CA2126878C - Photonic switching system - Google Patents

Abstract

A photonic switching system includes an optical link conversion board having a first end and a second end opposite to the first end, a plurality of wavelength converter elements arranged at a constant pitch along the first end of the optical link conversion board and converting input optical signals into optical signal components having different wavelengths, a combiner for combining the optical signal components received from the wavelength converter elements into an optical signal which includes optical signal components having a plurality of wavelengths, a plurality of light output parts arranged at a constant pitch along the second end of the optical link conversion board, and a deflector for sequentially deflecting the optical signal from the combiner to an arbitrary one of the light output parts in response to a control signal so that the optical signal at the arbitrary light output part includes a plurality of optical signal components having different wavelengths.

Description

- ~2&37~
" . 1 PHOTONIC SWITC~ING SYSTEM

BACKGROUND OF THE INVENTION
The present invention generally relates to photonic switching systems, and more particularly to a photonic switching system which cross connects, drops or inserts optical signal links of a plurality of channels.
In a broadband integrated services digital lo network (ISDN), it is necessary to use a transmission apparatus having a throughput in the order of 42.3 Gbps. In other words, it must be possible to cross connect, drop or insert 155.520 Mbps data of approximately 272 channels.
In a conventional system which cross connects, drops or inserts optical signal links of a plurality of channels, the process of cross connecting, dropping or inserting is carried out after once converting a received optical signal into an electrical signal, and the processed electrical signal is converted back into an optical signal before being transmitted to a terminal, a subscriber or a next node.
When carrying out the process electrically, it is necessary to use a large scale integrated circuit (LSI) having a high performance and capable of processing a large number of signals which are transmitted at a high transmission rate, but the performance of the existing LSI cannot meet such a demand. Even if an LSI having such a high performance were existed, the number of input and output pins would become extremely large, it would be extremely troublesome to equip the system with such an LSI, and required coaxial cables and interconnections would become extremely complex and large in scale. For this reason, there is a problem in that it is extremely difficult to realize by the conventional method a switching system whicn -s capable of swi.chlns cptical -" 2~ 78 : ~

signal links as the signal capacity further increases in the ; future.
SUMMARY OF THE I~VENTION
Accordingly, it is a general object of the present invention to provide a novel and use$ul photonic switching system in which the problems de~cribed above are eliminated.
Another and more specific object of the present invention is to provide a photonic switching system comprising:
an optical link conversion board having a first end and a second end opposite to the first end; a plurallty of variable wavelength light emitting elements arranged at a constant pitch along the first end of said optical link conversion board and emitting optical signal components having different wavelengths; a single optical star coupler means mixing the optical signal components received from said light emitting elements and outputting a mixed optical slgnal; and a plurality of multi-wavelength selective fllters arranged at a constant pitch along the second end of said optical link conversion board and receiving and processing only the mixed optical signal from said single optical star coupler means, each of said multi-wavelength selective filters selectively outputting an optical signal which includes optical signal components having desired wavelengths out of the wavelengths included in the optical signal components making up the mixed optical signal.
Still another ob~ect of the present invention is to provide a photonic switching system comprising: an optical llnk converslon board havlng a first end and a second end opposite to the flrst end; a plurality of variable wavelength llght emitting 212~78 elements arranged at a constant pitch along the first end of said optical link conversion board and emitting op~ical signal components having different wavelengths; optical star coupler means mixing ~he optical signal components received from said light emitting elements and outputting a mixed optical signal; and a plurality of multi-wavelength selective filters arranged at a constant pitch along the second end of said optical link conversion board and receiving the mixed optical signal from said optical star coupler means, each of said multi-wavelength selective filters selectively outputting an optical ~ignal which includes optical signal components having desired wavelengths out of the wavelengths included in the optical signal components making up the mixed optical signal, wherein said multi-wavelength selective filter comprises a first optical star coupler ~hich drops the mixed optlcal signal received from said optical star coupler means and outputs optical signals, a plurality of wavelength selecting elements which receive the optical signals from aid first optical star coupler and respectively output optical signal component~ from said wavelength selecting elements and outputs the optical signal which includes the optical signal components having the desired wavelengths.
Other objects and further features of the present invention will be apparent from the following detailed description when read in con~unctlon with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a system block diagram generally showing an optical link conversion board of a conceivable photonic switching system;

