SWITCHES AND INTEGRATED PHOTONIC INTERCONNECTION NETWORK IN AN OPTOELECTRONIC CHIP

专利摘要:
A photonic interconnection switch integrated in an optoelectronic chip, comprising first and second optical waveguide linear guides (2, 3) intersecting at a first intersection (4); first two forward photonic ring resonators (9, 10) respectively coupled to the first and second optical waveguides (2), two second photonic forward annular resonators (13, 14) respectively coupled to the first and second optical waveguides a third linear optical waveguide (17) coupled to the first and second annular resonators, a fourth linear optical waveguide (20) coupled to the first and second annular resonators. Basic switch, complex switch and photonic interconnection network integrated in an optoelectronic chip, including at least two elementary switches.
公开号:FR3071932A1
申请号:FR1759184
申请日:2017-10-02
公开日:2019-04-05
发明作者:Nicolas MICHIT；Patrick Le Maitre
申请人:STMicroelectronics Crolles 2 SAS；
IPC主号:

专利说明:

Switches and photonic interconnection network integrated in an optoelectronic chip
According to embodiments, the present invention relates to the field of photonic interconnection switches integrated in optoelectronic chips and photonic interconnection networks integrated in optoelectronic chips and including such switches.
It is known to produce linear optical waveguides, integrated in optoelectronic chips and capable of confining and guiding light.
It is also known to make photonic interconnection switches integrated in optoelectronic chips, making it possible to transfer photons from one optical waveguide to another optical waveguide via an annular redirection resonator , controllable by an electrical signal.
Generally, the resonator comprises an integrated ring and an integrated electronic component adjacent to this ring and controllable by an electrical signal, the integrated ring having portions adjacent to the optical waveguides so as to form zones of optical coupling between the ring and optical waveguides.
In the absence of an electrical signal, the integrated ring is in a state called "non-resonant" such as a light wave, brought to a coupling zone by an optical waveguide, crosses this coupling zone and continues its path in this optical waveguide.
On the other hand, in the presence of an electrical signal, the integrated electronic component modifies the state of the integrated ring which is then placed in a so-called "resonant" state such as a light wave which reaches a coupling zone by l one of the optical waveguides is transferred to the integrated ring and then transferred to the other optical waveguide via the other coupling zone, the light wave continuing its path in the other waveguide optics in an opposite direction.
Commonly, the structures described above are produced on silicon and silicon on insulator (SOI) substrates.
Furthermore, the document IEEE TRANSACTIONS ON COMPUTERS VOL. 65 NO 6 JUNE 2016 offers complex photonic interconnection networks integrated in optoelectronic chips, which include a plurality of optical waveguides and a plurality of switches, as described above, and which include intersections between the guides optical waves, for the selective transfer of data and data packets between sources and recipients, by selectively controlling the resonators.
The photon interconnection networks described above are limited by the losses and crosstalk which degrade the signals transmitted when the optical waves pass through intersections or resonators. They should therefore be kept to a minimum.
A basic photonic interconnection switch integrated in an optoelectronic chip is proposed, which includes:
first and second linear optical waveguides, which intersect forming a first intersection and which have first and second external optical coupling ends, respectively, so that the first and second linear waveguides have first branches between said intersection and said first ends and have second branches between said intersection and said second ends;
two first annular photonic redirection resonators, respectively comprising a single ring, respectively coupled to the first and second optical waveguides in local areas of optical coupling of the first branches, the latter passing between these first resonators, two second photonic annular resonators of redirection, respectively comprising a single ring, respectively coupled to the first and second optical waveguides in local optical coupling zones, the latter passing between these second resonators, a third linear optical waveguide coupled to the first and second resonators annulars, located on the same side with respect to the first branch of the second optical waveguide and the second branch of the first optical waveguide, into local areas of optical coupling, and a fourth linear optical waveguide coupled at the first and second reso annular nators located on the same side with respect to the first branch of the first optical waveguide and the second branch of the second optical waveguide, in local areas of optical coupling;
the third and fourth optical waveguides having first ends on the side of the first annular resonators and second ends on the side of the second annular resonators.
The third optical waveguide may not cross any of the other optical waveguides and the fourth optical waveguide may not cross any of the other optical waveguides.
The first and third optical waveguides can cross and the second and fourth optical waveguides can cross, respectively between their second ends and the second annular resonators, forming second and third intersections.
The elementary switch may include an axis of symmetry on which is located said intersection between said first and second waveguides and on either side of which are located said first and second annular resonators, respectively.
