NL1019309C2 - Method and device for processing light. - Google Patents

Description

Method and device for processing light

The invention relates to a method for processing light, comprising the steps of: A. separating, by means of a first processing means, a first luminous flux into: a second luminous flux comprising a first sub-signal with wavelengths falling within a first range and a first polarization direction and a third luminous flux comprising a second sub-signal with wavelengths falling within the first range and a second polarization direction, which second polarization direction is perpendicular to the first polarization direction; B. converting the third luminous flux into a fourth luminous flux by means of a first polarization rotating means, the second sub-signal being converted into a third sub-signal with wavelengths falling within the first range and a polarization direction equal to the first polarization direction, and C. separating a second processing means from the fourth luminous flux into: - a fifth luminous flux comprising a fourth sub-signal with wavelengths falling within the first range and a first polarization direction, and a sixth luminous flux.

The invention furthermore relates to a device for processing light comprising: - a first processing means for separating a first luminous flux into: - a second luminous flux comprising a first sub-signal with wavelengths falling within a first range and a first polarization direction, and a third luminous flux comprising a second sub-signal with wavelengths falling within the first range and a second polarization direction, which second polarization direction is perpendicular to the first polarization direction; a first polarization rotation means for converting the third luminous flux into a fourth luminous flux wherein the second sub-signal is converted into a third sub-signal with wavelengths falling within the first range and a polarization direction equal to the first polarization direction, and a second processing means for the separating the fourth luminous flux into: a fifth luminous flux comprising a fourth sub-signal with wavelengths falling within the first range and a first polarization direction, and - a sixth luminous flux.

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Methods and devices for processing light are known with which a sub-signal with wavelengths falling within a certain range can be separated from a luminous flux, or with which luminous fluxes can be combined. However, the use of polarization-dependent optical components such as ring resonators also makes such known methods and devices polarization-dependent. For many applications, however, a polarization-independent operation is desirable because, for example, the direction of polarization of the light is arbitrary, time-changeable, or not at all determined.

JP 4-358115 describes making a filter polarization independent by splitting light into two orthogonally polarized components, wherein the polarization direction of one component is rotated 90 ° both before and after filtering so that both components can be filtered by a single polarization dependent filter element. A disadvantage is the relatively large number of different optical components. Furthermore, the optical paths for the two components are not the same, as a result of which a mostly undesirable transit time difference, and associated phase difference, is created.

In US 5,388,001 we find a polarization-independent optical filter based on a wavelength-dependent polarization converter in combination with a polarization splitter and two polarization filters. The disadvantage is the complexity of the whole and the large number of optical components required.

WO 01/22139 describes a filter composed of two micro ring resonators, one for extraction of a TE-polarized sub-signal falling within a certain wavelength range, and the other for extraction of the complementary TM-polarized sub-signal. A disadvantage is that two different types of very well-matched microring resonators are required, which is difficult to realize in practice. Furthermore, also here the optical paths for the two sub-signals are not the same, which in turn leads to a usually undesirable transit time difference.

The object of the present invention is to provide a simple and effective method for processing light, preferably without the aforementioned disadvantage of a time difference between complementary sub-signals occurring during execution of the method. Another object of the invention is to provide a constructionally simple, polarization-independent device constructed from a limited number of polarization-dependent optical components, such as ring resonators and polarization rotators, and suitable for applying such a method.

To this end, the invention provides a method for processing light comprising the steps mentioned in the preamble, characterized in that the processing means are the same.

In this way, all light falling within a specific wavelength range can be separated from a luminous flux, regardless of the polarization direction.

By "one and the same" is meant here and in the following "with the same properties relevant to the operation concerned." Here and hereinafter, "light" means whether or not coded or modulated light is used, whereby frequencies outside the visible range are not excluded. Furthermore, "falling in", "right", and "perpendicular" here and in the following should always be read as "substantially falling in", "substantially the same" or "substantially perpendicularly". Similarly, for "one / the luminous flux" and "one / the partial signal", "at least a part of a / the luminous flux" or "at least a part of a / the partial signal" must always be read. For the sake of readability, the phrases "mainly" and "at least a part of" have always been omitted.