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Figure 2 i5 a perspective view ~howing the conceivable photonic switching system;
Figure 3 is a system block diagram generally showing an optical link conversion board of another conceivable photonlc switching system;
Figure 4 is a system block diagram showing an optical link conversion board of a first embodiment of a photonic switching system accordlng to the present lnvention;
Flgure 5 is a system block diagram showing an optical link converslon board of a second embodiment of the photonic switchlng system accordlng to the present lnventlon;
Figures 6 and 7 are system block diagrams for explaining ;
the blocking which occurs depending on the number of stages of optical link converslon board groups;
Figures 8 and 9 are system block diagram~ respectlvely showing optical link conversion boards of first and second optical link conversion board groups used in a third embodiment of the photonic switching system according to the present invention;
Figure 10 i5 a perspective view generally showing the third embodiment of the photonlc switching system 212~7~

1 according to the present invention;
FIG.ll is a system block diagram showing an embodiment of a multi-wavelength selective filter;
FIG.12 is a system block diagram generally showing an optical link conversion board of a first optical link conversion board group used in a fourth embodiment of the photonic switching system according to the present invention;
FIGS.13A through 13C are diagrams for explaining the fourth embodiment of the photonic switching system;
FIG.14 is a system block diagram for explaining another embodiment of a multi-wavelength selective filter;
FIG.15 is a system block diagram showing the multi-wavelength selective filter shown in FIG.14 in more detail; and FIG.16 shows an embodiment of a fiber notch filter shown in FIG.15.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
First, a description will be given of a conceivable photonic switching system so as to facilitate the understanding of the present invention.
FIG.l shows an optical link conversion board l of the conceivable photonic switching system. The optical link conversion board 1 is made of a light guide material and has a generally flat shape.
A plurality of wavelength converter elements 2 which can convert the wavelength of input light (hereinafter referred to as an optical signal) into arbitrary wavelength are provided on the left end of the optical link conversion board l in FIG.l at a constant pitch. Each wavelength converter element 2 has a light 3S input end facing left and a light output end facing right in FIG.l. For example, 16 or 17 wavelength converter elements 2 are provided. For example, a : ,, 2~2~78 1 wavelength converting laser diode which can freely convert the wavelength of the input optical signal by controlling an applying current may be used for the wavelength converter element 2.
A combiner 5 combines output optical signals of all the wavelength converter elements 2 and outputs an optical signal to a deflector 3. For example, a photocoupler is used as the combiner 5. The combiner 5 is provided at a central part of the optical link conversion board 1, and output ends of the wavelength converter elements 2 and the combiner 5 are optically coupled via guide means 9 such as optical waveguides and optical fibers.
In principle, the deflector 3 may use refraction of a prism. The deflector 3 deflects the optical signal from the combiner 5 in different directions depending on the wavelength, and optical signals are output from the right end of the optical link conversion board 1 at a constant interval.
Accordingly, the optical signals input to the wavelength converter elements 2 at the left end of the light link conversion board 1 are output from different positions at the right end of the optical link conversion board 1 depending on the wavelength converted in each wavelength converter element 2.
In other words, by controlling the wavelength at each wavelength converter element 2, each optical signal is output from an arbitrary position at the right end of the optical link conversion board 1.
As shown in FIG.2, a plurality of the above described optical link conversion boards 1 are arranged in parallel to form an optical link conversion board group. For example, a first optical link conversion board group la is made up of 16 optical link conversion boards 1 which are arranged vertically and are mutually parallel. For example, a second optical link conversion board group lb is made up of 17 optical link conversion ~ .

