CO-PACKAGED LIGHT ENGINE CHIPLETS ON SWITCH SUBSTRATE
A co-packaged optical-electrical module includes a module substrate with a minimum lateral dimension no greater than 100 mm. The co-packaged optical-electrical module further includes a main die with a processor chip disposed at a central region of the module substrate, the processor chip being configured to operate with a digital-signal processing (DSP) interface for extra-short-reach data interconnect. Additionally, the co-packaged optical-electrical module includes a plurality of chiplet dies disposed densely along a peripheral region of the module substrate. Each chiplet die is configured to be self-packaged light engine on a sub-module substrate with a minimum lateral dimension to allow a maximum number of chiplet dies on the module substrate with a distance of any chiplet die from the main die smaller than 50 mm for extra-short-reach interconnect operation.
This application is commonly assigned to Inphi Corp. with U.S. Attorney Docket No. 929RO0788US, filed concurrently on Jun. 5, 2020, which is incorporated by reference herein for all purposes.
BACKGROUND OF THE INVENTIONThe present invention relates to optical telecommunication techniques. More particularly, the present invention provides a light engine chiplet having stacked silicon photonics chip with opto-electrical chips in a compact package as an assembly unit for co-packaging a switch processor on a single switch substrate with minimum interconnect lengths, a switch module having multiple co-packaged light engine chiplets, and an optical-electrical system having the same.
As science and technology are updated rapidly, processing speed and capacity of the computer increase correspondingly. The communication transmission or reception using the traditional cable is limited to bandwidth and transmission speed of the traditional cable and mass information transmission required in modern life causes the traditional communication transmission overload. To correspond to such requirement, the optical fiber transmission system replaces the traditional communication transmission system gradually. The optical fiber communication is chosen for systems requiring higher bandwidth and longer distance that electrical cable cannot accommodate. Present electronic industrial performs research toward optical transmission which will become the mainstream in the future even for short distance communication. Said optical communication is a technology in that light wave functions as signal carrier and transmitted between two nodes via the optical fiber. An optical communication system includes an optical transmitter and an optical receiver. By the optical transceiver, the received optical signal can be converted to an electrical signal capable of being processed by an IC, or the processed electrical signal can be converted to the optical signal to be transmitted via optical fiber. Therefore, objective of communication can be achieved.
Over the last few decades, the use of communication networks exploded. In the early days Internet, popular applications were limited to emails, bulletin board, and mostly informational and text-based web page surfing, and the amount of data transferred was usually relatively small. Today, Internet and mobile applications demand a huge amount of bandwidth for transferring photo, video, music, and other multimedia files. For example, a social network like Facebook processes more than 500 TB of data daily. With such high demands on data and data transfer, existing data communication systems need to be improved to address these needs.
40-Gbit/s and then 100-Gbit/s data rates wide-band WDM (Wavelength Division Multiplexed) optical transmission over existing single-mode fiber is a target for the next generation of fiber-optic communication networks. More recently, optical components are being integrated on silicon (Si) substrates for fabricating large-scale silicon photonics integrated circuits that co-exist with micro-electronic chips. Chip-scale lasers packaged directly within silicon photonics opto-electrical system have been of interest for many applications such as wide-band DWDM or CWDM communication and wavelength-steered light detection. A whole range of photonic components, including filters, (de)multiplexers, splitters, modulators, and photodetectors, have been demonstrated, mostly in the silicon-on-insulator (SOI) platform. The SOI platform is especially suited for standard DWDM communication bands around 1550 nm or CWDM communication band around 1310 nm, as silicon (n=3.48) and its oxide SiO2 (n=1.44) are both transparent, and form high-index contrast, high-confinement waveguides ideally suited for medium to high-integration planar integrated circuits (PICs).
