Patent Application
20250208481
The present application claims priority to EP Patent Application No. EP23386138.4 filed on Dec. 21, 2023, the disclosure of which is incorporated by reference herein in its entirety.
The invention relates to methods and apparatuses for optical modulation, in particular using optical signals to modulate other optical signals.
Photonic integrated circuits (PICs) can carry dense information by separating optical signals in space, wavelength, and polarization. The enhanced bandwidth of photonics enables the efficient and compact realization of applications such as photonic cores, neuromorphic network arrays, broadband photodetection, and optical switches. However, it remains challenging to control and modulate signals in photonic circuits because photons having different frequencies do not interact with one another.
Previous approaches have attempted to modulate optical signals using active electronic circuitry. However, this depends on the relatively weak optical response induced by thermo-optic and electro-optic mechanisms. This inevitably increases the overall device footprint and energy consumption. Such devices also require long interaction lengths, which annihilates wavelength or phase selectivity.
It would therefore be desirable to provide a method and apparatus for optical modulation that solve some or all of these problems.
According to a first aspect of the disclosure, there is provided a method of optical modulation comprising: using a control optical signal to modulate a controlled optical signal, wherein: the controlled optical signal propagates in an optical medium of an optical transmission structure; and the control optical signal modulates the controlled optical signal by being at least partially absorbed in the optical transmission structure and thereby changing an optical property of the optical medium.
This method allows direct control of one optical signal using another. This opens the possibility of fully optical processing, which is highly scalable and has intrinsically high bandwidth.
Optionally, the control optical signal and the controlled optical signal propagate in the optical medium. Having both signals in the same medium can make the device more compact and increase the strength of their interaction.
Optionally, the optical transmission structure comprises a waveguide, a resonator, an interferometer, and/or a photonic crystal. These structures allow for greater control of the propagation and interaction of the optical signals.
Optionally, the changing of the optical property is achieved by one or more of the following: heat generation, inter-band transition, lasing, carrier depletion. These are convenient mechanisms that are well-understood and can be precisely controlled.
Optionally, either or both of the control optical signal and the controlled optical signal form a standing wave in the optical transmission structure. This creates a spatially well-defined distribution of the optical field which can be leveraged for better control and stronger interactions with the control optical signal and/or the controlled optical signal, thereby allowing more precise control of the modulation.
Optionally, the optical transmission structure comprises a plurality of absorbing elements; and the control optical signal forms a first standing wave configured such that electromagnetic radiation in the first standing wave is absorbed at selected portions of the first standing wave by the plurality of absorbing elements. The absorbing elements allow the absorption of the control optical signal to change the optical property of the optical medium.
Optionally, an absorption of the controlled optical signal by the plurality of absorbing elements is lower than an absorption of the control optical signal by the plurality of absorbing elements, optionally at least 50% lower, optionally at least 80% lower, optionally at least 95% lower, optionally at least 99% lower. This allows the effect of the control optical signal to dominate and minimise losses of the controlled optical signal during the modulation.
Optionally, wherein the controlled optical signal forms a second standing wave. This allows greater control of the regions in which the controlled optical signal has high intensity and will interact strongly, thereby allowing more precise control of the modulation.
Optionally, antinodes of the second standing wave are less well aligned with the plurality of absorbing elements than antinodes of the first standing wave. This reduces absorption of the controlled optical signal relative to the control optical signal.
Optionally, the plurality of absorbing elements are regularly spaced along a propagation direction of the optical transmission structure; at least a subset of the antinodes of the first standing wave are substantially aligned with the plurality of absorbing elements; and at least a majority of the antinodes of the second standing wave are aligned with regions nearer to respective midpoints between respective pairs of absorbing elements than with any absorbing element. This maximises absorption of the control optical signal while reducing absorption of the controlled optical signal.
Optionally, the plurality of absorbing elements are regularly spaced along a propagation direction of the optical transmission structure; and either a) a frequency of the control optical signal corresponds to an odd harmonic of the optical transmission structure, and a frequency of the controlled optical signal corresponds to an even harmonic of the optical transmission structure; or b) a frequency of the control optical signal corresponds to an even harmonic of the optical transmission structure, and a frequency of the controlled optical signal corresponds to an odd harmonic of the optical transmission structure. Using opposite odd and even harmonics of the optical transmission structure is a convenient way to ensure the correct relative alignment of the standing wave and absorbing elements within the optical transmission structure.