-' 2}2~7~

1 boards 1 which are arranged horizontally and are mutually parallel. For example, a third optical link conversion board group lc is made up of 16 optical link conversion boards 1 which are arranged vertically and are mutually parallel.
Each light input end (wavelength converter element 2) of the first optical link conversion board group la is arranged to match a corresponding one of light output positions of 16 (horizontal) x 17 tvertical) = 272 channels of an optical transmitter part 101. In addition, the first and second optical link conversion board groups la and lb are coupled in series and perpendicular to each other so that each light output position of the first optical link conversion board group la matches a corresponding one of light input ends (wavelength converter elements 2) o~ the second optical link conversion ~oard group lb.
Similarly, the second and third optical link conversion board groups lb and lc are coupled in series and perpendicular to each other so that each light output position of the second optical link conversion board group lb matches a corresponding one of light input ends (wavelength converter elements 2) of the third optical link conversion board group lc. In this case, each optical link conversion board l of the first and third optical link conversion board groups la and lc has 17 wavelength converter elements 2, and each optical link conversion board 1 of the second optical link conversion board group lb has 16 wavelength converter elements 2.
According to this conceivable photonic switching system, the wavelength of the output optical signal may be adjusted individually in each of the first through third optical link conversion board groups la through lc so as to guide the optical signal output from each optical communication channel of the optical transmitter part 101 to an arbitrary optical 212~878 1 communication channel of an optical receiver part 102.
Of course, it is possible to arrange the first and third optical link conversion board groups la and lc horizontally and the second optical link conversion board group lb vertically with respect to the optical transmitter part 101 and the optical receiver part 102.
If blocking is permitted, it is possible to omit the third optical link conversion board group lc and form the photonic switching system using only two stages of optical link conversion board groups (that is, the first and second optical link conversion board groups la and lb). However, when three stages of optical link conversion board groups are provided as shown in FIG.2, it becomes possible to carry out a blocking-free routing of optical signals.
FIG.3 shows an optical link conversion board of another conceivable photonic switching system. In FIG.3, those parts which are the same as those corresponding parts in FIGS.l and 2 are designated by the same reference numerals, and a description thereof will be omitted.
In the optical link conversion board la shown in FIG.3, a variable wavelength light emitting element 4 which can emit an optical signal having an arbitrary wavelength is provided in place of the wavelength con~erter element 2. In addition, the optical link conversion board 1 of tha first optical link conversion board group la and the optical transmitter part 101 may be provided integrally. For example, a wavelength tunable laser diode which generates laser beams of different wavelengths by varying the applying current may be used for the variable wavelength light emitting element 4.
Next, a description will be given of a first embodiment of a photonic switching system according to the present invention, by referring to FIG.4. In FIG.4, those parts which are the same as those corresponding 212& ?178 -~ _ 9 _ 1 parts in FIGS.l and 3 are designated by the same reference numerals, and a description thereof will be omitted.
The optical link conversion board l shown in FIG.4 may be used as each of the first through third optical link conversion groups la through lc shown in FIG.3. In FIG.4, a photocoupler 5 is used as the combiner and an acousto-optic device 23 is used as the deflector. A collimator 6 forms the output light of the photocoupler 5 into parallel light beams, and an optical amplifier 7 compensates for the optical loss at the acousto-optic device 23. A lens 8 converges the light beam at the light output position.
A signal having an RF frequency f is applied to the acousto-optic device 23. An angle e of diffraction of the acousto-optic device 23 can be described by ~ = f~/v, where ~ denotes the wavelength and v denotes the speed of sound within an acousto-optic medium.
Accordingly, in order to change ~, the RF
frequency f or the speed v is changed. When an optical signal including optical signal components having various wavelengths is input to the acousto-optic device 23, the input optical signal (light) takes an angle of diffraction dependent~-on the wavelength and is deflected in different directions without the need to change the RF frequency f. Hence, by appropriately selecting the RF frequency f, the optical signal components having different wavelengths can be ouL~L sequentially from the right end of the optical link conversion board 1 at constant intervals depending on the wavelength.
FIG.5 shows an optical link conversion board of a second embodiment of the photonic switching system according to the present invention. In FIG.5, those parts which are the same as those corresponding parts in FIGS.3 and 4 are designated by the same reference -numerals, and a description thereof will be omitted.