The first ends of the third and fourth optical waveguides and the second ends of the first and second optical waveguides may form light wave inputs, respectively optical wave outputs, and the first ends of the first and second waveguides. optical waveguides and the second ends of the third and fourth optical waveguides may form light wave outputs, respectively optical wave inputs.
There is also proposed a basic photonic interconnection switch integrated in an optoelectronic chip, which comprises two elementary switches, in which the waveguides of one are selectively connected to the waveguides of the other.
The resonators of said elementary switches may be able to resonate at the same frequency.
A complex photonic interconnection switch integrated in an optoelectronic chip is also proposed, which comprises an even number of elementary switches, in which the waveguides of the adjacent elementary switches are selectively connected in series and in which the elementary switches are subject in pairs at different frequencies.
A complex photonic interconnection switch integrated in an optoelectronic chip is also proposed, which comprises a plurality of basic switches, in which the waveguides of the adjacent elementary switches are selectively connected in series and in which the basic switches are subject to different frequencies.
There is also proposed a photonic interconnection network integrated in an optoelectronic chip, which includes optoelectronic devices respectively having input ports and optical wave output ports, which are selectively connected via a basic switch or via a complex switch.
Integrated photonic interconnection switches will now be described by way of example embodiments, illustrated by the drawing in which:
FIG. 1 represents a plan view of an elementary integrated photonic interconnection switch;
FIG. 2 represents a plan view of another elementary integrated photonic interconnection switch;
FIG. 3 represents modes of circulation of optical waves in the elementary switch of FIG. 1; Figure 4 shows a plan view of an integrated photonic interconnect switch;
FIG. 5 represents a view of a photonic interconnection network;
FIGS. 6A to 6D represent modes of circulation of optical waves in the basic switch of FIG. 4;
Figure 7 shows a plan view of another integrated photonic interconnect base switch; Figure 8 shows a plan view of another integrated photonic interconnect base switch; Figure 9 shows a plan view of another integrated photonic interconnect base switch; FIG. 10 represents a plan view of another integrated photonic interconnection base switch; FIG. 11 represents a plan view of a complex integrated photonic interconnection switch; and Figure 12 shows a plan view of another complex integrated photonic interconnect switch;
In FIG. 1 is illustrated an elementary photonic interconnection switch 1, integrated in an optoelectronic chip, in which the optical guides which will be described are in the same general plane.
The elementary switch 1 comprises a first and a second linear optical waveguide 2 and 3, which intersect forming an intersection 4 and which respectively have first and second ends 2a, 2b and 3a, 3b of external optical coupling, of so that the first and second linear waveguides 2 and 3 have first branches 5 and 6 between the intersection 4 and the first ends 2a and 3a and have second branches 7 and 8 between the intersection 4 and the second ends 2b and 3b.
The elementary switch 1 comprises two first annular photonic redirection resonators 9 and 10 coupled respectively to the first branches 5 and 6 of the first and second optical waveguides 2 and 3 in local areas of optical coupling 11 and 12 of the first branches 5 and 6, these branches 5 and 6 passing between these first resonators 9 and 10.
The elementary switch 1 comprises two second annular photonic redirection resonators 13 and 14 respectively coupled to the second branches 7 and 8 of the first and second optical waveguides 2 and 3 in local optical coupling zones 15 and 16 of the second branches 7 and 8, these branches 7 and 8 passing between these second resonators 13 and 14.
The elementary switch 1 comprises a third linear optical waveguide 17 coupled to the first and second annular resonators 10 and 13, located on the same side with respect to the first branch 6 of the second optical waveguide 3 and the second branch 7 of the first optical waveguide 2, in local optical coupling zones 18 and 21.
The elementary switch 1 comprises a fourth linear optical waveguide 20 coupled to the first and second annular resonators 9 and 14 located on the same side with respect to the first branch 5 of the first optical waveguide 2 and the second branch 8 of the second optical waveguide 3, in local optical coupling zones 19 and 22.
The third and fourth optical waveguides 17 and 20 have first ends 17a and 20a on the side of the first annular resonators 9 and 10 and second ends 17b and 20b on the side of the second annular resonators 13 and 14.
The annular resonators 9, 10, 13 and 14 respectively comprise single rings 23, 24, 25 and 26 forming optical waveguides. These rings 23, 24, 25 and 26 are adjacent to the aforementioned corresponding waveguides with which they constitute the aforementioned corresponding local optical coupling zones.
The rings 23, 24, 25 and 26 are respectively associated with integrated components (not shown), which, when subjected to electrical signals, are capable of modifying the state of the annular resonators 9, 10, 13 and 14 .
According to a particular arrangement illustrated in FIG. 1, the elementary switch 1 advantageously has a longitudinal geometric axis of symmetry 27 (from left to right in FIG. 1) passing through the intersection 4.
The rings 9 and 10 and the rings 13 and 14 are respectively arranged symmetrically with respect to the longitudinal axis 27.
The centers of the rings 9 and 14 and the centers of the rings 10 and 13 are arranged on lines 28 and 29 parallel to the longitudinal axis 17 and symmetrical with respect to the longitudinal axis 27.
The optical waveguides 2 and 3 are symmetrical with respect to the longitudinal axis 17.
