JPH0530043A - Optical self-routing circuit - Google Patents

Abstract

PURPOSE:To realize the optical self-routing circuit in which a time allocated to a header section of an optical packet signal is reduced. CONSTITUTION:Optical packet signals A-D from optical waveguides 1700-1703 are made incident in optical gates 1720-1727. Only the optical gate in which the header part of the optical packet signal applied to the optical gates 1720-1723 and an electric pulse are first coincident is in through-state and only the optical packet signal with a prescribed wavelength is outputted from the optical waveguide 1704 via an optical confluent device 1730. Similarly, only the optical gate in which the header part of the optical packet signal applied to the optical gates 1724-1727 and an electric pulse are first coincident is in through-state and only the optical packet signal with a prescribed wavelength is outputted from the optical waveguide 1705 via an optical multiplexer 1731.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical self-routing circuit for performing routing according to the header portion of an optical packet signal.

[0002]

2. Description of the Related Art Optical communication using an optical fiber for a transmission line is
Since the optical fiber has a wide band, it is possible to transmit a large amount of information, and the optical fiber is advantageous in that it does not receive induced noise. Therefore, it is expected to be widely used in the future. The switch used in this optical communication is preferably an optical switch capable of switching optical signals in the optical range. Among them, an optical packet switch that handles packetized optical signals is promising because it can efficiently exchange information of various signal speeds. Such an optical packet switch requires an optical self-routing circuit that reads the header portion of an optical packet signal and performs routing accordingly. As such a circuit, an "optical self-routing circuit" shown in FIG.
49).

In FIG. 6, the optical packet signals A and B input to the optical waveguides 601 and 602 are optical branching devices 60, respectively.
The optical gates 605, 606 and 60 are branched into two at 3, 604.
It is incident on 7, 608. The optical signals output from the optical gates 605 and 607 are combined by the optical combiner 609 and emitted from the optical waveguide 611. The optical signals output from the optical gates 606 and 608 are combined by the optical combiner 610 and emitted from the optical waveguide 612. The electric pulse generation circuit 613 has optical gates 605 and 60.
7, the same electric pulse is applied and the optical gates 606 and 608 are applied with another electric pulse.

FIG. 7 is a diagram for explaining one structure of the optical gates 605 to 608 of FIG. In FIG. 7, the optical gate is composed of one end face 720 of the light guide layer 710 and the other end face 7 of the light guide layer 710.
30, the input optical signal 700 is input to one end surface 720 of the light guide layer 710, and the output optical signal 750 is output from the other end surface 730. Further, the control signal V is applied via the electrode 740. This optical gate is V
= V _H , when the input optical signal 700 is incident, V
= V _L (V _L <V _H ), the optical signal incident while being applied is amplified and output. The details of such an optical gate are described in Proceedings of the Autumn Meeting of the Japan Society of Applied Physics, 1990, page 754, Lecture No. 26p-H-2.

FIG. 8 is a time chart for explaining the operation of FIG.
It is a chart. 8, 801 indicates the applied electrical pulse to the optical gates 605 and 607 in FIG. 6, the time t ₁
Maintain a between V _H of ~t ₂ t ₂ ~t ₆ between V _L. 802
It indicates the applied electrical pulse to the optical gates 606, 608 in FIG. 6, the time t ₂ between ~t ₃ V _H becomes t ₃ V between ~t ₆
Keep _L The optical packet signal A incident on the optical gates 605 and 606 in FIG. 6 is time t _{1 as} indicated by 803 in FIG.
The header optical signal exists only during the period from to t ₂ . Therefore, in the optical gate 605, the time when the electric pulse V _H and the time when the optical signal in the header portion are present are the same.
6 does not match. Therefore, the data portion of the optical packet signal A passes only the optical gate 605 and is routed to the optical waveguide 611 via the optical combiner 609. On the other hand, the optical packet signal B incident on the optical gates 607 and 608 is shown in FIG.
No. 804, the optical signal of the header portion exists only during the time t ₂ to t ₃ . Therefore, in the optical gate 608, the time when the electric pulse is V _H matches the time when the header optical signal exists, but the optical gate 607 does not match. Therefore, the data portion of the optical packet signal B passes only the optical gate 608 and is routed to the optical waveguide 612 via the optical combiner 610. As described above, the optical self-routing circuit of FIG. 6 self-routes to the optical waveguide 611 or 612 depending on whether the header portion of the optical packet signal is at time t _{1 to} t ₂ or t _{2 to} t ₃ .