212~87~

1 In this embodiment, the variable wavelength - light emitting element 4 is provided in place of the wavelength converter element 2 of the optical link conversion board 1 of the first optical link conversion board group la.
In addition, it is possible to deflect the optical signal to a predetermined light output position by inputting the input optical signal to dif~erent acousto-optic devices 23 and applying signals having different RF frequencies f to the acousto-optic devices 23.
Furthermore, it is possible to use a ; diffraction grating or a hologram as the beam deflector. A wave length divider may be used in place of the acousto-optic device 23 and the optical signal may be guided thereafter to the predetermined light output position using an optical fiber or the like.
Moreover, a light refractive index crystal may be used in place of the acousto-optic device 23. In this case, a diffraction grating is formed by irradiating on the crystal light beams from both sides with an angle of 45~ in both the upward and downward directions.
However, in the first and second embodiments described above, it is~impossible to freely guide the optical signals from all input positions to any output position when only two stages of the optical link conversion board groups are used, and the so-called blocking occurs. For this reason, it is necessary to connect three stages of the optical link conversion board groups in order to carry out the blocking-free routing of the optical signals.
FIG.6 shows a case where only two stages of optical link conversion board groups are connected, where there are 3 x 3 = 9 input ports and output ports.
When the input signals at the input ports 3 and b respectively are to be output from the output ports G

212~378 1 and H, it is only possible to output the signal at the input port a to the output port G or the signal at the input port b to the output port G because there is only one route which connects optical link conversion boards 301 and 302 as indicated by a thick solid line in FIG.6. In other words, the blocking occurs.
On the other hand, FIG.7 shows a case where three stages of optical link conversion board groups are connected, where there are 3 x 3 = 9 input ports and output ports. When the input signals at the input ports a and b respectively are to be output from the output ports G and H, it is possible to output the signal at the input port a to the output port G and to output the signal at the input port b to the output port G because there are more than one route connecting optical link conversion boards 201 and 202 as indicated by a thick solid line in FIG.7. In FIG.7, there are three routes connecting the optical link conversion boards 201 and 202, and no blocking occurs.
Next, a description will be given of embodiments in which the blocking can be prevented even when only two stages of optical link conversion board groups are connected.
FIGS.8 and 9 are system block diagrams ;~
respectively showing optical link conversion boards of in first and second optical link conversion board groups which are used in a third embodiment of the photonic switching system according to the present invention. In FIGS.8 and 9, those parts which are the same as those corresponding parts in FIGS.4 and 5 are designated by the same reference numerals, and a description thereof will be omitted.
In FIG.8, an optical link conversion board 11 which forms a first optical link conversion board group lla has the variable wavelength light emitting elements 4 provided at the input (left) end thereof for generating optical signals having arbitrary . ~
~ .
.
.

212~87~

1 wavelengths. An optical star coupler 15 is provided at the central part of the optical link conversion board 11 for mixing the optical signals output from all of the variable wavelength light emitting elements 4. The mixed optical signal is guided to the light output positions at the output (right) end. A multi-wavelength selective filter 13 is provided at each light output position. The multi-wavelength selective filter 13 selects an arbitrary wavelength out of the mixed optical signal. Hence, from each light output position, it is possible to output an arbitrary number of optical signal components having arbitrary wavelengths or to output no optical signal. The optical link conversion board 11 of the first optical link conversion board group lla and the optical transmitter part 101 mayr or may not be provided integrally.
In FIG.9, an optical link conversion board 12 which forms a second optical link conversion board group 12a has light input parts 16 provided at the input (left) end thereof solely for receiving input optical signal. ~he light input parts 16 are arranged at a constant pitch. Wavelength filters 17 are provided at the output (right) end of the optical link conversion board 12 The wavelength filters 17 are arranged at a constant pitch. Each wavelength filter 17 selectively outputs an optical signal component having an arbitrary wavelength out of the optical signal received from the optical star coupler 15.
Because the optical link conversion board 11 of the first optical link conversion board group lla has the structure shown in FIG.8 and the optical link conversion board 12 of the second optical link conversion board group 12a has the structure shown in FIG.9, the plurality of optical signal components output from one light output position of the optical link conversion board 11 can be separated and output from differen~ light output positions of the optical link '"' '': :