The optical waveguides 17 and 20 are symmetrical with respect to the longitudinal axis 17.
The optical waveguides 2 and 3 comprise rectilinear portions 30 and 31 which intersect by forming the intersection 4 and which are oriented at 45 ° relative to the axis of symmetry 27 by forming a cross.
The optical waveguide 2 comprises a longitudinal portion 32 which connects one end of its portion 30 and its external coupling end 2a and with which the ring 9 is coupled in one place and comprises a longitudinal portion 33 which connects the other end of its portion 30 and its external coupling end 2b and with which the ring 13 is coupled in one place.
The optical waveguide 3 comprises a longitudinal portion 34 which connects one end of its portion 31 and its external coupling end 3a and with which the ring 10 is coupled in one place and includes a longitudinal portion 35 which connects the other end of its portion 31 and its external coupling end 3b and with which the ring 14 is coupled in one place.
The optical waveguides 17 and 20 extend longitudinally and are symmetrical with respect to the longitudinal axis 17.
The first ends 2a, 3a, 17a and 20a of the optical waveguides 2, 3, 17 and 20 are oriented in a direction of the longitudinal axis 17 (to the left in FIG. 1) and the second ends 2b, 3b , 17b and 20b of the optical waveguides 2, 3, 17 and 20 are oriented in the other direction of the longitudinal axis 17 (to the right in Figure 1). The first ends 17a and 20a are further from the longitudinal axis 17 than the first ends 2a and 3a. The second ends 17b and 20b are further from the longitudinal axis 17 than the second ends 2b and 3b.
According to another configuration illustrated in FIG. 2, an elementary switch 101 differs from elementary switch 1 in that the parts of the first and third optical waveguides 2 and 17, located between the optical coupling zones and 21 and the second ends 2b and 17b, intersect forming an intersection 36 and that the parts of the second and fourth optical waveguides 3 and 20, located between the optical coupling zones and 22 and the second ends 3b and 20b, intersect at forming an intersection 37.
In the particular arrangement described above, the optical waveguides 2 and 17 of this other configuration are modified and have intermediate rectilinear portions 38 and 39 at 45 ° relative to the longitudinal axis which intersect forming the intersection 36 and the optical waveguides 3 and 20 are modified and have intermediate portions 40 and 41 at 45 ° relative to the longitudinal axis which intersect forming the intersection 37. The intersections 36 and 37 are symmetrical with respect to to the longitudinal axis 27 and are respectively on the longitudinal lines 29 and 28.
As before, the first ends 17a and 20a are further from the longitudinal axis 17 than the first ends 2a and 3a, while, unlike previously, the second ends 2b and 3b are further from the longitudinal axis 17 than the second ends 17b and 20b.
The elementary switch 1 and the elementary switch 101 operate in the following manner.
Generally, in the absence of an electrical activation signal from the four annular resonators 9, 10, 13 and 14, the four rings 23, 24, 26 and 26 are in an "OFF" state (nonresonant state). A light wave entering from one end of the four optical waveguides 2, 3, 17 and 20 exits from its other end.
Also generally, in the presence of an electrical signal activating said integrated electronic components associated with one of the annular resonators 9, 10, 13 and 14, the corresponding ring is in an "ON" state (resonant state) . The light wave entering at one end of one of the optical waveguides adjacent to this ring is redirected to the other optical waveguide adjacent to this ring, via this ring.
It is nevertheless accepted that in each optical waveguide, a wave can only flow in one direction and that, therefore, one end of an optical waveguide constitutes only either an input for receiving a light wave or an emission output of a light wave.
Also, the following configuration can be accepted, in order to form a basic switch with four inputs and four outputs (4x4).
The ends 2b, 3b, 17a and 20a of the optical waveguides 2, 3, 17 and 20 constitute light wave inputs.
The ends 2a, 3a, 17b and 20b of the optical waveguides 2, 3, 17 and 20 constitute light wave outputs.
The above inputs and outputs are symbolized in the drawing by corresponding incoming and outgoing arrows.
When none of the ring resonators 9, 10, 13 and 14 is activated, light waves can be routed directly from the input end to the output end of the waveguides 2, 3, 17 and 20.
In an operating case illustrated in FIG. 3 relative to the switch 1, if the annular resonator 10 is activated, a light wave entering through the end 17a of the optical waveguide 17 is diverted by this annular resonator 10 towards the guide d optical waves 3 and is routed to the output end 3a of this optical waveguide 3.
A light wave can be routed directly from the input end 2b of the optical waveguide 2 to the output end 2a of this optical waveguide 2.
On the other hand, if a light wave entered via the input 3b of the optical waveguide 3, it could not be routed towards the output 3a of this optical waveguide 3 because this output is already occupied by the deflected wave coming from of the optical waveguide 17.
According to an alternative, a light wave can be routed directly from the input end 20a of the optical waveguide 20 to the output end 20b of this optical waveguide 20. On the other hand, if a light wave entered by the input 3b of the optical waveguide 3, it could not be diverted by the annular resonator 14 to the optical waveguide 20 already thus occupied.
According to another alternative, a light wave entering through the input 3b of the optical waveguide 3 can be diverted by the annular resonator 14 towards the optical waveguide 20 to be directed towards the output 20b of the optical waveguide 20. On the other hand, if a light wave entered through the inlet 20a of the optical waveguide 20, it could not be routed to the end 20b of the optical waveguide 20 already so occupied. As a result, the elementary switch 1 is said to be "blocking".
