JP2003021851A - Optical switch module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an optical switch module which can add or drop an optical signal in a prescribed unit like the unit of packets without converting the optical signal once into an electric signal. SOLUTION: An optical signal 202 is inputted from a main input port 203 of an optical switch module 201 and is branched by an optical branching device 211 and is inputted to first and second optical gate switches 214 and 221. The output of the first optical gate switch 214 is outputted from a drop port 207, and an optical signal inputted from an add port 205 is taken as one of inputs to an optical junction device 229 through a third optical gate switch 224. The output of the second optical gate switch 221 is taken as the other input. The first to third optical gate switches 214, 221, and 224 are set to the transmission or interception state in combinations different by slots, and thus the optical switch module 201 performs processing like add, drop, through, etc., different by slots.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical switch module suitable for use as a node in a network that transfers data at high speed as packets.

[0002]

2. Description of the Related Art The spread of network communication technologies such as the Internet requires large-capacity data communication, and the development of wavelength multiplexing communication technology has been activated. OADM (Op
ticalAdd Drop Multiplexing) is an optical add / drop multiplexing technology that allows data to be freely input and output for each wavelength, and has been actively developed in recent years. This OAD
When M is used, an optical signal of an arbitrary wavelength can be added (inserted) from a node to a transmission line, or conversely, an optical signal of an arbitrary wavelength can be dropped (branched) from a transmission line to a node. By using the OADM, it is possible to easily change the optical path configuration in response to changes in network traffic.

FIG. 4 shows an example of an OADM circuit forming a conventionally proposed OADM node. This OADM circuit is proposed in Japanese Patent Laid-Open No. 11-275007. The proposed OADM circuit 101 uses fiber grading like other similar OADM circuits.

The input port 102 of the OADM circuit 101 shown in FIG.
The DM optical signal 103 is supplied and input to the first terminal 105 ₁ of the first optical circulator 104. The first optical circulator 104 includes first to third terminals 105 _{1 to} 105 ₃ and each of the terminals 105 ₁ to 1
The optical signal is transmitted only in one direction between 05 ₃ . That is, the direction from the _first terminal 105 ₁ to the second terminal 105 ₂ , the direction from the second terminal 105 ₂ to the third terminal 105 _3, and the direction from the _third terminal 105 ₃ to the first terminal 105 ₁ . The optical signal is transmitted only in the direction.

The first fiber grating 106 is connected to the _second terminal 105 ₂ of the first optical circulator 104.
One end of is connected. The first fiber grating 106 has a characteristic of reflecting only light of a specific wavelength and transmitting light of other wavelengths. An optical isolator 107 is provided at the other end of the first fiber grating 106.
One end of the second fiber grating 108 is connected via. The optical isolator 107 transmits an optical signal only in the direction from the first fiber grating 106 to the second fiber grating 108, and has a role of preventing multiple reflection between the fiber gratings 106 and 108. These fiber gratings 106 and 108 have similar characteristics to each other.

The other end of the second fiber grating 108 is connected to the first terminal 11 of the second optical circulator 109.
It is connected to 2 ₁ . This second optical circulator 1
09 also includes a first through third terminals 112 ₁ to 112 ₃ in the same manner as the first optical circulator 104, the terminals 112
_The optical signal is transmitted only in one direction between _{1 to} 112 ₃ . That is, the direction from the _first terminal 112 ₁ to the second terminal 112 ₂ , the direction from the second terminal 112 ₂ to the third terminal 112 _3, and the direction from the _third terminal 112 ₃ to the first terminal 112 ₁ . The optical signal is transmitted only in the direction.

In the proposed OADM circuit 101, the main line
Of the WDM optical signal 103 input from the optical fiber of the system
The optical signal of a specific wavelength is the first fiber grating
The first light is reflected by the optical path 106 and travels through the path shown in the figure.
Third terminal 105 of circulator 104₃Is branched to
It On the other hand, the light passes through the first fiber grating 106.
The optical signals of other wavelengths that are generated are transmitted to the second optical circulator 10
9th third terminal 112 ₃Light of a specific wavelength input from
The signal is multiplexed with the optical signal 115 from the output port 114.
Output to a trunk optical fiber not shown as
become. Therefore, here, the first optical circular
And the first fiber grating 106
It functions as a branching part of the optical signal, and the second fiber grating
And the second optical circulator 109
It will function as a signal insertion unit.