[0006]

In the conventional optical self-routing circuit, depending on whether the header portion of the optical packet signals A and B is present in the time slot from time t _{1 to} t ₂ or time t _{2 to} t ₃ . Optical waveguides 611 and 612
Self-route to. Thus, in the past, since the time slots corresponding to each optical waveguide on the output side are assigned to the header section, when the number of optical waveguides on the output side is increased in order to increase the scale of the optical self-routing circuit, the header section is proportionally increased. There has been a problem that the time required for the extension is long and therefore the processing time of the header portion is long.

An object of the present invention is to provide an optical self-routing circuit in which the time allocated to the header portion does not become long even if the scale of the optical self-routing circuit is increased.

[0008]

An optical self-routing circuit according to the present invention is connected to n m optical branching devices and output terminals of the n m optical branching devices to apply an electric pulse signal (n Xm) optical gates and m n optical multiplexers that join the outputs of n optical gates belonging to different m optical branching systems from each other. It is characterized in that the optical signal of a predetermined wavelength is passed thereafter only when the electric pulse signals are simultaneously applied.

Further, the optical self-routing circuit of the present invention electrically connects the n optical branching circuits with each other and passes the optical signal of a predetermined wavelength thereafter only when the optical signal and the electric pulse signal are simultaneously applied. Each of the n optical branching devices is composed of (n × m) optical gates consisting of m groups of which n are connected to each other and m n optical combiners. The output terminal is connected to the optical gates belonging to different groups among the (n × m) optical gates, and the optical gates within the time section assigned to each group of the (n × m) optical gates. Among the optical gates to which the optical signal and the electrical signal are simultaneously applied at different times, only the optical gate to which the optical signal is first applied passes the optical signal of the predetermined wavelength thereafter, and the (n × m) The output of the optical gate of is combined with the n optical combiners of m units for every m groups.

Further, the optical self-routing circuit of the present invention electrically connects the n optical branching units and the optical signals having a predetermined wavelength thereafter only when the optical signal and the electric pulse signal are simultaneously applied. Each of the n optical branching devices is composed of (n × m) optical gates consisting of m groups of which n are connected to each other and m n optical combiners. The output terminal is connected to the optical gates belonging to different groups among the (n × m) optical gates, and the optical gates within the time section assigned to each group of the (n × m) optical gates. Among the optical gates to which the optical signal and the electrical signal are simultaneously applied at different times, only the optical gate to which the optical signal of the maximum light amount is applied passes the optical signal of the predetermined wavelength thereafter, and the (n × m) The output of each of the optical gates is merged for each of m groups by the n optical multiplexers. .

Further, the optical self-routing circuit of the present invention passes the optical signal over the entire wavelength range of the optical signals of a plurality of wavelengths to be used thereafter only when the optical signal and the electric pulse signal are simultaneously applied to the optical gate. And an optical gate which is connected to either an input terminal or an output terminal of the optical gate and which transmits one optical signal of a predetermined wavelength from the optical signals of the plurality of wavelengths. It is characterized by

Furthermore, the optical self-routing circuit of the present invention allows the optical gate to pass the optical signal over the entire wavelength range of the optical signals of a plurality of wavelengths used only when the optical signal and the electric pulse signal are simultaneously applied. It is characterized in that it is an optical gate in which an optical gate for controlling and a wavelength selection element for transmitting one optical signal of a predetermined wavelength from the optical signals of the plurality of wavelengths are integrated.

[0013]

The optical self-routing circuit of the present invention performs routing using an optical gate that transmits an optical signal of a predetermined wavelength only when a header optical signal and an electric pulse signal are simultaneously applied. It is possible to route to the output end corresponding to the combination with the time when the electric pulse is applied, and the length of the header optical signal can be shortened to 1 / n (n: the number of wavelengths to be used) as compared with the conventional case. Further, in the optical self-routing circuit of the present invention capable of being routed to the output end corresponding to the combination of the wavelength of the optical signal and the time when the electric pulse is simultaneously applied, the header part optical signals of the plurality of optical packet signals are transmitted at the same time. If there is a collision of the optical packet signals, one of the optical gates connected to the same output end according to the priority according to the slight time difference or the light amount difference is in a state of passing the optical packet signal. Since the other optical gates do not pass the optical packet signal, a plurality of packet optical signals can be self-routed without being simultaneously output to the same output end.

