PHOTONIC CHIP, FIELD PROGRAMMABLE PHOTONIC ARRAY AND PHOTONIC INTEGRATED CIRCUIT

Abstract

The present invention relates to a photonic chip carried out by the combination and interconnection of equally-oriented Programmable Photonics Processing Blocks, with all their longitudinal axes in parallel, implemented over a photonic chip that is capable of implementing one or multiple, simultaneous photonics circuits with optical feedback paths and/or linear multiport transformations, by the appropriate programming of its resources and the selection of its input and output ports. The invention also relates to a parallel field-programmable photonic array (P-FPPA) comprising of, at least one programmable circuit based on equally-oriented/parallel tunable beam-splitters with independent coupling and phase-shifting configuration and peripheral high-performance building blocks.

Claims

1-25. (canceled)

26. A photonic chip, comprising: at least two programmable photonic analog blocks (PPABs), and interconnections between the at least two programmable photonic analog blocks (PPABs), being implemented via a photonic chip, characterized in that the at least two programmable photonic analog blocks (PPABs) have the same orientation, and are parallel to each other, and the interconnections between the at least two programmable photonic analog blocks (PPABs) comprise equally-oriented, programmable, tunable couplers which are interconnectable to configure optical cavities, optical loops, and both feed-forward and feed-backward interferometric structures, being the programmable tunable couplers with additional phase configuration their primitive element.

27. The photonic chip of claim 26, wherein each one of the at least two programmable photonic analog blocks (PPABs) comprises a longitudinal axis, wherein the longitudinal axes of the at least two programmable photonic analog blocks (PPABs) are parallel.

28. The photonic chip of claim 26, wherein the programmable photonic analog block (PPAB) comprises of at least two photonic waveguide elements.

29. The photonic chip of claim 28, wherein the photonic waveguide element is configured to allow propagation in both directions.

30. The photonic chip of claim 26, wherein the programmable photonic analogue block (PPAB) comprises at least two input ports and at least two output ports and is described by at least a unitary 2×2 rotation matrix of the special unitary group with different phase relationships among components of the matrix.

31. The photonic chip of claim 26, wherein the PPABs are configured to set an arbitrary splitting ratio K (0<=K<=1) as well as set a common phase shift Δ.sub.PPAB between at least one input port and at least one output ports.

32. The photonic chip of claim 26, wherein at least two equally-oriented programmable photonic analog blocks (PPABs) are configured by a series of photonic waveguide elements developed on a photonic chip.

33. A photonic integrated circuit comprising the photonic chip of claim 26, wherein the photonic chip is interconnected to high-performance building blocks configured to perform basic optical processing tasks such as: optical amplification, optical sources, electro-optical modulation, opto-electronic photodetection, optical absorption, variable optical attenuators, non-linear processing elements and delay line arrays, optical wavelength, spatial, modal and polarization (de)multiplexing, optical routing.

34. The photonic integrated circuit of claim 33, further comprising high-performance building blocks configured to perform spatial division wavelength multiplexing/demultiplexing of light, either in a cyclic or non-cyclic way.

35. The photonic integrated circuit of claim 33, further comprising equally-oriented primitive components implemented by a non-resonant Mach-Zehnder Interferometer.

36. The photonic integrated circuit of claim 33, further comprising equally-oriented primitive components implemented by a non-resonant Mach-Zehnder Interferometer with two arms of equal length.

37. The photonic integrated circuit of claim 33, further comprising equally-oriented primitive components implemented by a resonant interferometer.

38. The photonic integrated circuit of claim 33, further comprising equally-oriented primitive components implemented by a dual-drive directional coupler.

39. The photonic integrated circuit of claim 33, further comprising equally-oriented primitive components with an arbitrary number of ports.

40. The photonic integrated circuit of claim 33, further comprising equally-oriented primitive components implemented where the phase and amplitude tuners are based on: Nano Electro Mechanical Systems (NEMS), and Micro-Electro Mechanical Systems (MEMS), thermo-optic effects, electro-optic effects, opto-mechanics, electro-absorption, electro-capacitive effects, electro-inductive effects, memristor elements or non-volatile phase actuators.

41. The photonic integrated circuit of claim 26, wherein the equally-oriented waveguide mesh arrangements of PPABs are distributed in a uniform topology.