Optionally, a frequency of the control optical signal corresponds to a first resonance frequency of the optical transmission structure; a difference between the frequency of the control optical signal and the first resonance frequency is selected to produce a predetermined weighting between a change in a property of the control optical signal and the modulation of the controlled optical signal. The difference between the first resonance frequency and the frequency of the control optical signal will affect how strongly the control optical signal is absorbed in the optical transmission structure. Varying this difference allows a weighting to be created between the amplitude of the control optical signal and the strength of its effect on the optical property of the optical medium.
Optionally, a frequency of the controlled optical signal corresponds to a second resonance frequency of the optical transmission structure; a difference between the frequency of the controlled optical signal and the second resonance frequency is selected to produce a predetermined functional form of a relationship between a change in a property of the control optical signal and the modulation of the controlled optical signal. The change in optical property of the optical medium will typically alter the second resonance frequency. Thereby, the relative frequency of the second resonance frequency and the controlled optical signal will determine how the change in optical property affects transmission of the controlled optical signal.
Optionally, the first resonance frequency is different to the second resonance frequency. This allows the control optical signal and controlled optical signal to be more clearly decoupled at an output of the optical transmission structure.
Optionally, information is encoded in the control optical signal and/or the controlled optical signal, and modulating the controlled optical signal comprises performing a computational operation using the encoded information. This permits the method to be used for all-optical computation operations without the need to convert information back and forth from optical to conventional electronics for processing. This removes the losses and delay associated with those conversions.
Optionally, using a control optical signal to modulate the controlled optical signal comprises using a plurality of control optical signals. This allows multiple signals to be combined in a single operation.
Optionally, a frequency of each of the control optical signals corresponds to a resonance frequency of the optical transmission structure; a difference between the frequency of each of the control optical signals and the corresponding resonance frequency is selected to produce a predetermined weighting between a change in a property of the respective control optical signal and the modulation of the controlled optical signal. This allows different control optical signals to have different effects on the controlled optical signal as an output. This permits more complex computational operations.
Optionally, the method further comprises performing a computational operation by combining information encoded in each of the plurality of control optical signals. This can be advantageous for applications such as artificial neural networks and matrix-vector operations.
Optionally, the modulating of the controlled optical signal further comprises changing a property of the control optical signal. This allows the modulation of the controlled optical signal to vary in time as the property of the control optical signal changes.
Optionally the property of the control optical signal comprises an amplitude, phase, or polarisation of the control optical signal. These can all affect the absorption of the control optical signal by the optical transmission structure.
Optionally, the absorbing of the control optical signal changes the optical property via the thermo-optic effect. This is a well-understood effect by which the optical property can be affected.
Optionally, the optical property is refractive index. This has a predictable effect on the transmission of the controlled optical signal.
Optionally, the control optical signal and/or the controlled optical signal enter the optical transmission structure via evanescent coupling to an input waveguide; and/or the control optical signal and/or the controlled optical signal leave the optical transmission structure via evanescent coupling to an output waveguide. These allow for separation of the optical transmission structure from other components and the formation of standing waves, which can be convenient in some circumstances.
Optionally, the first standing wave is formed by: splitting the control optical signal into two portions, optionally equal portions; and coupling the two portions of the control optical signal into the optical transmission structure in opposite propagation directions. This allows the behaviour of the standing wave to be controlled by controlling the splitting of the control optical signal.
Optionally, changing the phase of the control optical signal comprises changing a relative phase of the two portions of the control optical signal. This allows the characteristics of the standing wave to be changed.
Optionally, the method further comprises adjusting a relative phase of the two portions of the control optical signal to increase absorption of the control optical signal by the plurality of absorbing elements. This maximises the efficiency of the device by increasing the effect of the control optical signal.
Optionally, the second standing wave is formed by: splitting the controlled optical signal into two portions, optionally equal portions; and coupling the two portions of the controlled optical signal into the optical transmission structure in opposite propagation directions. This allows the behaviour of the standing wave to be controlled by controlling the splitting of the control optical signal.
Optionally, the method further comprises adjusting a relative phase of the two portions of the controlled optical signal to decrease absorption of the controlled optical signal by the plurality of absorbing elements. This maximises the efficiency of the device by reducing the losses experience by the controlled optical signal.