[0014]

FIG. 1 is a diagram showing a first embodiment of the present invention. The optical packet signal A or C input to the optical waveguide 101 is divided into four by the branching device 103, and the optical gates 105 to 105
It is incident on 108. Further, the optical packet signal B or D input to the optical waveguide 102 is divided into four by the branching device 104 and is incident on the optical gates 109 to 112. Light gate 1
The output optical signals of 05 and 109, 106 and 110, 107 and 111, and 108 and 112 are optical multiplexers 113 to 1 respectively.
Output from the optical waveguides 119 to 122 via 16. From the electric pulse generating circuit 123 to the optical gates 105 and 109,
2 of 106 and 110, 107 and 111, 108 and 112
Different electric pulses are applied to each element.

FIG. 2 is a timing chart for explaining the operation of FIG. 201 is an optical gate 105 and 109
Shows the applied electrical pulses to, V _H next during time t ₁ ~t _2, between V _{L 1} of t ₂ ~t ₆ kept. 202 shows the applied electrical pulse to the optical gate 106 and 110, the time t ₂ ~
It becomes V _H during t ₃ and is kept at V _{L 1} between t _{3 and} t ₆ . The 203 indicates the applied electrical pulse to the optical gates 107 and 111, V _H next during time t ₁ ~t _2, time t ₂ ~t ₆
Keep V _{L 2} during the period. Further, 204 is an optical gate 108 and 1
12 shows an electric pulse applied to V, and V is applied between times t _{2 and} t ₃ .
_It becomes _H and maintains _{VL 2} from time t _{3 to} t ₆ . A case where the optical packet signal A having the wavelength λ _{1 and} the optical packet signal B having the wavelength λ ₂ are respectively incident from the optical waveguides 101 and 102 will be described. As shown by 205 and 206 of the optical packet signals A and B, respectively, the optical signal of the header section is between the times t _{1 and} t ₂ ,
Data unit optical signal between times t ₄ ~t ₅ is present. The optical gates 105, 106, 109 and 110 or the optical gates 107, 108, 111 and 112 receive a current while V _H is being applied and then current is applied while V _{L 1} or V _{L 2} is applied. Is injected, and an optical signal of wavelength λ ₁ or λ ₂ corresponding to the injection current is transmitted, amplified and output.
Optical gates 105 to 108 on which the optical packet signal A is incident
In the optical gates 105 and 107, an electric pulse is V _H
And the time when the optical signal of the header part exists are t ₁ to t
₂ and not the other optical gates 106-108. Therefore, the optical gates 105 and 107 have wavelengths λ ₁ and λ, respectively.
_Since only the _second optical signal is transmitted, the data portion of the optical packet signal A having the wavelength λ ₁ passes only the optical gate 105 and is routed to the optical waveguide 119 via the optical combiner 113. Further, the optical gate 109 to which the optical packet signal B is made incident
Of the optical gates 109 and 111, the time when the electric pulse is V _H and the time when the optical signal in the header section exists are t ₁
˜t ₂ but not the other optical gates 110, 112. Therefore, the optical gates 109 and 111 each have a wavelength λ ₁
Since only the optical signal of λ ₂ is transmitted, the data portion of the optical packet signal B of wavelength λ ₂ passes only the optical gate 111 and is routed to the optical waveguide 121 via the optical combiner 115.

Next, the case where the optical packet signals C and D having the same wavelength λ ₁ enter from the optical waveguides 101 and 102 respectively will be described. The optical packet signals C and D are 207,
As shown in 208, the time t ₁ ~t ₂ or t ₂ ~t
Each header section light signal is present between the ₃ time t ₄ ~t ₅
There is an optical signal in the data section together. Optical packet signal C
Of the optical gates 105 to 108 to which light is incident
In 05 and 107, the time when the electric pulse is V _H and the time when the optical signal of the header portion exists coincides with t ₁ to t ₂ , but the other optical gates 106 and 108 do not coincide. Therefore optical gate 1
05 and 107 transmit only the optical signals of wavelengths λ ₁ and λ ₂ , respectively, so that the data portion of the optical packet signal C of wavelength λ ₁ passes only the optical gate 105 to the optical waveguide 119 via the optical combiner 113. Routed.