42. The photonic integrated circuit of claim 26, wherein the equally-oriented waveguide mesh arrangements of PPABs are distributed in a non-uniform topology.

43. The photonic integrated circuit of claim 33, wherein the equally-oriented waveguide mesh arrangements of PPABs interconnections comprise nodes wherein the equally-oriented waveguide mesh arrangements of PPABs interconnections maintain the same length between all nodes.

44. The photonic integrated circuit of claim 33, wherein the equally-oriented waveguide mesh arrangements of PPABs interconnections comprise nodes wherein the equally-oriented waveguide mesh arrangements of PPABs interconnections maintain arbitrary lengths between all nodes.

45. The photonic integrated circuit of claim 33, wherein at least two equally-oriented waveguide mesh arrangements are interconnected between them enabling a multi-stage or multicore platform.

46. The photonic integrated circuit of claim 33, wherein the waveguide mesh arrangement is connected to an electrical subsystem driving actuators or to on-chip actuators/receivers, to an electrical subsystem monitoring optoelectronic read-outs and to a microprocessor that run optimization and configuration programs.

Description

DESCRIPTION OF THE DRAWINGS

[0025] In order to complement the description being made and with the object of helping to better understand the characteristics of the invention, in accordance with a preferred practical embodiment thereof, said description is accompanied, as an integral part thereof, by a set of figures where, in an illustrative and non-limiting manner, the following has been represented:

[0026] FIG. 1 shows some non-limitative examples of a schematic diagram example of the proposed photonic chip of the invention, wherein the illustration shows a detail of the internal signal coupling layout interconnection of Equally-oriented Programmable Photonic Analog Blocks or Tunable Basic Units (TBUs) and following a uniform pattern. (Up: Conventional hexagonal uniform waveguide mesh distribution according to the state of the art, Down: proposed equally-oriented layout of the present invention.

[0027] FIG. 2 shows some non-limitative examples of a schematic diagram example of the proposed photonic chip of the invention, wherein the illustration shows a detail of the internal signal coupling layout interconnection of Equally-oriented Programmable Photonic Analog Blocks and following a uniform pattern. (Up: Conventional square uniform waveguide mesh distribution according to the state of the art, Down: proposed equally-oriented layout of the present invention.

[0028] FIG. 3 shows some non-limitative examples of a schematic diagram example of the proposed photonic chip of the invention, wherein the illustration shows a detail of the internal signal coupling layout interconnection of Equally-oriented Programmable Photonic Analog Blocks and following a uniform pattern. (Up: Conventional triangular uniform waveguide mesh distribution according to the state of the art, Down: proposed equally-oriented layout of the present invention.

[0029] FIG. 4 shows some non-limitative examples of a schematic diagram example of the proposed photonic chip of the invention, wherein the illustration shows a detail of the internal signal coupling layout interconnection of Equally-oriented Programmable Photonic Analog Blocks and following a non-uniform pattern.

[0030] FIG. 5 shows on the left-hand, the main steps involved in the design/configuration flow of a photonic chip of the present invention and on the right-hand, the soft and hard tiers of the photonic chip and the expanded layout including peripheral high-performance blocks.

[0031] FIG. 6 shows a simultaneous implementation of a Ring cavity, a balanced Mach-Zehnder Interferometer and a 3×3 multiple port interferometer using a design of the photonic chip of the present invention where all the processing units are equally-oriented.

[0032] FIG. 7 shows an FPPA implementation with high-performance building blocks providing wavelength multiplexing and demultiplexing tasks. The arrangement of basic processing units can be coupled to this block enabling the processing in different channels and different wavelengths.

PREFERRED EMBODIMENT OF THE INVENTION

[0033] In a preferred embodiment of the object of the invention, a device is provided as shown in FIG. 1 where a field-programmable photonic array (P-FPPA) is seen which comprises at least one, but preferably a large number of equally-oriented programmable photonic analogue blocks (PPAB) implemented by way of a series of photonic waveguide elements developed on a photonic chip substrate. These blocks have programmable characteristics and can propagate the light in both directions. Take into account that the design in FIG. 1 does not assume any particular interconnection geometry and that the resulting design shown there is only for the purposes of illustration. Although various configurations for the PPBA may be considered, here it is illustrated the design with a very basic 4-port PPBA units. The scheme of said equally-oriented PPAB and their interconnections are shown in the square of FIG. 1 for a particular axis orientation and without internal coupling routes. In general, different options will be considered, wherein all PPAB blocks will remain in the same orientation. FIG. 1-4 shows some of the possible interconnection options. The function of the PPAB is to provide independent power coupling relations and adjustable phase adjustments, as explained below.