With the advances of optical communication technology and applications driven by the market, the demands become stronger on increasing bandwidth for optical communication and decreasing package footprint of an optical transceiver. It is more and more challenging to integrate all necessary components within smaller and smaller module package. For the state-of-art optical transceiver products, all the critical components including clock data recovery (CDRs), modulator drivers, transimpedance amplifiers (TIAs), and PLC photonics blocks having optical passives, modulators, and photo detectors, are assembled side-by-side on a same SOI-based component substrate in a 2D fashion. This approach has at least two drawbacks for developing any future optical transceiver with data rate greater than 400G. Firstly, the side-by-side placement of the components consumes much of the board area for optical transceiver as a pluggable product or major substrate area for on-board optics product, making it very difficult to further shrink the product size. Secondly, side-by-side placement on the substrate creates longer electrical transmission length and often requires wire bonds between electrical die and photonics die, introducing more electrical loss which damages signal integrity for very high data rate transceiver product, e.g., >56 Gbaud symbol rate. In particular, the wire bonds lead to impedance mismatch due to large inductance, degrading the signal at higher frequencies. As such, it is not practical to use wirebond as electrical interconnect between chips or between chips and board for the applications where high frequency (e.g., >40 GHz) analog signal is transmitted. The large inductance of wire bonds has become a bottle neck of high-speed data transmission.
To shorten the interconnect length of conventional wire bonds between electronics devices (e.g., from modulator driver/TIA to digital signal processor DSP) or between electronics (driver/TIA) and photonics (e.g., CDR and PAM4 ASIC), people have started to use through-silicon via (TSV) process and silicon interposer in Si photonics die to replace wire bonds and make interconnections. With the advancement of silicon TSV manufacturing process for making Si photonics components and integrating active components with wafer-level assembly and burn-in testing, a co-packaged optical-electrical system that assembles an optical-electrical processor on a compact module substrate in very short interconnect length with multiple chiplet light engines would provide great high-performance benefit and desired bandwidth capacity for various applications involving backplane reach, or medium reach, or short reach, or extra-short reach interconnect switch for high-speed data communication.
BRIEF SUMMARY OF THE INVENTIONThe present invention relates to optical telecommunication techniques. More particularly, the present invention provides a light engine module package for assembling multiple silicon-photonics sub-modules on a single printed circuit board. Merely by example, the present invention discloses an in-packaged silicon-photonics sub-module of integrated optical transceivers on a single silicon photonics substrate each being configured with four or more lasers providing multiple optical channels, a compact light engine module package of assembling multiple such optical sub-modules on a single substrate via a silicon interposer with 1.6 Tbit/s opto-electrical switch capacity for high-speed data communication, though other applications are possible.
In modern electrical interconnect systems, high-speed serial links have replaced parallel data buses, and serial link speed is rapidly increasing due to the evolution of CMOS technology. Internet bandwidth doubles almost every two years following Moore's Law. But Moore's Law is coming to an end in the next decade. Standard CMOS silicon transistors will stop scaling around 3 nm. And the internet bandwidth increasing due to process scaling will plateau. But Internet and mobile applications continuously demand a huge amount of bandwidth for transferring photo, video, music, and other multimedia files. This disclosure describes techniques and methods to improve the communication bandwidth beyond Moore's law.