212~78 .
1 conversion board 12. Hence, whPn the first and second optical link conversion board groups lla and 12a are connected as shown in FIG.10, it is possible to carry out the routing of the optical signals from the optical transmitter part 101 to the optical receiver part 102 without introducing the blocking, although only two stages of optical link conversion board groups are provided.
FIG.11 shows an embodiment of the multi-wavelength selective filter 13. The multi-wavelength selective filter 13 includes optical star couplers 13a and 13c and wavelength filters 13b. The optical star coupler 13a drops the input optical signal into a plurality of optical signal components. The dropped optical signal components from the optical star coupler 13a are passed through the wavelength filters 13b. Each wavelength filter 13b can selectively output optical signal component having an arbitrary wavelength dependent on a control signal CNT applied thereto. The optical signal components from the wavelength filters 13b are mixed and output from the optical star coupler -13c.
For example, the number of wavelength filters 13b is equal to the number of wavelengths of the optical -signal components included in the input optical signal.
Hence, it is possible to pass an arbitrary number of optical signal components having arbitrary wavelengths by independently controlling the wavelength filters 13b so that optical signal components having different wavelengths are permitted to pass or not permitted to pass at all.
FIG.12 shows the optical link conversion board 11 of the first optical link conversion board group lla which is used in a fourth embodiment of the photonic switching system according to the present invention. In FIG.12, those parts which are the same as those corresponding parts in FI&S.4 and 8 2r2 design2,ed bv 212~878 1 the same reference numerals, and a description thereof will be omitted.
In this embcdiment, an acousto-optic device 23 is used in place of the multi-wavelength selective filter 13. In addition, the acousto-optic device 23 is driven by a modulation frequency f in which frequencies fl, f2, ..., fl7 may be multiplexed. The optical star coupler 15, the collimator 6, the optical amplifier 7 and the lens 8 are the same as those described in 10 conjunction with FIG.4. -According to this emhodiment, the second optical link conversion board group 12a may be made up of the optical link conversion board 12 shown in FIG.9.
By using the second optical link conversion board group 12a and the first optical link conversion board group lla which is made up of the optical link conversion board 11 shown in FIG.12, it is also possible to carry out a blocking-free routing of optical signals using only two stages of optical link conversion board groups.
In this embodiment, the acousto-optic device 23 deflects one or a plurality of optical signal components having a plurality of wavelengths to a desired light output position of the optical link conversion board 1. FIG.13A shows a case where the RF
frequency f = fl is applied to the acousto-optic -~-device 23 to deflect the optical signal component having the wavelength Al to a light output position LOP2.
Similarly, FIG.13B shows a case where the RF frequency f = f2 is applied to the acousto-optic device 23 to deflect the optical signal component having the wavelength A2 to the light output position LOP2.
FIG.13C shows a case where the RF frequency f = f f2 is applied to the acousto-optic device 23 to deflect the optical signal components having the wavelengths ~1 and 12 to the light ~uL~uL position LOP2.
Hence, according to this embodiment, it is 212~78 1 possible to output to one light output position of the optical link conversion board 1 an optical signal whicA
includes a plurality of optical signal components having different wavelengths. This is the reason why it becomes possible to carry out a blocking-free routing of optical signals by use of only two stages of optical link conversion boards.
Of course, the embodiment shown in FIG.4 may be modified similarly like the fourth embodiment of the photonic switching system.
In the embodiments described above, the optical link conversion boards need not be connected directly, and optical fibers or optical fiber bundles may be used to connect the optical link conversion boards. In addition, when a semiconductor laser diode amplifier or an Er doped fiber having optical amplifying function is inserted in the optical fibers or optical fiber bundles, it is possible to compensate for the optical loss introduced at each optical link conversion board and prevent characteristic deterioration of the light receiving circuit on the reception side.
Furthermore, in the described embodiments, the so-called cross connection is taken as an example of the optical switching. However, when a part of the input or output channel is dropped, it is of course possible to easily carry out the so-called insert or drop.
Next, a description will be given of another embodiment of tne multi-wavelength selective filter.
According to this embodiment of the multi-wavelength selective filter, it is possible to extract an arbitrary number of optical signal components having arbitrary wavelengths out of an optical signal which includes a plurality of optical signal components having different wavelengths.
First, a description will be given of an operating principle of the multi-wavelength selective filter, by relerring ~o rIG.14. The mul~i-wavelength 212~7~