[0034] The PPAB is a 2×2 photonic component capable of independently configuring a common tunable phase shift Δ.sub.PPAB and tunable optical power splitting ratio K=sin □ (0<=K<=1) between its optical waveguide input fields and its output optical waveguide output fields. [0035] FIG. 5 shows some examples of the simple programming of the RPI+PPAB which leads to very basic operations required in the processing of photonic signals. Many more are possible.

[0036] By means of suitable programming and the concatenation of successive equally-oriented processing blocks, the P-FPPA can implement complex autonomous and/or parallel photonic circuits and signal processing transformations by discretizing conventional optical processing circuits into RPI and PPAB units.

[0037] In particular, this concept is illustrated by means of three generic designs, which are represented in FIG. 5, respectively.

[0038] The parallel field-programmable photonic array (P-FPPA) according to the invention is an array of equally-oriented uncommitted elements that can be interconnected according to the user's specifications configured for a wide variety of applications. An P-FPPA combines the programmability of the most basic reconfigurable photonic integrated circuits in a scalable interconnection structure, allowing programmable circuits with much higher processing density. Thus, processing complexity comes from the interconnectivity. In addition, it solves the problems related to previous waveguide meshes where the interconnection topology was constrained by the resulting TBU orientations. Our proposed invention solves them several problems: first, the footprint is reduced considerably, reducing the limit of the integration density and thus the versatility of the circuits. Secondly, some photonic components are sensitive to orientation due to their intrinsic material and waveguide geometry properties. For example, some phase actuators require a certain component orientation, in order to maintain a reasonable tuning efficiency. With current approaches, only phase-change effects that support arbitrary component orientation can be employed. Moreover, some TBUs employ 3-dB couplers (directional couplers or multimode interferometers), which are also sensitive to orientation, limiting the overall circuit performance. With the proposed invention, both the processing performance and the circuit reproducibility and reliability are improved. It is also an object of the present invention a photonic integrated circuit comprising of programmable tunable couplers for the interconnection of at least two equally-oriented programmable photonic elements as described in the previous paragraph that uses the programmable tunable couplers as their primitive element to configure interferometric structures.

[0039] Preferably, the equally-oriented programmable tunable couplers are interconnectable in such a way that they allow the configuration of optical cavities, optical loops, and both feed-forward and feed-backward interferometric structures using the tunable couplers with additional phase configuration as their primitive element.

[0040] Also preferably, the photonic integrated circuit is interconnected to high-performance building blocks configured to perform basic optical processing tasks such as: optical amplification, optical sources, electro-optical modulation, opto-electronic photodetection, optical absorption, variable optical attenuators, non-linear processing elements and delay line arrays, optical wavelength, spatial, modal and polarization (de)multiplexing, optical routing. In this case, in the photonic integrated circuit, the waveguide mesh arrangement is connected to an electrical subsystem driving the actuators or to on-chip actuators/receivers, to an electrical subsystem monitoring the optoelectronic read-outs and to a microprocessor that run the optimization and configuration programs.

[0041] The photonic integrated circuit may further comprise equally-oriented primitive components implemented by a non-resonant Mach-Zehnder Interferometer, or equally-oriented primitive components implemented by a non-resonant Mach-Zehnder Interferometer with two arms of equal length, or equally-oriented primitive components implemented by a resonant interferometer, or equally-oriented primitive components implemented by a dual-drive directional coupler, or equally-oriented primitive components with an arbitrary number of ports, or equally-oriented primitive components implemented where the phase and amplitude tuners are based on: Nano Electro Mechanical Systems (NEMS), and Micro-Electro Mechanical Systems (MEMS), thermo-optic effects, electro-optic effects, opto-mechanics, electro-absorption, electro-capacitive effects, electro-inductive effects, memristor elements or non-volatile phase actuators.