Other operating cases can be developed by equivalence to the case described above by activating the annular resonators 9, 13 and 14 respectively.
The above cases apply equally to the basic switch 101.
In the case where the annular resonators 9, 10, 13 and 14 are capable of resonating at a frequency λ, the elementary switches 1 and 101 are capable of directing or redirecting light waves established at this frequency.
Having defined elementary switches 1 and 101 above, we will now describe basic switches with four inputs and four outputs (4x4), including pairs or pairs of elementary switches connected "in series".
It is specified that the expression “in series” means that the waveguides of an elementary switch are selectively connected to the waveguides of the other elementary switch according to specific modes of coupling. It is specified that the word "selectively" means that any of the waveguides of an elementary switch can be connected to any of the waveguides of the other elementary switch.
As illustrated in FIG. 4, a basic switch 201 comprises first and second elementary switches 1 connected “in series”, in a coupling mode such that the second ends 2b, 3b, 17b and 20b of the first elementary switch (on the left in FIG. 4) are connected to the first ends 2a, 3a, 17a and 20a of the second elementary switch (on the right in FIG. 4).
Thus, the first optical waveguides 2, the second optical waveguides 3, the third optical waveguides 17 and the fourth optical waveguides 20 of the two elementary switches 1 are respectively connected "in series".
In FIG. 5 is illustrated a photonic interconnection network integrated in an optoelectronic chip, which includes optoelectronic devices Dl, D2, D3 and D4 having respectively input ports Pie, P2e, P3e and P4e and output ports Pis , P2s, P3s and P4s of optical waves, which are selectively linked via the basic switch 201.
For example, as illustrated in FIG. 4, on the one hand (on the left in FIG. 4) of the first ends 2a, 3a, 17a and 20a, external, waveguides of the first elementary switch 1 are respectively connected to the ports P3e, P4e, Pis and P2s and on the other hand (on the right in FIG. 4) the second ends 2b, 3b, 17b and 20b, external, waveguides of the second elementary switch 1 are respectively connected to the ports P3s, P4s, P2e and Pie.
It is considered as an operating condition that each of the devices D1 to D4 can, at a given time, receive light waves coming from only one device other than itself.
It is also considered as an operating condition that a light wave entering one of the elementary switches 1 can only be derived to exit this elementary switch 1.
Circulation modes or optical paths described below by way of examples with reference to FIGS. 6A to 6D, can then be produced by selectively activating the resonators 9, 10, 13 and 14 of the elementary switches 1 of the base switch 201.
As illustrated in FIG. 6A, the resonators 9, 10, 13 and 14 of the elementary switches 1 are not activated.
Then, light waves from the output ports Pis, P2s are routed directly to the input ports P2e and Pie via the third and fourth waveguides 17 and 20, respectively "in series", elementary switches 1 and light waves from the output ports P3s and P4s are routed directly to the input ports P4e and P3e via the first and second waveguides 2 and 3, respectively "in series", of the elementary switches 1.
As illustrated in FIG. 6B, the resonators 9 and 10 of the first elementary switch 1 and of the second elementary switch 1 are activated.
Then, a light wave coming from the port Pis is diverted towards the port P4e via the resonator 10 of the first switch 1, a light wave coming from the port P2s is diverted towards the port P3e via the resonator 9 of the first elementary switch 1, a light wave from the port P3s is derived to the port Pie via the resonator 9 of the second elementary switch 1, a light wave from the port P4s is derived to the port P2e via the resonator 10 of the second elementary switch 1.
As illustrated in FIG. 6C, the resonator 14 of the first elementary switch 1 and the resonator 9 of the second elementary switch 1 are activated.
Then, a light wave from the Pis port is directly routed to the P2e port, a light wave from the P4s port is directly routed to the P3e port, a light wave from the P2s port is diverted to the P4e port via the resonator 14 of the first elementary switch 1, a light wave coming from the port P3s is diverted towards the port Pie via the resonator 9 of the second elementary switch 1.
As illustrated in FIG. 6D, the resonator 10 of the first elementary switch 1 and the resonator 13 of the second elementary switch 1 are activated.
Then, a light wave from the P2s port is directly routed to the Pie port, a light wave from the P4s port is directly routed to the P3e port, a light wave from the Pis port is diverted to the P4e port via the resonator 10 of the first elementary switch 1, a light wave coming from the port P3s is diverted towards the port P2e via the resonator 13 of the second elementary switch 1.
Other modes of circulation or optical paths can be envisaged.
It follows from the above that, the aforementioned conditions being respected, the devices DI to D4 can, selectively, exchange optical waves via the base switch 201, without blocking because any device 101 to 104 can freely transmit information to any other device by simply respecting the fact that a device can only receive (respectively transmit) signals from (respectively towards) one other device at a time. Thus, the basic switch 201 is said to be “non-blocking”.
In the case where the annular resonators of the elementary switches 1 are able to resonate at a frequency λ, the base switch 201 is able to direct or redirect light waves established at this frequency.