According to a second aspect of the disclosure, there is provided an optical modulation element configured to use a control optical signal to modulate a controlled optical signal, the optical modulation element comprising: an optical transmission structure comprising an optical medium in which the controlled optical signal can propagate, wherein the optical transmission structure is configured to at least partially absorb the control optical signal such that the absorption causes a change in an optical property of the optical medium; and a controller configured to modulate the controlled optical signal by changing the optical property using the control optical signal.
This element allows direct control of one optical signal using another. This opens the possibility of fully optical processing, which is highly scalable and has intrinsically high bandwidth.
Optionally, the optical transmission structure comprises a plurality of absorbing elements, optionally wherein each of the plurality of absorbing elements comprises one or more of a metal, an intrinsically or extrinsically doped semiconductor, a non-linear material which absorbs light through two photon absorption or other nonlinear process, a dielectric having a non-zero absorption coefficient, or a phase-change material, optionally germanium-antimony-tellurium. Phase-change materials can have large and controllable changes in optical properties, thereby allowing for strong modulation effects.
Optionally, the optical transmission structure comprises a resonator, for example a ring resonator or transmission line resonator. These allow for the formation of standing waves, which can improve performance by controlling regions of high intensity of the optical signals.
Embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings in which corresponding reference symbols represent corresponding parts, and in which
As discussed above, current methods of modulating optical signals often require the interaction of the light with electronic devices. Amongst other problems, this limits the bandwidth and response speed of the modulation. The present method and apparatus allow for all-optical modulation, where one optical signal is used to modulate another optical signal without any requirement for interaction with electronics.
In the context of this invention, optical signals can be any electromagnetic signal. Commonly-used wavelengths for photonic computing are in the near infra-red, as used in the example experimental results below. However, the method and apparatus are not particularly limited thereto with appropriate choice of materials and dimensions.
The optical modulation element 1 comprises an optical transmission structure 4. The optical transmission structure 4 comprises an optical medium 5 in which the controlled optical signal 3 can propagate. As well as the controlled optical signal 3, the control optical signal 2 may propagate in the optical medium 5. However, this is not essential, and the control optical signal 2 may be received and propagate in another part of the optical transmission structure 4. The optical medium 5 may be any suitable material such as a metal, semiconductor, or dielectric. For example, the optical medium 5 may comprise silicon, for example being fabricated on a silicon on insulator (SOI) wafer. The optical medium 5 may also comprise free space (e.g. air or a vacuum) in some embodiments.
The optical transmission structure 4 may comprise any suitable structure suitable for the optical signals being used. For example, the optical transmission structure 4 may comprise a waveguide, a plasmonic waveguide, a resonator, an interferometer, and/or a photonic crystal. Thereby, the optical medium 5 may form part of the waveguide, resonator, interferometer, and/or photonic crystal. Where the optical transmission structure 4 comprises a resonator, the resonator may be, for example, a ring resonator or transmission line resonator. The optical transmission structure 4 may be formed by suitable conventional fabrication processes, such as photolithography, electron-beam lithography, reactive ion etching, and additive techniques such as deposition. The optical transmission structure 4 may be part of a larger photonic structure, in particular an on-chip photonic structure.
The control optical signal 2 and the controlled optical signal 3 enter and leave the optical transmission structure 4 before and after the modulation process via any suitable mechanism. For example, either or both of the control optical signal 2 and the controlled optical signal 3 may enter the optical transmission structure 4 via evanescent coupling to an input waveguide 7. The control optical signal and/or the controlled optical signal may also leave the optical transmission structure 4 via evanescent coupling to an output waveguide 8. This allows the optical modulation element 1 to be easily incorporated into a larger optical device comprising other optical processing elements.
The optical transmission structure 4 is configured to at least partially absorb the control optical signal 2. By being at least partially absorbed in the optical transmission structure 4, the control optical signal 2 modulates the controlled optical signal 3, as will be described in more detail below.
This is illustrated schematically with the difference between
In this example, the absorption of the control optical signal 2 changes an optical property of the optical medium 5 such that the reduction in the amplitude of the controlled optical signal 3 leaving the optical transmission structure 4 is increased relative to the reduction in the absence of the control optical signal 2. Thereby, the amplitude of the controlled optical signal 3 is modulated by the application of the control optical signal 2. Of course, this is merely exemplary, and in other examples the absorbtion of the control optical signal 2 may cause an increase in the amplitude of the controlled optical signal 3, or change a property of the controlled optical signal 3 other than its amplitude.