The third terminal 105 ₃ of the first optical circulator 104 is connected to the drop (branch) port 116, and the branched optical signal 117 is output. The add (insert) port 118 is connected to the third terminal 112 ₃ of the second optical circulator 109, and the optical signal 119 to be inserted is input from this port.

[0009]

Therefore, although the OADM circuit 101 of this proposal can add and drop an optical signal in wavelength units, it can add or drop an optical signal in a predetermined unit in the same wavelength. I couldn't. Here, the predetermined unit means, for example, a packet unit or a cell unit.

Incidentally, Japanese Patent Laid-Open Nos. 2000-004213, 2000-078176, and 20.
In Japanese Patent Laid-Open No. 00-165425, an optical signal is added or dropped as it is in units of wavelength, and there is a similar problem.

On the other hand, it is possible to convert an optical signal into an electric signal once, store it in a memory, and add or drop the stored electric signal in packet units or cell units. It is also possible to convert the electric signal that has undergone such processing into an optical signal again and send it out. However, when such processing is performed, the time for storing the electric signal in the memory becomes the transfer delay time in the node. Therefore, signal transmission delay becomes a serious problem in applications such as video that requires real-time performance and telephones on the Internet.

Therefore, an object of the present invention is to provide an optical switch module which can add or drop an optical signal in a predetermined unit such as a packet unit without once converting the optical signal into an electric signal.

[0013]

According to a first aspect of the present invention, (a) a main input port for inputting an optical signal sent in a predetermined unit, and (b) an optical signal input from the main input port. Optical branching means for branching the optical signal into first and second optical signals, and (c) transmission / blocking selection of inputting or blocking the first optical signal output from the optical branching means. A first optical gate switch for performing the
Drop port that outputs the optical signal that has passed through the optical gate switch and (e) whether the second optical signal that has been branched by the optical branching unit is input and whether this is transmitted or blocked.
A second optical gate switch for selecting the cutoff; (f) an add port for inputting an optical signal of a predetermined unit to be inserted;
(G) Third selection for transmitting or blocking whether to transmit or block a predetermined unit of optical signal input from this add port
2 x 1 which inputs the optical signals transmitted through the third optical gate switch and the second optical gate switch, and selects and outputs one of them.
An optical switch, (i) a main output port arranged on the output side of this 2 × 1 optical switch, and (u) an optical signal input from a main input port, which is passed through to the main output port without being extracted Slot, a second slot for extracting the optical signal input from the main input port to the drop port without passing through the main output port, and a second slot for inserting the optical signal from the add port and outputting only this to the main output port. Slot 3 and a fourth slot that extracts the optical signal input from the main input port to the drop port, inserts the optical signal from the add port, and outputs only this to the main output port,
At least two or more of the fifth slots for extracting the optical signal input from the main input port to the drop port and outputting the same optical signal to the main output port are arranged so that at least two slots are continuous in succession. The optical switch module is provided with an optical gate switch transmission / interruption state control means for controlling by combining the time timings of whether each of the third optical gate switches is in the transmission state or the interruption state.

That is, according to the first aspect of the present invention, the optical signal sent to the main input port in a predetermined unit such as a packet unit is branched into the first and second optical signals by the optical branching unit, and The first optical signal is input to the first optical gate switch that selects whether to transmit or block the first optical signal, and its output is connected to the drop port. Similarly, for the second optical signal, the transmission / blocking selection of whether to transmit or block the second optical signal is similarly performed.
Input to the optical gate switch, and one input side of the 2 × 1 optical switch is connected to the output side thereof. Further, the optical signal of a predetermined unit input from the add port is input to the third optical gate switch which selects whether to transmit or block the optical signal, and the output side thereof is 2 ×.
1 Connect to the other input side of the optical switch. The main output port is arranged on the output side of the 2 × 1 optical switch.
With such a structure, the optical gate switch transmission / interruption state control means controls the first to third optical gate switches by combining the timings of the transmission state and the interruption state in combination. At some point (slot)
Then, let the optical signal input from the main input port pass through to the main output port without extracting it, or extract the optical signal input from the main input port to the drop port without passing through to the main output port, or add port. From the main input port to the drop port while inserting the optical signal from the main input port into the drop port and inserting the optical signal from the add port into the main output port. Alternatively, the optical signal input from the main input port can be extracted to the drop port and the same optical signal can be output to the main output port. Therefore, when performing signal processing that causes all of these five aspects equally, the first to fifth aspects corresponding to each of these aspects are performed.
Of each of the first to third optical gate switches are arranged so that they are sequentially repeated in a predetermined order in time, and the main state is controlled at a timing corresponding to these. A signal may be input from the output port or the add port, or a signal may be output from the main output port or the drop port. The first principle
~ It is not necessary to have all of each of the fifth slots, but only some of them.