As illustrated in FIG. 7, a basic switch 301 comprises two elementary switches 101 connected “in series”, head to tail, in a coupling mode such that the second ends 2b, 3b, 17b and 20b of one of the switches elementary 101 are connected to the second ends 2b, 3b, 17b and 20b of the other elementary switch 101.
Thus, the first optical waveguides 2, the second optical waveguides 3, the third optical waveguides 17 and the fourth optical waveguides 20 of the two elementary switches 101 are respectively connected "in series", by constituting a basic switch with four inputs and four outputs (4x4).
In fact, the basic switch 301 differs from the basic switch 201 only by the existence of intersections 36 and 37.
Circulation modes or optical paths described above by way of examples with reference to FIGS. 6A to 6D are directly applicable to the basic switch 301.
In the case where the annular resonators of the elementary switches 101 are able to resonate at a frequency λ, the basic switch 301 is able to direct or redirect light waves established at this frequency.
As illustrated in FIG. 8, a basic switch 401 comprises two elementary switches 101 connected “in series”, in a coupling mode such that the second ends 2b, 3b, 17b and 20b of the optical waveguides 2, 3, 17 and 20 of one of the elementary switches are connected to the first ends 2b, 3b, 17b and 20b of the optical waveguides 2, 3, 17 20 of the other elementary switch.
Thus, the first, second, third and fourth optical waveguides 2, 3, 17 and 20 of one of the elementary switches 101 are respectively connected to the third, fourth, second and first optical waveguides 17, 20, 3 and 2 of the other elementary switch 101.
For example, on the one hand (on the left in FIG. 8) of the first ends 2a, 3a, 17a and 20a, external, waveguides of the first elementary switch 101 are respectively connected to the ports P3e, P4e, Pis and P2s and on the other hand (on the right in FIG. 8) the second ends 2b, 3b, 17b and 20b, exterior, of the waveguides of the second elementary switch 101 are respectively connected to the ports Pie, P2e, P4s and P3s.
Operating conditions equivalent to those mentioned above being observed, circulation modes or optical paths can be achieved by selectively activating the resonators 9, 10, 13 and 14 of the two elementary switches 101 of the base switch 401, so that the devices DI to D4 can selectively exchange light waves via the basic switch 401, without blocking. The basic switch 401 is also "non-blocking".
In the case where the annular resonators of the elementary switches 101 are able to resonate at a frequency λ, the basic switch 401 is able to direct or redirect light waves established at this frequency.
As illustrated in FIG. 9, a basic switch 501 comprises two elementary switches, namely an elementary switch 1 (on the left in FIG. 9) and an elementary switch 101 (on the right in FIG. 9), connected "in series" , in a coupling mode such that the second ends 2b, 3b, 17b and 20b of the optical waveguides 2, 3, 17 and 20 of the elementary switch 1 are connected respectively to the first ends 3a, 2a, 17a and 20a of the guides of optical waves 3, 2, 17 and 20 of the elementary switch
101.
Thus, the first, second, third and fourth optical waveguides 2, 3, 17 and 20 of the elementary switch 101 are "in series" with the second, first, third and fourth optical waveguides of the elementary switch 1.
For example, on the one hand (on the left in FIG. 9) of the first ends 2a, 3a, 17a and 20a, outside, waveguides of the first elementary switch 1 are respectively connected to the ports P3e, P4e, Pis and P2s and on the other hand (on the right in FIG. 9) the second ends 2b, 3b, 17b and 20b, external, waveguides of the second elementary switch 101 are respectively connected to the ports P3s, P4s, P2e and Pie.
Operating conditions equivalent to those mentioned above being observed, circulation modes or optical paths can be achieved by selectively activating the resonators 9, 10, 13 and 14 of the two elementary switches 1 and 101 of the base switch 501, so that the devices D1 to D4 can, selectively, exchange light waves via the basic switch 501, without blocking. The basic switch 501 is also "non-blocking".
In the case where the annular resonators of the elementary switches 1 and 101 are able to resonate at a frequency λ, the basic switch 501 is able to direct or redirect light waves established at this frequency.
As illustrated in FIG. 10, a basic switch 601 comprises two elementary switches, namely, an elementary switch 1 (on the right in FIG. 10) and an elementary switch 101 (on the left in FIG. 10), connected "in series ", But in a coupling mode such that the second ends 2b, 3b, 17b and 20b of the first, second, third and fourth optical waveguides 2, 3, 17 and 20 of the elementary switch 1 are connected respectively to the first ends 17a, 20a, 3a and 2a of the elementary switch 101.
Thus, the first, second, third and fourth optical waveguides 2, 3, 17 and 20 of the elementary switch 1 are connected "in series" with the first third, fourth, second optical waveguides 17, 20, 3 and 2 of the elementary switch 101.
For example, on the one hand (on the left in FIG. 10) of the first ends 2a, 3a, 17a and 20a, outside, waveguides of the elementary switch 101 are respectively connected to the ports P3e, P4e, Pis and P2s and on the other hand (on the right in FIG. 10) the second ends 2b, 3b, 17b and 20b, exterior, of the waveguides of the second elementary switch 101 are respectively connected to the ports Pie, P2e, P4s and P3s.
Operating conditions equivalent to those mentioned above being observed, circulation modes or optical paths can be achieved by selectively activating the resonators 9, 10, 13 and 14 of the two elementary switches 1 and 101 of the base switch 601, so that the devices D1 to D4 can, selectively, exchange light waves via the basic switch 601, without blocking. The basic switch 601 is also "non-blocking".