Further, in the optical gates 109 to 112 to which the optical packet signal D is incident, the optical gates 110 and 112 have a time when the electric pulse is V _H and a time when the header optical signal exists are t ₂ to t ₃ . Match but other optical gates 109, 1
11 does not match. Therefore, since the optical gates 110 and 112 transmit only the optical signals of the wavelengths λ ₁ and λ ₂ , respectively, the data portion of the optical packet signal D of the wavelength λ ₁ passes only the optical gate 110 and is transmitted via the optical combiner 114. It is routed to the waveguide 120.

As described above, in the optical self-routing circuit of FIG. 1, the optical waveguide 119 corresponding to the combination of the wavelengths λ ₁ and λ ₂ of the optical packet signal and the times t ₁ to t ₂ or t _{2 to} t ₃ at which the header portion exists. ~ 122 can be self-routed. Therefore, the length of the header optical signal can be shortened to 1 / n (n: the number of wavelengths to be used) as compared with the conventional case where self-routing is performed only according to the time when the header exists.

A second embodiment of the present invention will be described with reference to FIG. The optical packet signals A to D input to the optical waveguides 1700 to 1703 are divided into two by the optical branching devices 1710 to 1713, and are divided into optical gates 1720, 1724 and 1721, 1 1.
725, 1722, 1726 and 1723, 172
It is incident on 7. The optical signals output from the optical gates 1720 to 1723 are output from the optical waveguide 1704 via the optical combiner 1730. The optical signals output from the optical gates 1724 to 1727 are output from the optical waveguide 1705 via the optical combiner 1731. Electric pulse generation circuit 1740 and optical gate 1720-
1723 is a light gate 1724 through a resistor 1900.
1727 is connected via a resistor 1910.

FIG. 4 is a timing chart for explaining the operation of FIG. Reference numeral 401 denotes a voltage pulse applied to the resistor 1900, which becomes V _{H 0} between times t _{1 and} t ₄ , and t
_{When 4 to} t ₇ , V _{L a} is maintained. 402 is an optical gate 1720
˜1723 applied voltage pulses, V _H , t ₄ less than V _{H 0} between times t _{1 and} t ₄ by resistor 1900.
Keep V _{L 1} less than V _{L a for} ~ t ₇ . Reference numeral 403 denotes a voltage pulse applied to the resistor 1910, which is time t _{1 to} t _4.
V _{H 0} during the period, and maintains V _{L b} during the period from t _{4 to} t ₇ . 40
Reference numeral 4 denotes a voltage pulse applied to the optical gates 1724 to 1727, which is _{VH 0} during the time t _{1 to} t ₄ by the resistor 1910.
Smaller V _H , smaller than V _{L b} between t ₄ and t ₇ V _{L 2}
Keep

An optical packet signal A of wavelength λ ₁ incident on the optical gates 1720 and 1724 has a header portion having a light amount P ₁ at times t ₁ to t ₂ and a data portion at times t _{5 to} t ₆ as shown at 405. Exists. As shown by 406, the optical packet signal B having the wavelength λ ₂ incident on the optical gates 1721 and 1725 has a header portion whose light amount is P _{1 from} time t _{1 to} t ₂ at time t ₅ to t ₂ .
There is a data part at t ₆ . Optical gates 1722, 172
As shown by 407, the optical packet signal C having the wavelength λ ₁ which is incident on the light source ₆ has a header portion whose light quantity is P ₁ at times t ₂ to t ₃ ,
data portion is present in the t ₅ ~t _6. Optical gate 1723,
The optical packet signal D of wavelength λ ₂ incident on the 1727 is 4
As shown by 08, a header part having a light amount P ₁ is present at times t ₁ to t ₂ and a data part is present at times t _{5 to} t ₆ . Light gate 17
20-1723 or the optical gates 1724-1727 receive V _{L 1} when light is incident while V _H is being applied.
Or current is injected while V _{L 2} is applied,
The optical signal of wavelength λ ₁ or λ ₂ corresponding to the injection current is transmitted, amplified and output.