[0042] In the integrated circuit, the equally-oriented waveguide mesh arrangements of PPABs are distributed in a non-uniform topology, or the equally-oriented waveguide mesh arrangements of PPABs interconnections maintain the same length between all nodes, or the equally-oriented waveguide mesh arrangements of PPABs interconnections maintain arbitrary lengths between all nodes.

[0043] The left part of FIG. 6 shows the main steps of the design flow process, which is now described. The starting point for the design flow is the initial application entry to be implemented. The specifications are then processed by an optimization procedure to enhance the area and performance of the final circuit. Then, specifications are transformed into a compatible circuit of FPPA processing blocks (technology mapping), optimizing attributes such as delay, performance or number of blocks.

[0044] Technology mapping phase transforms the optimized network into a circuit that consists of a restricted set of circuit elements (P-FPPA processing blocks). This is done selecting parts of the network that can each be implemented by one of the available basic circuit elements, and then specifying how these elements will be interconnected. This will determine the total number of processing blocks required for the targeted implementation.

[0045] Then, a decision about the placement follows, assigning each processing block to a specific location in the P-FPPA. At that moment, the global routing is done choosing the processing units that will operate as access lightpaths. In contrast to FPGA, this structure does not physically differentiate between processing blocks and Interconnection resources. Formerly, the processing block configurations are chosen correspondingly and performance calculation and design verification are carried out. It can be done either physically by feeding all the necessary configuration data to the programming units to configure the final chip or by employing accurate models of the P-FPPA. At each step it is possible to run an optimization process that might decide to re-configure any of the previous steps. Preferably, the programmable photonic analogue block (PPAB) comprises at least two input ports and at least two output ports and is described by at least a unitary 2×2 rotation matrix of the special unitary group with different phase relationships among its four components.

[0046] From the aforementioned description it can be appreciated that the P-FPPA involves not only the physical hardware of the photonic and control electronic tier but also it is composed of a software layer (see upper right part of FIG. 5).

[0047] The steps contained in the generic design flow can be done automatically by the software layer, by the user, or a mixture of the two, depending on the autonomy and the capabilities of the P-FPPA. In addition, a failure in any of the steps will require an iterative process till the specifications are accomplished successfully. Additional parallel optimization process (mainly self-winding), enable robust operation, self-healing attributes and additional processing power to the physical device.

[0048] Similarly to modern FPGA families, FPPA can include peripheral and internal high-performance blocks (HPB) to expand its capabilities to include higher level functionality fixed into the chip. This is shown schematically in the lower right part of FIG. 5. Having these common functions embedded into the chip reduces the area required and gives those functions increased performance compared to building them from primitives. Moreover, some of them are impossible to be obtained by a discretized version of basic processing blocks. Examples of these include high-dispersive elements, spiral waveguide delay lines, generic modulation and photo detection subsystems, optical amplifiers and source subsystems and high-performance filtering structures to cite a few.

[0049] A special case of HPB is an interconnection of the arrangement of basic processing units with input/output wavelength multiplexing/demultiplexing devices, either of which can be spectrally cyclic, or non-cyclic. As illustrated in FIG. 7, it introduces another degree of flexibility, allowing the processing of multiple wavelengths. It shows that the system enables the processing on different spatial channels/modes as well as different frequency channels/modes.

[0050] In addition, the P-FPPA can incorporate multiple and independent processing cores that can be interconnected among them and to high-performance building blocks to increase the processing performance. This processing cores of waveguide meshes can be integrated in the same substrate or can be integrated in different dies.

Operation Examples

[0051] FIG. 6 provide some examples where FPPA of different types are programmed to emulate and implement simultaneously different photonic circuits. In each case the figure includes the FPPA layout with colored processing units according to the code defined earlier and the layouts of the implemented circuits.

[0052] Physical Implementation

[0053] The physical implementation of the P-FPPA device calls for an integrated optics approach either based on silicon photonics platform or a hybrid/heterogeneous III-V and Silicon photonics platforms.

[0054] As for the PPAB elements, the currently available photonics technology options are based on any phase tuning effect like: MEMS, thermo-optic effects, electro-optic effects, opto-mechanics, electro-capacitive effects or non-volatile phase actuators. This phase shifter actuators are integrated in any interferometric structure with more than two ports. Finally, as mentioned before, more complex FPPFA layouts can be designed by setting different interconnections schemes among the equally-oriented processing blocks some examples are shown in the lower part of FIGS. 1-4.