According to a second aspect of the present invention, (a) a main input port for inputting an optical signal sent in a predetermined unit;
(B) optical branching means for branching the optical signal input from the main input port into first and second optical signals; and (c) first
Tunable light source, and (d) a second tunable light source,
(E) A third wavelength tunable light source, and (H) a first combiner for inputting the first optical signal output from the optical branching unit and multiplexing the optical signal output by the first wavelength tunable light source. And (g) a second combiner for inputting the second optical signal output from the optical branching unit and multiplexing with the optical signal output by the second wavelength tunable light source, and (h) a predetermined unit to be inserted. An add port for inputting the optical signal of (3), (i) a third combiner for combining the optical signal input from this add port and the optical signal output by the third wavelength tunable light source, and (n) A first optical gate switch for inputting an optical signal output from the first combiner and selecting whether to transmit or block the optical signal; and (l) a light transmitted through the first optical gate switch. Input the drop port that outputs the signal and the optical signal that the second confluencer outputs, and transmit it. The second optical gate switch, which selects whether to transmit or block, and (w) the optical signal output from the third combiner, which is transmitted or blocked to be transmitted or blocked. And a third optical gate switch for performing (2) 2 × 1 which inputs the optical signals transmitted respectively through the third optical gate switch and the second optical gate switch and selects and outputs one of them. Optical switch,
(Y) A main output port arranged on the output side of the 2 × 1 optical switch, and (T) a first slot that allows the optical signal input from the main input port to pass through to the main output port without being extracted. A second slot for extracting the optical signal input from the main input port to the drop port without passing through the main output port, and a third slot for inserting the optical signal from the add port and outputting only this to the main output port , The fourth slot that extracts the optical signal input from the main input port to the drop port, inserts the optical signal from the add port and outputs only this to the main output port, and drops the optical signal input from the main input port At least two slots out of the fifth slots that are extracted to the port and output the same optical signal to the main output port are first consecutively arranged so as to be consecutive. Is provided to the third optical switch module and optical gate switches transmission and disengaged state control means for each of the optical gate switch control by combining the temporal timing of either a cut-off state or a transmission state of.

That is, according to the invention described in claim 2, the basic structure is the same as that of the invention described in claim 1, but each of the optical gate switches is provided with its own variable wavelength light source and merger. This enables wavelength conversion of the optical signals input to these optical gate switches.

According to a third aspect of the present invention, in the optical switch module according to the first or second aspect, the optical gate switch transmission / interruption state control means includes the first to third optical gate switches. It is characterized in that each of the five slots is set to a predetermined transmission state or a blocking state, and the control of each of the first to fifth slots is periodically repeated in a predetermined order. There is.

That is, the invention according to claim 3 is the invention according to claim 1 or claim 2, in which each of the first to fifth slots corresponding to each of the above aspects is provided. When these are evenly distributed, the respective aspects will appear equally. For example, when the optical signal input from the main input port has an add or drop ratio passed directly to the main output port. If the number of slots is smaller than that of the above, the appearance ratio of each slot may be set to be unequal in the entire system including the optical switch module.

According to a fourth aspect of the invention, in the optical switch module according to the first or second aspect, the first optical band for blocking spontaneous emission optical noise is provided between the first optical gate switch and the drop port. The feature is that a pass filter is arranged.

That is, according to the invention described in claim 4, since the first optical bandpass filter for blocking the spontaneous emission optical noise is arranged between the first optical gate switch and the drop port, a highly reliable optical signal is provided. A switch module can be constructed.

According to a fifth aspect of the invention, in the optical switch module according to the first or second aspect, a second optical band for blocking spontaneous emission optical noise is provided between the main output port and the 2 × 1 optical switch. The feature is that a pass filter is arranged.