In the case where the annular resonators are able to resonate at a frequency λ, the basic switch 601 is able to direct or redirect light waves established at this frequency.
Having defined basic switches above, we will now describe complex switches including basic switches formed of pairs or pairs of elementary switches.
As illustrated in FIG. 11, a complex switch 1001, with four inputs and four outputs (4x4) which can be respectively connected to the devices D1 to D4, comprises an even number of elementary switches 101, as described with reference to FIG. 1, which are connected "in series", one after the other as described above with reference to FIG. 8.
The elementary switches 101 are assembled for example into two groups 1002A and 1002B "in series" which each comprise elementary switches 101, specifically identified, in each group, by the references 101 (λ1) ... 101 (λΐ) ... , the elementary switches 101 (λ1) being adjacent. Each group can include an even or odd number of elementary switches 101.
Thus, each group can include, “in series”, an elementary switch 101 (λ1) and an elementary switch 101 (λΐ), an elementary switch 101 (λ1) and two elementary switches 101 (λΐ) and 101 (Xk), a elementary switch 101 (λ1) and three elementary switches 101 (λΐ), 101 (Xk) and 101 (λ1), and so on.
Advantageously, the elementary switches 101 (λ1), 101 (λΐ) are respectively such that their respective resonators 9, 10, 13 and 14 are capable of deriving light waves having respectively frequencies λΐ, λΐ.
Thus, each pair of elementary switches 101 (λ1), 101 (λΐ), one of which is from group 1002A and the other from group 1002B, behaves specifically in an equivalent manner to the pairs of elementary switches 101 of base switch 401 previously described with reference to Figure 8.
Given that each pair of elementary switches 101 (λΐ), 101 (λΐ), is "non-blocking", the complex switch 1001 is "non-blocking".
Thus, incoming light waves including frequencies λΐ, λΐ are directed or redirected by the basic switches respectively constituted by the pairs of elementary switches 101 (λ1) and 101 (λΐ), respectively.
The light wave at the frequency λΐ is directed or redirected by the pair of elementary switches 101 (λ1) and passes through the other elementary switches without being redirected.
The light wave at the frequency λΐ is directed or redirected by the pair of elementary switches 101 (λΐ) and passes through the other elementary switches without being redirected.
It follows from the above that in the case where it is appropriate to redirect light waves comprising two frequencies, the complex switch 1001 comprises four elementary switches 101 forming two pairs of base switches 401 allocated respectively to the two frequencies.
In the case where it is necessary to redirect light waves comprising three frequencies, the complex switch 1001 comprises six elementary switches 101 forming three pairs of basic switches 401 allocated respectively to the three frequencies.
More generally, in the case where it is appropriate to redirect light waves comprising m frequencies, the complex switch 1001 twice comprises m elementary switches 101 forming m pairs of basic switches 401 allocated respectively to the m frequencies.
According to alternative embodiments, the elementary switches 101 making up the complex switch 1001, respectively allocated in pairs to light waves of frequencies λΐ and λΐ could be nested in different ways.
As illustrated in FIG. 12, a complex switch 2001, with four inputs and four outputs (4x4) which can be respectively connected to the devices DI to D4, comprises an even number of elementary switches connected “in series”, for example according to a following configuration .
The elementary switches are assembled for example into two groups 2002A and 2002B "in series". Each group can include an even or odd number of elementary switches.
More specifically, each group 2002A comprises at least two elementary switches 101 connected “in series” in accordance with the basic switch 401 described previously with reference to FIG. 8.
The elementary switches 101 of group 2002A and those of group 2002B are arranged head to tail so that the adjacent elementary switches 101, one of which is of group 2002A and the other of which is of group 200B, are connected in accordance with the basic switch 301 described with reference to FIG. 7. However, according to an alternative embodiment, the elementary switches 101 could be connected in accordance with the basic switch 201 described with reference to FIG. 4.
Advantageously, the elementary switches 101 of group 2002a and those of group 2002B are respectively such that their respective resonators 9, 10, 13 and 14 are able to derive light waves having respectively different frequencies.
Are thus formed, pairs or pairs of elementary switches, forming basic switches, subject respectively to different frequencies λΐ, λΐ.
Equivalently to the example described with reference to FIG. 11, each pair or pair of elementary switches, forming a basic switch, is capable of directing and redirecting optical waves established at the frequency allocated to them, while these optical waves pass through the other elementary switches directly.
According to an alternative embodiment, the elementary switches 101 of group 2002A and those of group 2002B could be connected in reverse.
The basic switches and the complex switches have been described and represented in the figures by placing the elementary switches in line. However, for the purpose of topography in the chips, the elementary switches could be non-aligned, so as to form, for example, coils.
As can be seen from the above, the basic switches described and the complex switches described are non-blocking, whereas they contain very simple but blocking elementary switches. As a result, the number of intersections of the optical waveguides and the number of resonators are reduced so that losses and crosstalk are reduced.