1 selective filter shown in FIG.14 includes a plurality of speciflc waYelength eliminating means S01, a plurality of optical link switching means 503 and a control means 504 which are coupled as shown.
The plurality of specific wavelength eliminating means 501 respectively eliminate optical signal components having different wavelengths from passing optical signal. The plurality of optical link switching means 503 can freely switch the optical links so that the optical signal transmitted through an optical link 502 is transmitted as it is through the optical link 502 or is returned to the optical path after passing through the specific wavelength eliminating means 501. The control means 504 controls the operation of each optical link switching means 503.
Hence, it is possible to pass only the optical signal components having wavelengths other than the wavelength eliminated by the specific wavelength eliminating means 501. As a result, it is possible to pass an arbitrary number of optical signal components having arbitrary wavelengths from a case where all the optical signal components having the different wavelengths are passed to a case where all the optical signal components having the different wavelengths are not passed at all.
FIG.15 shows the embo~; -nt of the multi-wavelength selective filter shown in FIG.14 in more detail. In FIG.15, those parts which are the same as those corresponding parts in FIG.14 are designated by the same reference numerals, and a description thereof will be omitted.
In a multi-wavelength selective filter S10 shown in FIG.15, a fiber notch filter is used as the specific wavelength eliminating means 501. An optical fiber is used as the optical link 502, and an optical switch is used as the optical link switching means 503.
A control circuit is used as the control means 504. A
plurality or optical switches 503 are inserted in se-les 212 ~ 3 7 8 , ~.

1 in the optical fiber 502 for arbitrarily switching the optical link. For example, the number of optlcal switches 503 is equal to the number of optical signal components having the different wavelengths included in the optical signal which is transmitted in the optical fiber 503. In other words, when the optical signal includes 10 kinds of optical signal components having the different wavelengths, then 10 optical switches 503 are inserted.
The fiber notch filter 501 eliminates an optical signal component having a specific wavelength from the passing optical signal. The number of fiber notch filters 501 provided corresponds to the number of optical switches 503 which are provided. The fiber notch filters 501 respectively eliminate optical signal components having mutually different wavelengths from the passing optical signal.
FIG.16 shows an embodiment of the fiber notch filter 501 which includes first and second coupler parts 511 and 513, and a delay loop 512 which is made of an optical fiber. The input optical signal is equally dropped into two optical signal components. One optical signal component from the first coupler part 511 is supplied directly to the second coupler part 513, while the other optical signal component from the first coupler part 511 is supplied to the second coupler part 513 after passing through the delay loop 512. The optical signal components from the first coupler part 511 and the delay loop 512 are mixed into one optical signal and then equally dropped into two optical signal components by the second coupler part 513. Only one of the two optical signal components from the second coupler part 513 is output from the fiber notch filter 501.
Accordingly, the optical signal components which are mixed at the second coupler part 513 after passing two different routes have a phase difference 2~26878 1 because one of the optical signal components is passed through the delay loop 512. As a result, the optical signal component having a specific wavelength is attenuated and eliminated by the interference and only the optical signal component having the remaining wavelengths is output. The fiber notch filters 501 shown in FIG.15 can respectively eliminate optical signal components having mutually different wavelengths because the lengths of the delay loops 512 are different for each fiber notch filter 501.
Returning now to the description of FIG.15, the optical switches 503 are provided so that it is possible to individually select whether the optical signal transmitted through the optical fiber 502 is to be transmitted as it is through the optical fiber 502 or is to be returned to the optical fiber 502 after passing through the fiber notch filter 501. For example, the optical switch 503 on the right side in FIG.15 passes the optical signal as it is through the optical fiber 502, while the optical switch 503 on the left side in FIG.15 returns the optical signal to the optical fiber 502 after passing the optical signal through the fiber notch filter 501.
The switching of the optical switches 503 can ~' 25 be made by varying applying voltages--to the optical switches 503. The control circuit 504 controls this switching of the optical switches 503. The control circuit 504 includes switches 541 and voltage generating circuits 542. For example, a control signal from a computer (not shown~ is input to the control circuit 504, and the switches 541 which are provided in correspondence with the optical switches 503 are opened or closed in response to the control signal, thereby controlling the corresponding voltage generating circuits 542 to an ON or OFF state. The applied currents to the optical switches 503 are independently controlled so as to independently control the optical 212~78 ::-' "' - 19 -1 link switching operation of the optical switches 503, and thus, the optical signal is passed through one or a plurality of arbitrary fiber notch filters 501.
~herefore, when the optical signal does not pass through any fiber notch filter 501, all of the wavelengths of the optical signal are transmitted through the optical fiber 502. On the other hand, when ~ :
the optical signal passes through all of the fiber notch filters 501, all of the wavelengths of the optical 10 signal are eliminated and no optical signal is output :
from the multi-wavelength selective filter 510.
Further, when the optical signal passes through one or a plurality of fiber notch filters 501, only the optical signal components having the wavelengths other than one or plurality of wavelengths eliminated by the one or plurality of fiber notch filters 501 are transmitted ~:
through the optical fiber 502 and output from the multi-wavelength selective filter 510.
Of course, the multi-wavelength selective filter 510 can be used in place of the multi-wavelength selective filter 13 shown in FIG.8.
Further, the present invention is not limited to these embodiments, but various variations and modifications may be made without departing from the : -~ 25 scope of the present invention. ;