That is, according to the invention of claim 5, a second optical bandpass filter for blocking spontaneous emission noise is arranged between the main output port and the 2 × 1 optical switch. Similar to the invention, a reliable optical switch module can be constructed. Of course, the invention described in claim 4 and the invention described in claim 5 may be applied to the optical switch module at the same time.

According to a sixth aspect of the invention, in the optical switch module according to the second aspect, each of the first to third optical gate switches is a semiconductor optical amplifier, and outputs from the first to third tunable light sources. It is characterized in that wavelength conversion is performed by the mutual gain modulation effect using corresponding optical signals.

That is, in the invention described in claim 6, the optical switch module according to claim 2 enables signal processing such as add or drop to be performed in a predetermined unit such as a packet unit, and also enables wavelength conversion. ing.

[0025]

DETAILED DESCRIPTION OF THE INVENTION

[0026]

EXAMPLES The present invention will be described in detail below with reference to examples.

First embodiment

FIG. 1 shows the configuration of an optical switch module according to the first embodiment of the present invention. The optical switch module 201 has a main input port 203 for inputting an optical signal 202 from an adjacent node (not shown), an add port 205 for inputting an optical signal 204 to be added in packet units, and an optical signal 2 for input from the main input port 203.
A drop port 207 that outputs an optical signal 206 extracted in packet units from 02 and a main output port 209 that outputs an optical signal 208 that has been added to or deleted from the optical signal 202 input from the main input port 203. Equipped with each port.

The optical signal 202 input from the main input port 203 is input to the optical branching device 211, and is branched into first and second optical signals 212 and 213 having exactly the same signal state. The first optical signal 212 of these is
It is adapted to be input to the first optical gate switch 214. The first optical gate switch 214 is a switch that transmits or blocks the input first optical signal 212. The switching control is performed by the first optical gate switch 214.
Is performed by the first selection control signal 215 input to the. The first optical gate switch 214 can obtain an amplification gain in its transmission state. The amplification gain is controlled by inputting the first amplification gain control signal 216 to the first optical gate switch 214.

The optical signal 218 output from the first optical gate switch 214 is input to the first optical bandpass filter 219. The first optical bandpass filter 219 is provided to block spontaneous emission noise of the optical signal 218 input thereto.

The second optical signal 213 after being branched by the optical branching device 211 is input to the second optical gate switch 221. The second optical gate switch 221 is a switch that transmits or blocks the second optical signal 213. The switching control is performed by the second selection control signal 2 input to the second optical gate switch 221.
22. Second optical gate switch 221
It is also possible to obtain an amplification gain in the transparent state. The amplification gain is controlled by the second amplification gain control signal 2
23 is input to the second optical gate switch 221.

On the other hand, the optical signal 204 input from the add port 205 is input to the third optical gate switch 224. Third optical gate switch 224
Is a switch for transmitting or blocking the optical signal 204. The switching control is performed by the third selection control signal 225 input to the third optical gate switch 224.
The third optical gate switch 224 can also obtain an amplification gain in the transmissive state. The amplification gain control is performed by inputting the third amplification gain control signal 226 to the third optical gate switch 224.

The optical signal 227 output from the second optical gate switch 221 and the optical signal 228 output from the third optical gate switch 224 are input to the optical combiner 229 so that they are combined. ing. Optical combiner 2
The second optical bandpass filter 231 is provided on the output side of 29.
Are arranged to block the spontaneous emission noise of the optical signal.
Optical signal 208 that has passed through the second optical bandpass filter 231
From the main output port 209 to the optical switch module 201
It is designed to be output outside.

In the optical switch module 201 of this embodiment, the optical branching device 211 and the optical combiner 229 are
A 3 dB coupler can be used. A semiconductor optical amplifier (SOA), for example, can be used for the first to third optical gate switches 214, 221, and 224. In addition, the first and second optical bandpass filters 21
A fiber Bragg grating (FBG) can be used for 9, 231.

Next, the operation of the optical switch module 201 having the above configuration will be described. The first to third optical gate switches 214, 221, and 224 are configured to switch between a transparent state and a blocking state in units of time slots each having a predetermined fixed length. These switching is performed by switching the first to third selection control signals 215, 222, 225.
Done by The following five types of operations are described as first to fifth
In time slots TS _{1 to} TS ₅ .