权利要求:
Claims (12)
[1" id="c-fr-0001]
1. Elementary photonic interconnection switch integrated in an optoelectronic chip, comprising first and second linear optical waveguides (2, 3), which intersect forming a first intersection (4) and which have first and first respectively second external optical coupling ends, so that the first and second linear waveguides have first branches between said intersection and said first ends and have second branches between said intersection and said second ends;
two first annular photonic redirection resonators (9, 10), respectively comprising a single ring, respectively coupled to the first and second optical waveguides (2) in local areas of optical coupling of the first branches, the latter passing between these first resonators, two second annular photonic redirection resonators (13, 14), respectively comprising a single ring, respectively coupled to the first and second optical waveguides in local areas of optical coupling, the latter passing between these second resonators, a third linear optical waveguide (17) coupled to the first and second annular resonators, located on the same side with respect to the first branch of the second optical waveguide and the second branch of the first optical waveguide, in local areas of optical coupling, and a fourth linear optical waveguide (20) coupled to u first and second annular resonators located on the same side with respect to the first branch of the first optical waveguide and the second branch of the second optical waveguide, in local areas of optical coupling;
the third and fourth optical waveguides having first ends on the side of the first annular resonators and second ends on the side of the second annular resonators.
[2" id="c-fr-0002]
2. Elementary switch according to claim 1, in which the third optical waveguide does not cross any of the other optical waveguides and in which the fourth optical waveguide does not cross any of the other optical waveguides.
[3" id="c-fr-0003]
3. Elementary switch according to claim 1, in which the first and third optical waveguides intersect and the second and the fourth optical waveguides intersect, respectively between their second ends and the second annular resonators, forming second and third intersections.
[4" id="c-fr-0004]
4. Elementary switch according to any one of the preceding claims, comprising an axis of symmetry on which is located said intersection between said first and second waveguides and on either side of which are located said first and second annular resonators respectively .
[5" id="c-fr-0005]
5. Elementary switch according to one of claims 1 and 2, in which the first ends of the third and fourth optical waveguides and the second ends of the first and second optical waveguides form light wave inputs, respectively optical wave outputs, and wherein the first ends of the first and second optical wave guides and the second ends of the third and fourth optical wave guides form light wave outputs, respectively optical wave inputs .
[6" id="c-fr-0006]
6. Basic photonic interconnection switch integrated in an optoelectronic chip, comprising two elementary switches according to any one of claims 1 to 5, in which the waveguides of one are selectively connected to the waveguides of the other.
[7" id="c-fr-0007]
7. Basic switch according to claim 6, in which the resonators of said elementary switches are capable of resonating at the same frequency.
[8" id="c-fr-0008]
8. Complex photonic interconnection switch integrated in an optoelectronic chip, comprising an even number of elementary switches according to any one of claims 1 to 5, in which the waveguides of the elementary switches
5 adjacent are selectively connected in series and in which the elementary switches are subjected in pairs to different frequencies.
[9" id="c-fr-0009]
9. Complex photonic interconnection switch integrated in an optoelectronic chip, comprising a plurality of
[10" id="c-fr-0010]
10 basic switches according to one of claims 6 and 7, in which the waveguides of the adjacent elementary switches are selectively connected in series and in which the basic switches are subjected to different frequencies.
10. Photonic interconnection network integrated in a chip
[11" id="c-fr-0011]
15 optoelectronics, comprising optoelectronic devices (Dl,
D2, D3, D4) respectively presenting input ports (Pie, P2e, P3e, P4e) and output ports (Pis, P2s, P3s, P4s) of optical waves, which are selectively connected via a basic switch according to one of claims 6 and 7 or via a complex switch according to one
[12" id="c-fr-0012]
20 of claims 8 and 9.