Both optical packet signals A and C having wavelengths of λ ₁ are desired signals as output from the optical waveguide 1704 and may collide with each other, and the applied voltage to the optical gates 1720 and 1722 becomes V _H. There is a header part within the time. However, since the optical packet signal A has the light quantity P ₁ in the header portion _first , the optical gate 1720 switches to a state in which the subsequent data portion is allowed to pass earlier. When the optical gate 1720 shifts to this operating state, the injection current into the optical gate 1720 increases, and the voltage applied to the optical gate 1722 decreases due to the voltage drop due to this current and the resistor 1900. The data portion of the optical packet signal C cannot be passed. As a result, only the data portion of the optical packet signal A having the wavelength λ ₁ passes through the optical gate 1720 and is self-routed to the optical waveguide 1704 via the optical combiner 1730.

Both optical packet signals B and D having wavelengths of λ ₂ may collide with the output of the optical waveguide 1705 at a desired signal, and the optical gates 1725 and 17 may be provided.
The header portion exists within the time when the applied voltage of 27 is V _H. However, since the optical packet signal B has the light quantity P ₁ in the header portion _first , the optical gate 1725 is switched to a state in which the subsequent data portion is passed earlier. Optical gate 172
5 shifts to this state, the injection current to the optical gate 1725 increases, and the voltage applied to the optical gate 1727 decreases due to this current and the voltage drop due to the resistor 1910. Therefore, the optical gate 1727 no longer receives the optical packet signal D. Cannot pass through the data part of. As a result, only the data portion of the optical packet signal B having the wavelength λ ₂ passes through the optical gate 1725 and is self-routed to the optical waveguide 1705 via the optical combiner 1731.

As described above, in this embodiment, not only is the wavelength of the optical packet signal self-routed to the optical waveguide 1704 or 1705 by either λ ₁ or λ ₂ , but a plurality of optical packet signals of the same wavelength are transmitted. Even if light is incident from the optical waveguides 1700 to 1703, the optical gate 17
It is possible to avoid the collision of optical packet signals by performing priority control in the order in which the header portion is present earlier in the time t _{1 to} t ₄ when V _H is applied to 20 to 1727.

Next, a third embodiment of the present invention will be described with reference to FIG. The optical packet signals A to D input to the optical waveguides 1700 to 1703 are respectively optical splitters 1710 to 1713.
Optical gates 1720, 1724 and 172
1, 1725 and 1722, 1726 and 1723,
It is incident on 1727. The output optical signals of the optical gates 1720 to 1723 are transmitted to the optical waveguide 1704 via the optical combiner 1730.
Is output from. The optical signals output from the optical gates 1724 to 1727 are output from the optical waveguide 1705 via the optical combiner 1731. Electric pulse generation circuit 1740 and optical gate 17
20-1723 is connected to the optical gate 17 via the resistor 1900.
24 to 1727 are connected via a resistor 1910.

FIG. 5 is a timing chart for explaining the operation of FIG. Reference numeral 501 denotes a voltage pulse applied to the resistor 1900, which is V _{H 0} between times t _{1 and} t ₂ , and t
During the period from _{2 to} t ₅ , V _{L a} is maintained. 502 is an optical gate 1720
˜1723 showing the applied voltage pulse, V _H , t ₂ less than V _{H 0} between times t _{1 and} t ₂ by resistor 1900.
Keep V _{L 1} less than V _{L a for} ~ t ₅ . Reference numeral 503 denotes a voltage pulse applied to the resistor 1910, which is from time t _{1 to} time t _2.
V _{H 0} during the period, and maintains V _{L b} between t ₂ and t ₅ . 5
Reference numeral 04 denotes a voltage pulse applied to the optical gates 1724 to 1727, which is V by the resistor 1910 between the times t _{1 and} t ₂ .
_{H 0} is less than V _H, kept between V _Lb smaller than V _{L 2} of t ₂ ~t _5.