First, in the first time slot TS ₁ ,
A through operation is performed in which the optical signal is not extracted and the main output port 209 is passed through. In this first time slot TS ₁ , the second optical gate switch 221 is in the transmitting state, and the first and third optical gate switches 21
4, 224 are in the cutoff state. The optical signal 202 arriving from the adjacent node is input to the optical switch module 201 from the main input port 203. The second optical signal 213 after being branched by the optical branching device 211 passes through the second optical gate switch 221, is input to the optical combiner 229 as an optical signal 227, and passes through the second optical bandpass filter 231. Then, it is output as an optical signal 208 from the main output port 209. That is, in this case, the optical signal 202 input to the optical switch module 201 is directly output as the optical signal 208.

The first optical signal 212 after being branched by the optical branching device 211 in the _first time slot TS ₁ is input to the first optical gate switch 214, which is in a cutoff state. Therefore, the optical signal 218 is not output from the first optical gate switch 214, and the optical signal 206 is not output from the drop port 207.

Next, the second time slot TS ₂ will be described. In the second time slot TS ₂ , the operation of extracting the optical signal without passing through the main output port 209 is performed. In the second time slot TS ₂ , the first optical gate switch 214 is in the transparent state. The second and third optical gate switches 221 and 224 are in the cutoff state. The optical signal 202 arriving from the adjacent node is input to the optical switch module 201 from the main input port 203. The first optical signal 212 after being branched by the optical branching device 211 passes through the first optical gate switch 214, and the optical signal 218 is input to the first optical bandpass filter 219, and from the drop port 207. It is output as an optical signal 206.

The second optical signal 213 after being branched by the optical branching device 211 in this second time slot TS ₂
Is input to the second optical gate switch 221, which is in a cutoff state. Therefore, the optical signal 227 is not output from the third optical gate switch 224,
The optical signal 208 is not output from the main output port 209.

Next, the third time slot TS ₃ will be described. In the third time slot TS ₃ , an add operation for inserting an optical signal is performed. In this third time slot TS ₃ , the first optical gate switch 214 and the second optical gate switch 214
The optical gate switch 221 is in the cutoff state, and the third optical gate switch 224 is in the transmission state.
The optical signal 202 arriving from the adjacent node is input to the optical switch module 201 from the main input port 203, but the first and second optical gate switches 214, 2
21 are in the cutoff state, these are the optical signals 206, 2 from the drop port 207 and the main output port 209.
It is not output as 08.

On the other hand, the optical signal 204 to be inserted is input from the add port 205 of the optical switch module 201 to the third optical gate switch 224. Since the third optical gate switch 224 is in a transmissive state, it is input to the optical combiner 229 as an optical signal 228 and output as an optical signal 208 from the main output port 209 via the second optical bandpass filter 231. Will be done.

Next, the fourth time slot TS ₄ will be described. In the fourth time slot TS ₄ , the drop and add operations for extracting and inserting the optical signal are performed. In the fourth time slot TS ₄ , the first and third optical gate switches 214 and 224 are in the transmitting state, and the second optical gate switch 221 is in the blocking state. Optical signal 2 arriving from the adjacent node mentioned above
02 is input to the optical switch module 201 from the main input port 203. The first optical signal 212 after being branched by the optical branching device 211 is the first optical gate switch 2
14 is input. Since the first optical gate switch 214 is in the transmissive state, the optical signal 218 that has passed through the first optical gate switch 214 is input to the first optical bandpass filter 219 and output as the optical signal 206 from the drop port 207. The optical signal 204 to be added is input from the add port 205 to the third optical gate switch 224. Since the third optical gate switch 224 is also in the transmission state, the optical signal 22 transmitted through this
8 passes through the optical combiner 229 and the second optical bandpass filter 231 and is output as the optical signal 208 to the main output port 209.
From the optical switch module 201 to the outside.

On the other hand, the second optical signal 213 after being branched by the optical branching device 211 is the second optical gate switch 2
21 is input, but this is in the cutoff state. Therefore, the optical signal 202 itself arriving from the adjacent node is not output from the main output port 209.