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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

WO2008080122A2|2006-12-22|2008-07-03|The Trustees Of Columbia University In The City Of New York|Systems and method for on-chip data communication|

---

US20130259420A1|2012-03-29|2013-10-03|Haruhiko Yoshida|Optical transmission-reception system and light-receiving unit|

---

WO2015168919A1|2014-05-09|2015-11-12|华为技术有限公司|Optical router|

---

WO2016116162A1|2015-01-22|2016-07-28|Telefonaktiebolaget Lm Ericsson |An optical switch, an optical network node and an optical network|

---

US5623356A|1995-02-09|1997-04-22|Lucent Technologies Inc.|Combined wavelength router and switch apparatus for use in a wavelength division multiplexed optical communication system|

---

US6195187B1|1998-07-07|2001-02-27|The United States Of America As Represented By The Secretary Of The Air Force|Wavelength-division multiplexed M×N×M cross-connect switch using active microring resonators|

---

US8019185B2|2008-02-14|2011-09-13|Hrl Laboratories, Llc|Unit-cell array optical signal processor|

---

US8032023B2|2008-11-07|2011-10-04|Alcatel Lucent|Reconfigurable DWDM wavelength switch based on complementary bandpass filters|

---

CN101872039A|2010-05-12|2010-10-27|中国科学院半导体研究所|44 non-blocking optical router based on active micro-ring resonator|

---

CN101871790B|2010-06-08|2012-03-21|浙江大学|Photo sensor based on vernier effect of broadband light source and cascading optical waveguide filter|

---

CN202041212U|2011-03-08|2011-11-16|东南大学|Integrated optical chip for three-axis optical fiber gyro|

---

CN103733448B|2011-08-10|2016-08-17|富士通株式会社|Semiconductor laser|

---

CN104678676B|2015-03-04|2017-10-31|兰州大学|A kind of reciprocal optical logical device based on micro-ring resonator|

---

US9602431B2|2015-03-20|2017-03-21|International Business Machines Corporation|Switch and select topology for photonic switch fabrics and a method and system for forming same|

---

FR3071932B1|2017-10-02|2019-11-08|Stmicroelectronics Sas|SWITCHES AND INTEGRATED PHOTONIC INTERCONNECTION NETWORK IN AN OPTOELECTRONIC CHIP|FR3071932B1|2017-10-02|2019-11-08|StmicroelectronicsSas|SWITCHES AND INTEGRATED PHOTONIC INTERCONNECTION NETWORK IN AN OPTOELECTRONIC CHIP|

---

CN110737052B|2019-11-04|2020-06-16|兰州大学|Reconfigurable arbitrary optical mode exchanger based on micro-ring resonator|

---

CN112799174B|2021-04-06|2021-06-25|中国电子科技集团公司信息科学研究院|Tunable optical filter|

法律状态:
2018-09-20| PLFP| Fee payment|Year of fee payment: 2 |

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2019-04-05| PLSC| Search report ready|Effective date: 20190405 |

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2019-09-19| PLFP| Fee payment|Year of fee payment: 3 |

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2021-07-09| ST| Notification of lapse|Effective date: 20210605 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1759184A|FR3071932B1|2017-10-02|2017-10-02|SWITCHES AND INTEGRATED PHOTONIC INTERCONNECTION NETWORK IN AN OPTOELECTRONIC CHIP|

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FR1759184|2017-10-02|FR1759184A| FR3071932B1|2017-10-02|2017-10-02|SWITCHES AND INTEGRATED PHOTONIC INTERCONNECTION NETWORK IN AN OPTOELECTRONIC CHIP|

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CN201821525590.XU| CN209446833U|2017-10-02|2018-09-18|Photonic interconnections switch and the network being integrated in opto chip|

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CN201811089670.XA| CN109597167B|2017-10-02|2018-09-18|Photonic interconnect switches and networks integrated in optoelectronic chips|

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US16/148,535| US10393965B2|2017-10-02|2018-10-01|Photonic interconnection switches and network integrated in an optoelectronic chip|