In a preferred application, the method comprises, in addition to steps AC, also the steps: D. separating the fifth luminous flux by means of a third processing means into: a seventh luminous flux comprising a fifth sub-signal with wavelengths falling within the first range and a first polarization direction, and an eighth luminous flux; E. converting the seventh luminous flux into a ninth luminous flux by means of a second polarization rotary means, the fifth sub-signal being converted into a sixth sub-signal with wavelengths falling within the first range and a polarization direction equal to the second polarization direction, and F. combining a fourth processing means of the first sub-signal and the ninth luminous flux into a tenth luminous flux, wherein: the processing means are the same, and the polarization-rotating means are the same.

4

Thus, complementary sub-signals falling within a certain wavelength range can be separately separated from a luminous flux and then be combined, for example to be further processed or transported.

The second processing means and the third processing means can thereby coincide, and preferably also the first processing means and the fourth processing means, which involves a generally pursued reduction of the number of components required.

By "coincidence" is meant here and hereinafter "insofar as the relevant parts are concerned, become one in which the separate functions of separating and joining are performed by one and the same processing means".

And optionally also the first polarization rotation means 31 and the second polarization rotation means 32 can coincide, which means an even further reduction of the number of components required.

In another preferred application, the method comprises, in addition to steps A-C, also the steps of: DD. separating the second luminous flux by means of a fifth processing means into: a twelfth luminous flux comprising a seventh sub-signal with wavelengths falling within the first range and a first polarization direction, and a thirteenth luminous flux; 20 EE. converting the twelfth luminous flux into a fourteenth luminous flux by means of a third polarization rotary means, the seventh sub-signal being converted into an eighth sub-signal with wavelengths falling within the first range and a polarization direction equal to the second polarization direction, and FF. combining the fourth sub-signal and the fourteenth luminous flux into a fifteenth luminous flux by means of a sixth processing means, wherein: the processing means are the same and the polarization rotating means are the same.

In this way the total optical paths for the complementary sub-signals 30 can be made equal within a certain wavelength range so that no undesired mutual transit time difference arises during the execution of the method.

5

The second processing means and the sixth processing means can coincide here, and also the first processing means and the fifth processing means, which in turn entails a generally pursued reduction of the number of components required.

And optionally also the first polarization rotary means and the third polarization rotary means can coincide, which in turn means a still further reduction of the number of components required.

A method according to the invention can also comprise the step of: X. combining at least one extra-luminous flux with at least one of the luminous fluxes by means of at least one extra processing means.

In this way, one or more additional luminous fluxes can be added so that combined and more complex operations with multiple luminous fluxes become possible.

The extra-processing means preferably coincides with one of the processing means. One or more of the processing means already present are then also used for introducing one or more extra-luminous fluxes.

In addition, the extra-luminous flux can comprise at least one luminous flux, which luminous flux is obtained by carrying out at least one step of a method according to the invention.

In this way, for example, after separating sub-signals with wavelengths falling within a first range, sub-signals with wavelengths falling within a second range can then be separated. This can again be repeated for a third range, etc., so that it is possible to separate sub-signals falling within a number of specific wavelength ranges separately. It is also possible, for example, to add separated sub-signals to a luminous flux. The number of options for separating and reassembling is in principle unlimited, which makes complex optical operations possible with a minimum number of components.

The invention further provides an apparatus for processing light of the type mentioned in the preamble, characterized in that the processing means are the same.

Such a device is very simple in construction and comprises only two types of optical components: one type of polarization-dependent wavelength-dependent filter element and one type of polarization driver.

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In a preferred embodiment the device also comprises: a third processing means for separating the fifth luminous flux into: a seventh luminous flux comprising a fifth sub-signal with wavelengths falling within the first range and a first polarization direction, and - an eighth luminous flux, and a second polarization turning means for converting the seventh luminous flux into a ninth luminous flux wherein the fifth sub-signal is converted into a sixth sub-signal with wavelengths falling within the first range and a polarization direction equal to the second polarization direction, and - a fourth processing means for merging the first sub-signal and the ninth luminous flux to a tenth luminous flux, wherein: the processing means are the same, and the polarization rotating means are the same.

For example, orthogonally polarized complementary sub-signals falling within a certain wavelength range can be separately separated from a luminous flux and subsequently combined, for example for further processing or transport.

The second processing means and the third processing means can thereby coincide, and preferably also the first processing means and the fourth processing means, which involves a generally pursued reduction of the number of components required.