To absorb the control optical signal 2, the optical transmission structure 4 may comprise a plurality of absorbing elements 6. The absorbing elements 6 may be located in or on the optical medium 5. Each of the plurality of absorbing elements 6 may comprise any suitable material that can absorb an optical signal. For example, the absorbing elements 6 may comprise a metal, an intrinsically or extrinsically doped semiconductor, a non-linear material which absorbs light through two photon absorption or other nonlinear process or a dielectric having a non-zero absorption coefficient.
The absorbing elements 6 may also comprise a phase-change material, optionally germanium-antimony-tellurium. Phase-change materials can change their optical properties on changing phase. This can allow for a further avenue for dynamic control of the absorption properties of the absorbing elements 6, thereby permitting greater flexibility in how the control optical signal 2 is absorbed and modulates the controlled optical signal 3.
An absorption of the controlled optical signal 3 by the plurality of absorbing elements 6 is preferably lower than an absorption of the control optical signal 2 by the plurality of absorbing elements 6. The controlled optical signal 3 will generally be used as the output of the optical modulation element 1, and so this allows for modulation of the controlled optical signal 3 while reducing the effective loss of signal amplitude due to the modulation process. Optionally, the absorption of the controlled optical signal 3 by the plurality of absorbing elements 6 is at least 50% lower than an absorption of the control optical signal 2 by the plurality of absorbing elements 6, optionally at least 80% lower, optionally at least 95% lower, optionally at least 99% lower.
The absorption of the control optical signal 2 in the optical transmission structure 4 causes a change in an optical property of the optical medium 5. The optical property may, for example, be refractive index. This allows the control optical signal 2 to affect the propagation of the controlled optical signal 3 in the optical transmission structure 4. The changing of the optical property may be achieved by any suitable mechanism, such as one or more of heat generation, inter-band transition, lasing, carrier depletion. The absorbing of the control optical signal 2 may change the optical property via the thermo-optic effect.
The modulating of the controlled optical signal 3 further comprises changing a property or characteristic of the control optical signal 2. To achieve this, the optical modulation element 1 further comprises a controller (not pictured in
By changing a property of the control optical signal 2, the absorption of the control optical signal 2 in the optical transmission structure 4 can be varied. This in turn allows the effect on the optical property of the optical medium 5 to be varied. The property of the control optical signal 2 may comprise any suitable parameter, such as an amplitude, phase, or polarisation of the control optical signal. All of these properties can affect the absorption of the control optical signal 2, for example by the plurality of absorbing elements.
To enhance the interactions of the control optical signal 2 and the controlled optical signal 3 with the optical medium 5, and enhance the interactions of the control optical signal 2 with the absorbing elements 6, the optical transmission structure 4 may be configured such that either or both of the control optical signal 2 and the controlled optical signal 3 form a standing wave in the optical transmission structure 4.
A standing wave is formed when coherent light of nearly equal intensity is coupled into a suitable transmission structure travelling in opposite directions. This can be achieved in various ways, for example by transmitting coherent light travelling in opposite directions into the structure, or by using a structure with a reflective boundary from which light travelling in a first direction is reflected back in the opposite direction. The light in the transmission structure can also comprise a combination of a standing wave and a propagating wave.
The formation of the standing wave can be achieved by illuminating both sides of the optical transmission structure 4 (i.e. both the input waveguide 7 and the output waveguide 8) with the control optical signal 2 and/or the controlled optical signal 3. This is illustrated in
The optical transmission structure 4 and/or the transmission of the control optical signal 2 into the optical transmission structure 4 may be such that it forms a first standing wave in the optical transmission structure 4. Similarly, the controlled optical signal 3 may form a second standing wave in the optical transmission structure 4.
As well as allowing for enhanced interaction of the control optical signal 2 with the absorbing elements 6, forming a standing wave with the controlled optical signal 3 can allow the absorption of the controlled optical signal 3 in the optical medium 5 to be greatly reduced compared to a propagating wave example such as shown in
The first standing wave may be formed by splitting the control optical signal 2 into two portions, optionally equal portions, and coupling the two portions of the control optical signal 2 into the optical transmission structure 4 in opposite propagation directions. This is how the first standing wave is formed in the example of
A frequency of the control optical signal 2 may be chosen to correspond to a first resonance frequency of the optical transmission structure 4. The correspondence of the frequency of the control optical signal 2 and the first resonance frequency does not require that the frequency of the control optical signal 2 is substantially the same as the first resonance frequency. Rather, this means that the frequency of the control optical signal 2 is substantially within the resonance peak around the first resonance frequency. The frequency of the control optical signal 2 may be closer to the first resonance frequency than to any other resonance frequency of the optical transmission structure 4. The frequency of the control optical signal 2 may be within a full-width at half-maximum of the resonance peak around the first resonance frequency. This allows for lower-power modulation because of the stronger interaction of the control optical signal 2 around the first resonance frequency. It is possible to use frequencies outside of the full-width at half-maximum of the resonance peak, but this requires higher input power of the control optical signal 2 to achieve the same change in the optical property of the optical medium 5.