Finally, the fifth time slot TS ₅ will be described. In the fifth time slot TS ₅ , the operation of extracting the optical signal and passing it to the main output port 209 is performed. In the fifth time slot TS ₅ , the first and second optical gate switches 214 and 221 are in the transmitting state, and the third optical gate switch 224 is in the blocking state. The optical signal 202 arriving from the adjacent node is input to the optical switch module 201 from the main input port 203. The first optical signal 212 after being branched by the optical branching device 211 is input to the first optical gate switch 214. First optical gate switch 2
Since 14 is in the transmission state, the optical signal 218 transmitted through this is input to the first optical bandpass filter 219 and output from the drop port 207 as the optical signal 206. The second optical signal 21 after being branched by the optical branching device 211
In 3 as well, since the second optical gate switch 221 is in the transmission state,
This is transparent. Then, as the optical signal 227, the optical combiner 2
The optical signal 208 is input to the optical fiber 29 and is output from the main output port 209 as an optical signal 208 via the second optical bandpass filter 231.

On the other hand, the third optical gate switch 224 is in the cutoff state. Therefore, no signal is inserted from the third optical gate switch 224.

As described above, by repeating the _first to fifth time slots TS _{1 to} TS ₅ , the optical switch module 201 performs various processes such as adding and dropping of optical signals.

FIG. 2 shows such an operation of the optical switch module. As shown in (a) of the figure, the optical signals 202 input to the main input port 203 in the respective time slots TS ₁ , TS ₂ , TS ₄ , TS ₅ are converted into optical signals P ₁ , P ₂ , P ₄ , P respectively. _Set to ₅ . Since the optical signal 202 is not input in the third time slot TS ₃ , the optical signal P ₃ does not exist. The same figure (b) shows the drop port 207.
It represents the optical signal 206 output from the. Further, FIG. 7C shows the optical signal 204 input from the add port 205 in the first time slot TS ₁ .
These are the optical signal P ₃ ′ input in the third time slot TS ₃ and the optical signal P ₄ ′ input in the _fourth time slot TS ₄ .

FIG. 6D shows the content of the optical signal 208 output from the main output port 209. In the first time slot TS ₁ , the optical signal P ₁ input from the main input port 203 as shown in FIG. 7A is directly output from the main output port 209 as shown in FIG. Will be. In the second time slot TS ₂ , the optical signal P ₂ input from the main input port 203 as shown in FIG. 7A is directly output from the drop port 207 as shown in FIG. Will be.

In the third time slot TS ₃ , the optical signal P ₃ ′ input from the add port 205 as shown in FIG. 7C is output from the main output port 209 as shown in FIG. It will be output as is. In the fourth time slot TS ₄ , the optical signal P ₄ input from the main input port 203 as shown in FIG. 7A is directly output from the drop port 207 as shown in FIG. Also, the optical signal P ₄ ′ input from the add port 205 as shown in FIG. 7C is directly output from the main output port 209 as shown in FIG.

In the last and fifth time slot TS ₅ ,
The optical signal P ₅ input from the main input port 203 as shown in FIG. 7A is directly output from the drop port 207 as shown in FIG. Thus, the data is also output from the main output port 209 as it is.

As described above, in the optical switch module 201 of this embodiment, the timings of transmitting and receiving optical signals are adjusted to the first to fifth time slots TS _{1 to} TS ₅ according to the processing states of the respective signals. By setting them, it becomes possible to add and drop the optical signals with each time slot as a minimum unit without causing any delay in these optical signals.

Second embodiment

FIG. 3 shows the configuration of an optical switch module according to the second embodiment of the present invention. In the second embodiment, the same parts as those in the first embodiment shown in FIG. 1 are designated by the same reference numerals, and the description thereof will be appropriately omitted. In the optical switch module 301 of the second embodiment,
The first and second combiners 3 are provided on the output side of the optical branching device 211 that branches the optical signal 202 input from the main input port 203.
02 and 303 are provided. The first tunable light source 304 has an optical signal 305 on the other input side of the first combiner 302.
And the second tunable light source 306 is connected to the other input side of the second combiner 303.
It is designed to input 7.

The optical signal 308 output from the first combiner 302 is input to the first optical gate switch 311, and the optical signal 309 output from the second combiner 303 is input to the second optical gate switch 312. It is supposed to be entered. The third optical gate switch 313 is an optical combiner 229.
(Hereinafter, referred to as output side optical combiner 229.) It is arranged as one of the two inputs. These first to third optical gate switches 311 to 313 are the first to third optical gate switches of the first embodiment.
The third optical gate switches 214, 221, and 224 simply switch between the transmission state and the cutoff state, but in addition to this, a wavelength conversion function is provided.