Claims (3)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A photonic switching system comprising:
an optical link conversion board having a first end and a second end opposite to the first end;
a plurality of variable wavelength light emitting elements arranged at a constant pitch along the first end of said optical link conversion board and emitting optical signal components having different wavelengths;
a single optical star coupler means mixing the optical signal components received from said light emitting elements and outputting a mixed optical signal; and a plurality of multi-wavelength selective filters arranged at a constant pitch along the second end of said optical link conversion board and receiving and processing only the mixed optical signal from said single optical star coupler means, each of said multi-wavelength selective filters selectively outputting an optical signal which includes optical signal components having desired wavelengths out of the wavelengths included in the optical signal components making up the mixed optical signal.

2. A photonic switching system comprising:
an optical link conversion board having a first end and a second end opposite to the first end;
a plurality of variable wavelength light emitting elements arranged at a constant pitch along the first end of said optical link conversion board and emitting optical signal components having different wavelengths;
optical star coupler means mixing the optical signal components received from said light emitting elements and outputting a mixed optical signal; and a plurality of multi-wavelength selective filters arranged at a constant pitch along the second end of said optical link conversion board and receiving the mixed optical signal from said optical star coupler means, each of said multi-wavelength selective filters selectively outputting an optical signal which includes optical signal components having desired wavelengths out of the wavelengths included in the optical signal components making up the mixed optical signal, wherein said multi-wavelength selective filter comprises a first optical star coupler which drops the mixed optical signal received from said optical star coupler means and outputs optical signals, a plurality of wavelength selecting elements which receive the optical signals from said first optical star coupler and respectively output optical signal components from said wavelength selecting elements and outputs the optical signal which includes the optical signal components having the desired wavelengths.

3. The photonic switching system as claimed in claim 1, wherein said multi-wavelength selective filter comprises a plurality of eliminating means respectively for eliminating an optical signal component having a specific wavelength, a plurality of switching means respectively coupled to a corresponding one of said eliminating means for passing an optical signal as it is or through the corresponding eliminating means in response to a control signal, and control means for controlling switching of said switching means by supplying the control signal to each of said switching means, said switching means being coupled in series in n stages and receiving the optical signal from said optical star coupler means at the switching means in a first stage and outputting the optical signal which includes the optical signal components having the desired wavelength components from the switching means in an nth stage.