The second standing wave may be formed in a similar manner. Specifically, by splitting the controlled optical signal 3 into two portions, optionally equal portions, and coupling the two portions of the controlled optical signal 3 into the optical transmission structure 4 in opposite propagation directions.
A frequency of the controlled optical signal 3 may be chosen to correspond to a second resonance frequency of the optical transmission structure 4. The correspondence of the frequency of the controlled optical signal 3 and the second resonance frequency does not require that the frequency of the controlled optical signal 3 is substantially the same as the second resonance frequency. Rather, this means that the frequency of the controlled optical signal 3 is substantially within the resonance peak around the second resonance frequency. For example, the frequency of the controlled optical signal 3 may be closer to the second resonance frequency than to any other resonance frequency of the optical transmission structure 4. The frequency of the controlled optical signal 3 may be within a full-width at half-maximum of the resonance peak around the second resonance frequency.
The first resonance frequency may be different to the second resonance frequency. However, this is not essential because, as mentioned above, the control optical signal 2 and the controlled optical signal 3 may be distinguished by another characteristic such as polarisation.
The use of standing waves allows for the strength of the interaction between the optical signals and the optical transmission structure 4 to be engineered by choosing the positions of the nodes and antinodes of the standing waves in the optical transmission structure 4. By modulating the spectral parameters of the optical signals (i.e. wavelength or phase), the spatial positions of the corresponding standing wave nodes and antinodes can be shifted. This can be used to create a difference in the strength of interaction (and thereby the absorption) of the control optical signal 2 and the controlled optical signal 3 with the absorbing elements 6, for example. Where the optical transmission structure 4 comprises a plurality of absorbing elements 6, the first standing wave can be configured such that electromagnetic radiation in the first standing wave is absorbed at selected portions of the first standing wave by the plurality of absorbing elements 6.
As mentioned above, the modulating of the controlled optical signal 3 may comprise changing a property of the control optical signal 2 such as frequency, phase, amplitude, mode, polarisation, and time delay.
In this context, changing the phase of the control optical signal 2 may comprise changing a relative phase of the two portions of the control optical signal 2. This may be achieved through a phase shifter on one arm of the input waveguide, for example. By changing the relative phase of the two portions, the positions of the nodes and antinodes of the first standing wave in the optical transmission structure 4 can be shifted.
Controlling the position of the antinodes of the first and second standing waves can be used to increase the intensity contrast between the control and controlled optical signals 2, 3 in the optical transmission structure 4 at a specific position if they have different wavelengths.
In general, it is advantageous for the control optical signal 2 to interact strongly with the absorbing elements 6. It is also advantageous for the absorption of the controlled optical signal 3 by the absorbing elements to be low. To this end, the antinodes of the second standing wave may be less well aligned with the plurality of absorbing elements 6 than antinodes of the first standing wave. At least a subset of the antinodes of the first standing wave may be substantially aligned with the plurality of absorbing elements 6, and at least a majority of the antinodes of the second standing wave are aligned with regions nearer to respective midpoints between respective pairs of absorbing elements than with any absorbing element.
To achieve these alignments, the method may further comprise a step of adjusting a relative phase of the two portions of the control optical signal 2 to increase absorption of the control optical signal 2 by the plurality of absorbing elements 6. The method may further comprise adjusting a relative phase of the two portions of the controlled optical signal 3 to decrease absorption of the controlled optical signal 3 by the plurality of absorbing elements 6.