And optionally also the first polarization rotation means and the second polarization rotation means can coincide, which means a still further reduction of the number of components required.

In another preferred embodiment, the device also comprises: a fifth processing means for separating the second luminous flux into: a twelfth luminous flux comprising a seventh sub-signal with wavelengths falling within the first range and a first polarization direction, and a thirteenth luminous flux; a third polarization rotary means for converting the twelfth luminous flux into a fourteenth luminous flux wherein the seventh sub-signal is converted into a 7 eighth sub-signal with wavelengths falling within the first range and a polarization direction equal to the second polarization direction, and a sixth processing means for merging from the fourth sub-signal and the fourteenth luminous flux to a fifteenth luminous flux, wherein: - the processing means are the same, and - the polarization-rotating means are the same.

The device is thus polarization independent and does not have the aforementioned disadvantage of a transit time difference between sub-signals generated by the device. The number of optical components is in principle still limited to one type of polarization-dependent wavelength-dependent filter element and one type of polarization driver. The second processing means and the sixth processing means can coincide here, and also the first processing means and the fifth processing means, which in turn entails a generally pursued reduction of the number of components required.

And optionally also the first polarization rotary means and the third polarization rotary means can coincide, which in turn means a still further reduction in the number of components required.

A device according to the invention can also comprise at least one extra processing means for combining at least one extra light current with at least one of the light currents.

The device can thus be made suitable for combined and more complex operations with multiple luminous fluxes. The extra-processing means preferably coincides with one of the processing means. The total number of required processing means is thus limited.

The extra-luminous flux can herein comprise at least one luminous flux which luminous flux is obtained by means of a device according to the invention.

The number of options for separating and reassembling is in principle unlimited, which makes complex optical operations possible with a minimum number of components. The device can thus be made suitable for, for example, multiplexing and demultiplexing tasks.

8

In a preferred application of a method according to the invention or in a preferred embodiment of a device according to the invention, at least one of the processing means comprises a ring resonator, preferably a micro ring resonator. Ring resonators, such as microdisk resonators or microring resonators or combinations of several resonators, are satisfactory as wavelength-dependent filters, in which their polarization-dependent behavior, which is undesirable for many known devices, can be exploited in a method or device according to the invention.

A device according to the invention equipped with micro ring resonators is extremely suitable for being manufactured integrally and miniaturized by, for example, using techniques known from the field of "microsystem technology", also known as "microstructural technology".

The invention is explained below with reference to a number of non-limiting exemplary embodiments. To that end: figure 1 schematically shows a basic first embodiment of a device according to the invention; figure 2 schematically a second embodiment; figure 3 schematically a third embodiment; figure 4 schematically a fourth embodiment, in principle functionally the same as the third embodiment of figure 3 but with a different layout; Fig. 5 schematically shows a fifth embodiment, in principle functionally the same as the second embodiment, but with processing means coinciding; Fig. 6 schematically shows a sixth embodiment, in principle functionally the same as the second and fifth embodiments, but with polarization rotating means coinciding; Fig. 7 schematically shows a seventh embodiment, in principle functionally the same as the third and fourth embodiments, but with processing means coinciding; Fig. 8 schematically shows an eighth embodiment, in principle functionally the same as the third, fourth and seventh embodiments but with polarization rotating means 30 which coincide; Figure 9 shows a ninth embodiment comprising two mutually coupled devices according to the invention; i.

9 - Figure 10 shows a tenth embodiment comprising two mutually coupled devices according to the invention, and - Figure 11 shows an eleventh embodiment comprising two mutually coupled devices according to the invention, wherein part of the processing means 5 coincide.

Figure 1 shows a basic first embodiment 1 composed of two identical ring resonators 21, 22 which serve as wavelength-dependent polarization-dependent filters, and a polarization turner 31 which rotates the polarization direction of light passed along it through 90 °. By means of the first ring resonator 21 a second luminous flux 42 comprising a first sub-signal 11 is separated from a first luminous flux 41. This first sub-signal 11 comprises light falling within a first wavelength range with a first polarization direction P1. The remaining, third luminous flux 43 containing a second sub-signal 12 falling within the first wavelength range with a second orthogonal polarization direction P2 is guided along the first polarization rotator 31. The third luminous flux 43 is herein converted into a fourth luminous flux 44 comprising a third sub-signal 13 with a polarization direction P2 "equal to the first polarization direction P1. By means of the second ring resonator 22, a fourth luminous flux 45 is separated from the fourth luminous flux 44, comprising a fourth sub-signal 14 with a polarization direction P2 "equal to the first polarization direction P1. Ideally, the first sub-signal 11 and the fourth light signal 14 are complementary orthogonal sub-signals comprising all light falling within the first wavelength range. For example, the remaining sixth luminous flux 46 can be further processed.