As shown by 505, the optical packet signal A having the wavelength λ ₁ incident on the optical gates 1720 and 1724 has a header portion having a light amount P ₁ at times t ₁ to t ₂ and a data portion at times t _{3 to} t _4. Exists. As shown by 506, the optical packet signal B having the wavelength λ ₂ incident on the optical gates 1721 and 1725 has a header portion whose light amount is P _{2 from} time t _{1 to} t ₂ at time t ₃ to t ₂ .
There is a data part at t ₄ . Optical gates 1722, 172
As shown at 507, the optical packet signal C having the wavelength λ ₁ incident on the light source _No. 6 has a header portion whose light amount is P ₃ between times t ₁ and t ₂ ,
data portion is present in the t ₃ ~t _4. Optical gate 1723,
The optical packet signal D of wavelength λ ₂ incident on the 1727 is 5
As shown in 08, a header part having a light intensity of P ₄ exists at times t ₁ to t ₂ , and a data part exists at times t _{3 to} t ₄ . Here, the light quantity values of the header optical signals of the packet signals A to D are P ₁ > P ₂ >
And it has a P _3> P _4. Optical gates 1720-1723
Alternatively, the optical gates 1724-1727 receive _{VL 1} or _{VL 2} when light is incident while V _H is being applied.
While the current is being applied, a current is injected, and an optical signal having a wavelength λ ₁ or λ ₂ corresponding to the injected current is transmitted, amplified and output.

The optical packet signals A and C having both wavelengths of λ ₁ are desired signals which are output from the optical waveguide 1704 and may collide with each other, and the applied voltage to the optical gates 1720 and 1722 becomes V _H. There is a header part at the time.
However, since the light amount P ₁ of the header portion of the optical packet signal A is larger than the light amount P ₃ of the header portion of the optical packet signal C, the optical gate 1720 is quickly switched to a state in which the subsequent data portion is passed. When the optical gate 1720 shifts to this operating state, the injection current to the optical gate 1720 increases, and the voltage drop due to this current and the resistor 1900 lowers the applied voltage to the optical gate 1722. The data part of the packet signal C cannot be passed. As a result, only the data portion of the optical packet signal A of wavelength λ ₁ passes through the optical gate 1720 and the optical combiner 17
It is self-routed to the optical waveguide 1704 via 30.

Both optical packet signals B and D having wavelengths of λ ₂ may collide with the output of the optical waveguide 1705 and a desired signal.
The header portion exists at the time when the applied voltage of 27 is V _H. However, the light quantity P _{2 at} the header of the optical packet signal B
Is larger than the light amount P ₄ of the header portion of the optical packet signal D, the optical gate 1725 is quickly switched to a state in which the subsequent data portion is passed. When the optical gate 1725 shifts to this state, the injection current into the optical gate 1725 increases, and the voltage drop due to this current and the resistor 1910 causes the optical gate 1725.
Since the voltage applied to 727 decreases, it is no longer possible to use the optical gate 17
27 cannot pass the data portion of the optical packet signal D. As a result, only the data portion of the optical packet signal B of wavelength λ ₂ passes through the optical gate 1725 and the optical combiner 17
It is self-routed to the optical waveguide 1705 via 31.

As described above, in this embodiment, not only is the wavelength of the optical packet signal self-routed to the optical waveguide 1704 or 1705 by either λ ₁ or λ ₂ , but also a plurality of optical packet signals of the same wavelength are transmitted. Even if light is incident from the optical waveguides 1700 to 1703, priority control can be performed in the order of the amount of light of the header portion of the optical packet signal to avoid collision of the optical packet signal.

In order to facilitate the explanation in FIGS. 1 and 3, it is assumed that the optical signal having a predetermined wavelength is selectively passed thereafter only when the optical signal and the electric signal are simultaneously applied.
Although the case of using one optical gate has been described, an optical gate that has a transmission band of the entire wavelength range of optical signals of multiple wavelengths that uses this optical gate and an optical signal of a predetermined wavelength from the optical signals of multiple wavelengths is used. The same effect can be obtained by using a wavelength selection element that selectively transmits light.

[0032]

As described above, according to the present invention, it is possible to obtain an optical self-routing circuit for self-routing to an output terminal corresponding to a combination of a wavelength of an optical packet signal and a time when a header portion exists.

Further, when self-routing is performed in correspondence with the combination of the wavelength of the optical packet signal and the time when the header portion exists, even if a plurality of optical packet signals collide, one of these optical signal An optical self-routing circuit for preferentially self-routing can be obtained.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an optical self-routing circuit according to a first embodiment of the present invention.