The optical signal 321 output from the first optical gate switch 311 is a first optical signal that cuts off the spontaneous emission noise.
Is input to the optical bandpass filter 219 and is output as the optical signal 206 from the drop port 207. The first optical gate switch 311 has a first selection control signal 322 for switching its transmission and blocking states and a first amplification gain control signal 323 for controlling the amplification gain in the transmission state.
Is entered.

The optical signal 325 output from the second optical gate switch 312 and the optical signal 326 output from the third optical gate switch 313 are input to the output side optical combiner 229 and multiplexed. The second optical gate switch 312 is supplied with the second selection control signal 327 for switching between the transmission state and the cutoff state and the second amplification gain control signal 328 for controlling the amplification gain in the transmission state. It has become.
In addition, the third optical gate switch 313 is provided with a third selection control signal 32 for switching the transmission and blocking states thereof.
9 and a third amplification gain control signal 330 for controlling the amplification gain in the transparent state are input.

Here, the optical signal 335 is input from the third combiner 334 to the third optical gate switch 313. The third merger 334 has an add port 2
The optical signal 204 input from 05 and the optical signal 337 output from the third wavelength tunable light source 336 are multiplexed.

Optical switch module 3 having such a configuration
In 01, as in the case of the first embodiment shown in FIG.
The type of operation is the first to fifth time slots TS _{1 to} TS ₅
It is supposed to be done in. In this embodiment, the first to third combiners 302, 303 and 334 and the first to third tunable light sources 304, 306 and 336 are arranged in front of the first to third optical gate switches 311 to 313. ing. Therefore, taking the first optical gate switch 311 as an example,
Wavelength conversion is performed by multiplexing the input optical signal 202 and the optical signal 305 output from the first wavelength tunable light source 304 and passing them through the first optical gate switch 311 having a wavelength conversion function. You can For example, when a semiconductor optical amplifier (SOA) is used as the first optical gate switch 311, wavelength conversion may be performed using the cross gain modulation (XGM) effect.

Although the 3 dB coupler is used as the optical branching device 211 and the optical combiner 229 in the first embodiment, it is also possible to use a coupler having another branching ratio. It is also possible to use an optical branching means or an optical merging means other than the coupler. Further, in the first embodiment, an example in which a semiconductor optical amplifier (SOA) is used as the first to third optical gate switches 214, 221, and 224 has been shown, but the present invention is not limited to this, and other optical gate switches are used. May be used. Further, as the first and second optical bandpass filters 219 and 231 in the first embodiment, an example using a fiber Bragg grating (FBG) is given. However, the present invention is not limited to this, and it goes without saying that other optical bandpass filters such as a dielectric multilayer filter can be used.

[0060]

As described above, the first to sixth aspects of the invention are described.
According to the described invention, by using the first to third optical gate switches and changing the combination of transmission or blocking of these in slot units, processing such as add, drop, and through for each optical signal in a predetermined unit is performed. Enabled
Unlike the case where these processes are performed by once converting into an electric signal, there is no time delay in the process.

According to the second aspect of the invention, not only the processing such as adding, dropping, and passing of the optical signal can be performed in a predetermined unit, but also the wavelength conversion can be performed.

Further, according to the inventions of claims 4 and 5, since the optical bandpass filter is arranged, the spontaneous emission light noise can be shielded, and a reliable optical switch module can be constructed. it can.

[0063]

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a configuration of an optical switch module according to a first embodiment of the present invention.

FIG. 2 is a timing chart showing the operation of each time slot of the optical switch module in the first embodiment.

FIG. 3 is a schematic configuration diagram showing a configuration of an optical switch module according to a second embodiment of the present invention.

FIG. 4 is a schematic configuration diagram showing an example of a conventionally proposed OADM circuit.

