station 1a (1b) shown in FIG. 2 is provided between the optical matrix switch 3a (3b) and the star coupler 4. In this way, the input/output terminal station 1a (lb
) and the star coupler 4 are selected by the optical matrix switch 3a (3b) and connected by a negative path, it is equivalent to provide the transmission filter 23 at any position on this path.

In the configuration of FIG. 3, the part 31 surrounded by the broken line in the figure is nxn
It works exactly the same as an optical matrix switch. That is,
When input to the star coupler 4, the wavelength of light differs depending on the boat, but at the output end of the star coupler 4, all the lights with different wavelengths are mixed and output. Here, the transmission filter 23
If the transmission wavelength band is set, only one wavelength will be selectively output, that is, the input port of the star coupler 4 will be selected. Therefore, it can be seen that the above configuration works as an optical matrix switch.

In addition, the combination of the transmission filter 23 and the light receiving element 22, which is the configuration of the input/output terminal station in this practical example, can be implemented using n light receiving elements and n transmission filters, and can be constructed using components that are already in practical use. .

FIG. 4 is a block diagram showing another embodiment of the present invention. In the same figure, 41 is a transmitting/receiving terminal station, 43 is n (m
2 m) optical matrix switch, 44 is m (n
X n ) is a star coupler. This configuration is an application of the present invention to what is known as a folded link network configuration.

That is, the configuration of this example has the advantage that the number of optical matrix switches can be halved, and is suitable when it is desired to mount input and output terminals on the same side. In this case, for example, if the wavelength multiplicity is 1'6, the optical matrix switch 43 is 8×
16 pieces of 16 type, 8 pieces of 16X16 type in star coupler 44
If one is used, a switch with 128 lines can be constructed.

〔Effect of the invention〕

As explained above, according to the present invention, by combining a plurality of star couplers, a plurality of optical matrix switches, and a wavelength selection filter, large-scale It is possible to configure an optical switch. In addition, the star coupler requires less wavelength multiplexing, the wavelength division density of the wavelength selection filter can be lowered, and there is no need for a wavelength exchange element that is difficult to manufacture.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing an embodiment of an optical switching device according to the present invention, Fig. 2 (a) and (b) are transmitting/receiving terminal stations in Fig. 1, and Fig. 3 supplements the explanation of Fig. 1. FIG. 4 is a configuration diagram showing another example of the optical switching device according to the present invention. 1a, lb... Transmission/reception terminal station, 3a, 3b... Optical matrix switch, 4... Star coupler, 23... Transmission filter (wavelength selection filter). Patent Applicant Oki Electric Industry Co., Ltd. Agent Patent Attorney Former 1) Real-NC Be
Be

Claims (1)

[Claims] It has a plurality of input terminals and a plurality of output terminals, and when an optical signal of a different wavelength is input to each of the plurality of input terminals, the signal of the different wavelength is transmitted to each of the plurality of output terminals. A plurality of star couplers output a multiplexed signal in which the optical signals of a plurality of optical matrix switches that select and output one or more multiplexed signals; and a plurality of optical matrix switches that input the multiplexed signals that are selected and output by the plurality of optical matrix switches, and select arbitrary wavelength components in the input multiplexed signals. 1. An optical exchanger comprising a plurality of variable wavelength selection filters that selectively output only selected wavelengths.