In the second embodiment 2 shown in figure 2, the fifth luminous flux 45 is separated by means of a third processing means 23 into a seventh luminous flux 47 and a remaining eighth luminous flux 48. The seventh luminous flux 47, comprising a fifth sub-signal 15 falling within the first wavelength range with a polarization direction P2 'equal to the first polarization direction P1, is converted by means of a second polarization rotation means 32 into a ninth luminous flux 49 comprising a sixth sub-signal 16 with a polarization direction P2 "equal to the second polarization direction P2, which ninth luminous flux 49 is subsequently fourth processing means 24 is combined with the first sub-signal 11 into a tenth luminous flux 50. In an ideal case, the tenth luminous flux 50 will comprise the sum of the first sub-signal 11 and the complementary sixth sub-signal 16. However, due to the difference in the optical paths traversed, there is a transit time difference between these complementary sub-signals 11.16. In many cases, however, such a duration difference is undesirable or its absence is even required.

Figure 3 shows a third embodiment 3 of a device according to the invention in which the transit time difference between the combined complementary sub-signals 14, 18 is minimal, and in an ideal case zero, because the total optical paths involved are equal or equivalent because of the symmetry of the design. To that end, the second luminous flux 42 is separated by means of a fifth separating means 25 into a residual, thirteenth luminous flux 53 and a twelfth luminous flux 52 comprising a seventh sub-signal 17 with a polarization direction equal to the first polarization direction P1. The twelfth luminous flux 52 is guided along a third polarization rotation means 33, the seventh sub-signal 17 being converted into an eighth sub-signal 18 with a polarization direction ΡΓ equal to the second polarization direction P2. Subsequently, the eighth sub-signal 18 and the fourth sub-signal 14 are combined by means of a sixth separating means 26 into a fifteenth luminous flux 55 comprising in principle all light falling within the first wavelength range with no or a minimum transit time difference between the complementary sub-signals 14,18.

The fourth embodiment 4 shown in Figure 4 is functionally the same as the third embodiment 3 and comprises the same components, but the layout of the whole is alarming and such that the light currents do not cross each other. This has the advantage that unwanted cross-talk between the light currents and sub-signals can be reduced or prevented.

Figure 5 shows a fifth embodiment 5, which in principle is functionally the same as the second embodiment 2, in which however both the second and third processing means 22, 23 coincide into a combined, seventh processing means 27, as well as the first 30 and fourth processing means 21, 24 coincide to a combined eighth processing means 28.

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Figure 6 schematically shows a sixth embodiment 6, in principle functionally the same as the second and fifth embodiments 2.5, wherein the polarization rotation means 31, 32 also coincide into a first combined polarization rotation means 61.

Figure 7 shows a seventh embodiment 7 which in principle is functionally the same as the third and fourth embodiments 3,4, in which, however, both the second and sixth processing means 22, 26 coincide into a combined, ninth processing means 29, as well as the first and fifth processing means 21.25 coincide into a combined, tenth processing means 30.

Figure 8 shows schematically an eighth embodiment 8, in principle functionally equal to the third, fourth and seventh embodiments 3,4,7, wherein also the polarizing rotation means 31,33 coincide into a second combined polarization rotation means 62.

This coincidence of components implies a reduction in the number of components required, a reduction in the required surface area and volume, and a reduction in the cost price of the device.

Figure 9 shows a first example of a combined, ninth embodiment 9 in which a remaining, sixth luminous flux 46 'from a second device according to the invention 92 is used as incoming, first luminous flux 41 in a first device according to the invention 91. With this, after splitting off a fifteenth luminous flux 55 'comprising light falling within a certain wavelength range, a fifteenth partial current 55 comprising light falling within a different wavelength range can then be separated. This can be repeated again for a third wavelength range and so on.