[Explanation of symbols]

201, 301 Optical switch module 203 Main input port 205 ADPORT 207 Drop port 209 Main output port 211 Optical splitter 214, 311 First optical gate switch 221 and 312 Second optical gate switch 224, 313 Third optical gate switch 229 (Output side) Optical combiner 302 First merger 303 Second merger 304 First tunable light source 334 Third merger 336 Third tunable light source TS time slot P optical signal

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Claims (6)

[Claims] 1. A main input port for inputting an optical signal sent in a predetermined unit, and an optical branching unit for branching an optical signal input from the main input port into first and second optical signals. A first optical gate switch for inputting a first optical signal output from the optical branching unit and performing transmission / blocking selection of whether to transmit or block the first optical signal, and the light transmitted through the first optical gate switch. A drop port for outputting a signal, a second optical gate switch for inputting the second optical signal after being branched by the optical branching unit, and making a transmission / blocking selection as to whether to transmit or block the second optical signal, An add port for inputting an optical signal of a predetermined unit, and a third optical gate switch for selecting whether to transmit or block the optical signal of the predetermined unit input from the add port. Light gate Switch and the second optical gate switch, the 2 × 1 optical switch for inputting the optical signals respectively transmitted thereto and selecting one of them, and the main switch arranged on the output side of the 2 × 1 optical switch. An output port, a first slot that allows the optical signal input from the main input port to pass through to the main output port without being extracted, and an optical port that does not allow the optical signal input from the main input port to pass through to the main output port A second slot for extracting to a drop port, a third slot for inserting an optical signal from the add port and outputting only this to a main output port, and an optical signal input from a main input port for extracting to the drop port A fourth slot for inserting an optical signal from the add port and outputting only this to the main output port, and an optical signal input from the main input port for the drop port Each of the first to third optical gate switches is in a transparent state so that at least two slots of the fifth slots for extracting the same optical signal to the main output port are periodically continuous. 2. An optical switch module, comprising: an optical gate switch transmission / interruption state control means for controlling a combination of time timings of whether the optical gate switch is in the ON state or the OFF state. 2. A main input port for inputting an optical signal sent in a predetermined unit, an optical branching unit for branching an optical signal input from the main input port into first and second optical signals, 1 wavelength tunable light source, 2nd wavelength tunable light source, 3rd wavelength tunable light source, and light output from the 1st wavelength tunable light source by inputting the first optical signal output from the optical branching means. A first combiner for combining with a signal, and a second combiner for receiving the second optical signal output from the optical branching unit and combining with the optical signal output from the second wavelength tunable light source An add port for inputting an optical signal of a predetermined unit to be inserted, a third combiner for multiplexing the optical signal input from the add port and the optical signal output by the third tunable light source, Whether the optical signal output from the combiner of 1 is input and this is transmitted or blocked A first optical gate switch for performing transmission / blocking selection, a drop port for outputting an optical signal transmitted through the first optical gate switch, and an optical signal output by the second combiner are input to switch the input. A second optical gate switch for selecting whether to transmit or block, and a selection for transmitting or blocking whether the optical signal output from the third combiner is input to transmit or block this. A third optical gate switch for performing, and a 2 × 1 optical switch for inputting optical signals respectively transmitted through the third optical gate switch and the second optical gate switch and selecting and outputting one of them , A main output port arranged on the output side of this 2 × 1 optical switch, a first slot for allowing an optical signal input from the main input port to pass through to the main output port without being extracted, and a main input port Entered A second slot for extracting the received optical signal to the drop port without passing it through the main output port, a third slot for inserting the optical signal from the add port and outputting only this to the main output port, A fourth slot for extracting the optical signal input from the input port to the drop port, inserting the optical signal from the add port and outputting only this to the main output port, and the optical signal input from the main input port Each of the first to third optical gate switches is arranged so that at least two or more slots out of the fifth slots that are extracted to the drop port and output the same optical signal to the main output port are periodically continuous. An optical gate switch transmitting / blocking state control means for controlling by combining the timed timings of the transmission state and the blocking state Optical switch module, characterized by Bei. 3. The optical gate switch transmission / interruption state control means includes the first to third optical gate switches as first to third.
It is characterized in that a predetermined transmission state or a blocking state is set for each of the fifth slots, and control of these first to fifth slots is periodically repeated in a predetermined order. The optical switch module according to claim 1 or 2. 4. The first optical bandpass filter for blocking spontaneous emission optical noise is arranged between the first optical gate switch and the drop port. 2. The optical switch module described in 2. 5. The second optical bandpass filter for blocking spontaneous emission optical noise is arranged between the main output port and the 2 × 1 optical switch, according to claim 1 or 2. 2. The optical switch module described in 2. 6. The first to third optical gate switches are semiconductor optical amplifiers, respectively, and use the corresponding optical signals output from the first to third wavelength tunable light sources to perform wavelength conversion by a mutual gain modulation effect. The optical switch module according to claim 2, wherein