2 is a timing chart showing the operation of the optical self-routing circuit of FIG.

FIG. 3 is a configuration diagram of optical self-routing circuits according to second and third embodiments of the present invention.

FIG. 4 is a timing chart showing the operation of the optical self-routing circuit of the second embodiment of FIG.

5 is a timing chart showing the operation of the optical self-routing circuit of the third embodiment of FIG.

FIG. 6 is a configuration diagram of a conventional optical self-routing circuit.

FIG. 7 is a diagram for explaining the configuration of an optical gate.

8 is a timing chart showing the operation of the optical self-routing circuit of FIG.

[Explanation of symbols]

101, 102, 119, 120, 121, 122 Optical waveguides 103, 104 Optical splitter 112 Optical gates 113 to 116 Optical combiner 123 Electric pulse generation circuits 601, 602, 609, 612 Optical waveguides 603, 604 Optical splitters 605 to 605 608 optical gates 609 and 610 optical combiner 613 electric pulse generation circuit 1700 to 1705 optical waveguides 1710 to 1713 optical branching devices 1720 to 1727 optical gates 1730 and 1731 optical combiner 1740 electric pulse generator

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI Technical display location H04Q 3/52 101 B 9076-5K 8529-5K H04L 11/20 102 Z

Claims (5)

[Claims] 1. An n number of m optical branching devices, and (n × m) number of optical gates connected to the output terminals of the n m optical branching devices to which an electric pulse signal is applied, and the optical gates different from each other. The optical gate is composed of m n optical multiplexers which join the outputs of n optical gates belonging to the system of m optical branching devices, and the optical gate is predetermined only when an optical signal and an electrical pulse signal are simultaneously applied. An optical self-routing circuit, which allows optical signals of the wavelength 2. An n number of m optical branching devices and one number of n electrically connected to each other that allows an optical signal of a predetermined wavelength to pass thereafter only when an optical signal and an electric pulse signal are simultaneously applied. (N × m) optical gates consisting of m groups, and m
N optical multiplexers, and the output terminals of the n optical splitters are connected to optical gates belonging to different groups among the (n × m) optical gates. Xm) The light to which the optical signal is first applied among the optical gates to which the optical signal and the electric signal are simultaneously applied at different times for each optical gate within the time section assigned to each group of the optical gates. After that, an optical signal of a predetermined wavelength passes through only the gate, and the outputs of the (n × m) optical gates are combined by the m n optical combiners for every m groups. Optical self-routing circuit. 3. An n number of m optical branching devices and one n number of electrically connected devices that pass an optical signal of a predetermined wavelength thereafter only when an optical signal and an electrical pulse signal are simultaneously applied. (N × m) optical gates consisting of m groups, and m
N optical multiplexers, and the output terminals of the n optical splitters are connected to optical gates belonging to different groups among the (n × m) optical gates. Xm) The optical signal of the maximum light quantity was applied among the optical gates to which the optical signal and the electric signal were simultaneously applied at different times for each optical gate within the time section assigned to each group of the optical gates. After that, an optical signal of a predetermined wavelength passes through only the optical gate, and the (n ×
m) An optical self-routing circuit, wherein the outputs of the m optical gates are combined by the m n optical combiners for every m groups. 4. The optical gate according to any one of claims 1 to 3 is used only when an optical signal and an electric pulse signal are simultaneously applied, and the optical signal is used over the entire wavelength range of optical signals of a plurality of wavelengths. Optical gate composed of an optical gate for transmitting light and a wavelength selection element connected to either the input end or the output end of the optical gate and transmitting one optical signal of a predetermined wavelength from the optical signals of the plurality of wavelengths. An optical self-routing circuit characterized by: 5. The optical gate according to any one of claims 1 to 3 is used only when an optical signal and an electrical pulse signal are simultaneously applied, and the optical signal is used over the entire wavelength range of optical signals of a plurality of wavelengths. An optical self-routing circuit, which is an optical gate in which an optical gate for transmitting light and a wavelength selection element for transmitting one optical signal of a predetermined wavelength from the optical signals of the plurality of wavelengths are integrated.