Figure 10 gives a second example of a combined, tenth embodiment 10 in which a residual, sixth luminous flux 46 ”from a third device according to the invention 93 is introduced as extra luminous flux X4 into a first device according to the invention 91. Thus, a fourth sub signal (14) and an eighth sub signal (18), comprising light falling within a certain wavelength range, are added to the sixth luminous flux 46 ".

Figure 11 gives a third example of a combined, eleventh embodiment 11 in which a first device according to the invention 91 partially coincides with a 12th device according to the invention 94. Sub-signals can be separated, added and combined with this.

It will be clear to a person skilled in the relevant field that the invention is by no means limited to the described and shown exemplary embodiments and that within the scope of the invention an in principle unlimited number of variations and combinations are possible.

Claims (25)

Method for processing light, comprising the steps of: A. separating by means of a first processing means (21) a first luminous flux (41) into: a second luminous flux (42) comprising a first sub-signal (11) with within a first range falling wavelengths and a first polarization direction, and a third luminous flux (43) comprising a second sub-signal (12) with wavelengths falling within the first range and a second polarization direction, which second polarization direction is perpendicular to the first polarization direction; B. converting the third luminous flux (43) into a fourth luminous flux (44) by means of a first polarizing rotation means (31), the second sub-signal (12) being converted into a third sub-signal (13) with wavelengths falling within the first range and a polarization direction equal to the first polarization direction, and Method according to claim 1, characterized in that the method also comprises the steps of: D. separating the fifth luminous flux (45) by means of a third processing means (23) into: 25. a seventh luminous flux (47) comprising a fifth sub-signal (15) with wavelengths falling within the first range and a first polarization direction, and an eighth luminous flux (48); E. releasing the seventh luminous flux (47) into a ninth luminous flux (49) by means of a second polarizing rotation means (32), wherein the fifth sub-signal (15) is converted into a sixth sub-signal (16) with within the first range wavelengths and a polarization direction similar to the second polarization direction, and F. combining the first sub-signal (11) and the ninth luminous flux (49) into a tenth luminous flux (50) by means of a fourth processing means (24), wherein: the processing means (21 -24) are the same, and - the polarization turning means (31, 32) are the same. Method according to claim 1, characterized in that the method also comprises the 5 steps: DD. separating the second luminous flux (42) by means of a fifth processing means (25) into: - a twelfth luminous flux (52) comprising a seventh sub-signal (17) with wavelengths falling within the first range and a first polarization direction, and - a thirteenth luminous flux (53); EE. converting the twelfth luminous flux (52) into a fourteenth luminous flux (54) by means of a third polarizing rotation means (33), wherein the seventh sub-signal 17 is converted into an eighth sub-signal 18 with wavelengths falling within the first range and a polarization direction equal to the second polarization direction, and FF 15. combining the fourth sub-signal (14) and the fourteenth luminous flux (54) into a fifteenth luminous flux (55) by means of a sixth processing means (26), wherein: the processing means (21, 22, 25, 26) are the same, and the polarization turning means (31,33) are the same. Method according to claim 2, characterized in that the second processing means (22) and the third processing means (23) coincide. Method according to claim 2 or 4, characterized in that the first processing means (21) and the fourth processing means (24) coincide. 6. Method according to claim 2, 4 or 5, characterized in that the first polarization rotation means (31) and the second polarization rotation means (32) coincide. Method according to claim 3, characterized in that the second processing means (22) and the sixth processing means (26) coincide. Method according to claim 3 or 7, characterized in that the first processing means (21) and the fifth processing means (25) coincide. A method according to claim 3, 7 or 8, characterized in that the first polarization rotation means (31) and the third polarization rotation means (33) coincide. A method according to any one of the preceding claims, characterized in that the method also comprises the step of: X. combining at least one extra luminous flux (X1-X4) with at least one of the luminous flux (41-56). A method according to claim 10, characterized in that the extra-processing means coincides with at least one of the processing means (21-26). A method according to claim 10 or 11, characterized in that the extra-luminous flux (X1-X4) comprises at least one luminous flux (42'-56,, 42 "-56", 42 ", -56" ") Luminous flux is obtained by performing at least one step of a method according to the invention. Apparatus (1) for processing