Preferably, the plurality of absorbing elements 6 are regularly spaced along a propagation direction of the optical transmission structure 4. This facilitates the alignment of the absorbing elements 6 with the nodes and antinodes of the first and second standing waves. The propagation direction need not be a straight line, but follows the propagation of the controlled optical signal 3 and the control optical signal 2 through the optical transmission structure 4. For example, in
A convenient way to increase the contrast between the first and second standing waves at particular points in the optical transmission structure 4 (e.g. at the positions of the absorbing elements) is to choose different frequencies for the control optical signal 2 and the controlled optical signal 3 that correspond to opposite harmonics of the optical transmission structure. For example, the frequencies may be chosen such that a frequency of the control optical signal 2 corresponds to an odd harmonic of the optical transmission structure 4, and a frequency of the controlled optical signal 3 corresponds to an even harmonic of the optical transmission structure 4. Alternatively, a frequency of the control optical signal 2 may correspond to an even harmonic of the optical transmission structure 4, while a frequency of the controlled optical signal 3 corresponds to an odd harmonic of the optical transmission structure 4.
The operation of the device of
In the experimental results that follow, a frequency of the control optical signal 2 corresponds to the resonance frequency of the optical transmission structure 4 labelled as λ1 in
As mentioned above, the frequency of the controlled optical signal 3 is chosen to correspond to the second resonance frequency. However, the bandwidth of the controlled optical signal 3 is much narrower than the second resonance frequency peak, and remains unchanged as the refractive index of the optical medium 5 is altered. This effectively means that the difference between the frequency of the controlled optical signal 3 and the second resonance frequency changes as a result of the application of the control optical signal 2. This in turn affects the transmission of the controlled optical signal 3 through the optical transmission structure 4. Therefore, the application of the control optical signal 2 allows the transmission of the controlled optical signal 3 to be altered and thereby modulated.
Although this example uses different frequencies of the control optical signal 2 and the controlled optical signal 3 corresponding to different resonance frequencies of the optical transmission structure 4, a similar effect could be achieved even if the frequencies of the control optical signal 2 and the controlled optical signal 3 correspond to the same resonance frequencies of the optical transmission structure 4. For example, if the polarisations of the control optical signal 2 and the controlled optical signal 3 differ and the absorption by the absorbing elements 6 is polarisation-dependent.
Similarly as for the controlled optical signal 3, the bandwidth of the control optical signal 2 is much narrower than the first resonance frequency peak. This means that, for a given amplitude of the control optical signal 2 input to the optical transmission structure 4, the difference between the frequency of the control optical signal 2 and the first resonance frequency will affect the intensity of the control optical signal at the absorbing elements 6. This means that the difference between the frequency of the control optical signal 2 and the first resonance frequency can be selected to produce a predetermined weighting between a change in a property of the control optical signal 2 and the modulation of the controlled optical signal.
In addition, the difference between the frequency of the controlled optical signal 3 and the second resonance frequency will affect how the transmission of the controlled optical signal 3 is changed by the change in the optical property of the optical medium 5 and the corresponding shift in the second resonance frequency.
This is illustrated in
The time constant for these shifts can be relatively short, and so rapid changes in the amplitude and/or frequency of the control optical signal 2 can produce correspondingly rapid shifts in the transmission of the controlled optical signal 3.
The optical modulation element 1 can thereby be used for computational operations. Information can be encoded in the control optical signal 2 and/or the controlled optical signal 3, for example in changes in the amplitude and/or frequency of the optical signals. The optical modulation element 1 allows the information to be combined. Therefore, modulating the controlled optical signal 3 may comprise performing a computational operation using the encoded information.
Using a control optical signal 2 to modulate the controlled optical signal 3 may comprise using a plurality of control optical signals 2. As long as the different control optical signals 2 are distinguishable in some characteristic, they can be used to encode multiple channels of information, all of which may be used to modulate the controlled optical signal 3 combined using different weightings
A frequency of each of the control optical signals 2 may correspond to a resonance frequency of the optical transmission structure 4. The control optical signals 2 may correspond to the same resonance frequency, e.g. the first resonance frequency, or may correspond to different resonance frequencies, e.g. different harmonics of the optical transmission structure 4.
A difference between the frequency of each of the control optical signals 2 and the corresponding resonance frequency can then be selected to produce a predetermined weighting between a change in a property of the respective control optical signal 2 and the modulation of the controlled optical signal 3. Thereby, the information encoded in the different control optical signals 2 can be combined with corresponding weightings to perform computational operations. The method may therefore further comprise performing a computational operation by combining information encoded in each of the plurality of control optical signals 2.
This is illustrated schematically in
The results shown herein were obtained using the device of
| Number | Date | Country | Kind |
|---|---|---|---|
| 23386138.4 | Dec 2023 | EP | regional |