light, comprising: 10. a first processing means (21) for separating a first luminous flux (41) into: - a second luminous flux (42) comprising a first sub-signal (11) with within a first range of falling wavelengths and a first polarization direction, and - a third luminous flux (43) comprising a second sub-signal (12) with wavelengths falling within the first range and a second polarization direction, which second polarization direction is perpendicular to the first polarization direction; - a first polarizing rotation means (31) for switching the third luminous flux (43) into a fourth luminous flux (44), wherein the second sub-signal (12) is converted into a third sub-signal (13) with wavelengths falling within the first range and a polarization direction equal to the first polarization direction, and - a second processing means (22) for separating the fourth luminous flux (44) into: - a fifth luminous flux (45) comprising a fourth sub-signal (14) with wavelengths falling within the first range and a first polarization direction, and - a sixth luminous flux (46), characterized in that the processing means (21, 22) are the same. Device (2) according to claim 13, characterized in that the device also comprises: a third processing means (23) for separating the fifth luminous flux (45) into: a seventh luminous flux (47) comprising a fifth sub-signal (15) ) with wavelengths falling within the first range and a first polarization direction, and - an eighth luminous flux (48); 30. a second polarization rotation means (32) for converting the seventh luminous flux (47) into a ninth luminous flux (49), the fifth sub-signal (15) being converted into a sixth sub-signal (16) with wavelengths falling within the first range and a polarization direction equal to the second polarization direction, and a fourth processing means (24) for combining the first sub-signal (11) and the ninth luminous flux (49) into a tenth luminous flux (50), wherein: - the processing means (21- 24) are the same, and 5. the polarization rotating means (31, 32) are the same. Device (3,4) according to claim 13, characterized in that the device also comprises: - a fifth processing means (25) for separating the second luminous flux (42) into: a twelfth luminous flux (52) comprising a seventh sub-signal (17) with wavelengths falling within the first range and a first polarization direction, and 10 - a thirteenth luminous flux (53); - a third polarizing rotation means (33) for converting the twelfth luminous flux (52) into a fourteenth luminous flux (54) wherein the seventh sub-signal (17) is converted into an eighth sub-signal (18) with wavelengths falling within the first range and a polarization direction similar to the second polarization direction, and 15. a sixth processing means (26) for combining the fourth sub-signal (14) and the fourteenth luminous flux (54) into a fifteenth luminous flux (55), wherein: - the processing means (21, 22, 25, 26) are the same, and - the polarization rotating means (31, 33) are the same. C. separating the fourth luminous flux (44) by means of a second processing means (22) into: - a fifth luminous flux (45) comprising a fourth sub-signal (14) with wavelengths falling within the first range and a first polarization direction, and a sixth direction luminous flux (46), characterized in that the processing means (21, 22) are the same. Device (5,6) according to claim 14, characterized in that the second processing means (22) and the third processing means (23) coincide. Device (5,6) according to claim 14 or 16, characterized in that the first processing means (21) and the fourth processing means (24) coincide. Device (6) according to claim 14, 16 or 17, characterized in that the first polarization rotation means (31) and the second polarization rotation means (32) coincide. Device (7,8) according to claim 15, characterized in that the second processing means (22) and the sixth processing means (26) coincide. 20. Device (7,8) according to claim 15 or 19, characterized in that the first processing means (21) and the fifth processing means (25) coincide. Device (8) according to claim 15, 19 or 20, characterized in that the first polarization rotation means (31) and the third polarization rotation means (33) coincide. Device (9-11) according to any one of claims 13-21, characterized in that the device also comprises at least one extra processing means for combining at least one extra luminous flux (XI-X4) with at least one of the light currents (41-56), which extra-processing means preferably coincides with at least one of the processing means (21-26). Device (9-11) according to claim 22, characterized in that the extra-luminous flux (XI-X4) comprises at least one luminous flux (42, -56 ', 42 "-56", 42 "' - 56 '" ) which luminous flux is obtained by means of a device (92-94) according to the invention. A method according to any one of claims 1 to 12, characterized in that at least one of the processing means (21-30) comprises a ring resonator, preferably a micro ring resonator. The device (1-11) according to any of claims 13-23, characterized in that at least one of the processing means (21-30,2Γ-30,, 2Γ'-30 ", 2Γ" -30, ") a ring resonator, preferably a microring resonator.