In an embodiment, the present invention provides an in-packaged multi-channel light engine. The in-packaged multi-channel light engine includes four or more sub-assemblies of optical-electrical sub-modules. Each sub-assembly is assembled in a case formed with a lid member covering a peripheral side member over peripheral edge region of a sub-module substrate. Each optical-electrical sub-module includes at least four laser chips, one or more driver chips, and one or more trans-impedance amplifier (TIA) chips separately flip-mounted on a silicon photonics substrate and is coupled to an optical interface block and an electrical interface block commonly mounted on the corresponding sub-module substrate. The in-packaged multi-channel light engine further includes a first frame fixture with a crossly-joined bar across middle region to form four or more window structures configured to allow the four or more sub-assemblies to be fitted in respectively with top surfaces of the lid members on top and bottom sides of the corresponding sub-module substrates at bottom. Additionally, the in-packaged multi-channel light engine includes a second frame fixture configured to hold the first frame fixture with the four or more sub-assemblies. The in-packaged multi-channel light engine further includes an interposer plate having a top side with four or more first-sets of conducting bumps, a bottom side with four or more second-sets of patterned conducting bumps, and a plurality of through-plate conducting vias and interior conducting paths configured to connect the first-sets of conducting bumps with the four or more second-sets of patterned conducting bumps. Each first-set of conducting bumps is configured to bond to a respective sub-module substrate. Furthermore, the in-packaged multi-channel light engine includes a module substrate having a top side with four or more sets of conducting bump contacts configured to respectively bond to the four or more second-sets of conducting bumps. The in-packaged multi-channel light engine further includes a backplate member attached to a bottom side of the module substrate. Moreover, the in-packaged multi-channel light engine includes a top plate member configured to compress the second frame fixture that holds the first frame fixture with the four or more sub-assemblies, the interposer plate, and the module substrate vertically together with the backplate member. The top plate member is configured as a heatsink with a plurality of fin structures.
In a specific embodiment, the present invention provides a sub-assembly of a multi-channel light engine. The sub-assembly includes a sub-module substrate severed as a bottom member and a peripheral frame member having four sides disposed along a peripheral region on a front surface of the sub-module substrate. The peripheral frame member has an open slot through at least one side. The sub-assembly further includes a silicon photonics substrate electrically bonded via through-substrate vias bump contacts on the front surface of the sub-module substrate. The silicon photonics substrate is configured to fabricate multiple Si-based waveguide devices therein. Additionally, the sub-assembly includes one or more driver chips, one or more transimpedance amplifier chips, and multiple laser chips separately mounted on the silicon photonics substrate and coupled to corresponding Si-based waveguide devices to form a transmitter unit and a receiver unit. The sub-assembly further includes an optical interface block containing multiple planar waveguides formed on a glass substrate mounted on the front surface of the sub-module substrate next to the silicon photonics substrate. The multiple planar waveguides are optically coupled to corresponding Si-based waveguide devices and optical fibers in a fiber cable laid through the open slot through the at least one side. The optical interface block is configured to deliver output transmitted from the transmitter unit to an output optical fiber and to receive incoming multi-wavelength light signal from an input optical fiber for the receiver unit. Furthermore, the sub-assembly includes an electrical interface block including multiple ASIC chips mounted on the front surface of the sub-module substrate or a back surface thereof and configured to receive data signals based on which control signals for the laser chips are generated for producing multi-channel optical signals and process digital signals converted from the incoming light signal for electrical host. Moreover, the sub-assembly includes a top lid member covering the peripheral frame member to enclose the light engine.
In an alternative embodiment, the present disclosure provides a packaged chiplet of a multi-channel light engine. The packaged chiplet includes a lid member connected with a periphery member having one side with a socket port. Additionally, the packaged chiplet includes a sub-module substrate having a peripheral region configured to be attached with the periphery member to form an enclosure with the lid member. Furthermore, the packaged chiplet includes a first die comprising an application-specific integrated circuit (ASIC) chip configured to at least serve as a digital signal processing (DSP) interface. Moreover, the packaged chiplet includes a second die comprising a silicon photonics chip including Si-based waveguide devices coupled to multiple laser chips to respectively provide multiple different wavelengths for multiple channels of an optical transceiver. The second die is electrically coupled and physically stacked with the first die in the enclosure.
In another alternative embodiment, the present disclosure provides a co-packaged optical-electrical module. The co-packaged optical-electrical module includes a module substrate with a minimum lateral dimension no greater than 100 mm. Additionally, the co-packaged optical-electrical module includes a main die with a processor chip disposed at a central region of the module substrate. The processor chip being configured to operate with a digital-signal processing (DSP) interface for extra-short-reach data interconnect. Furthermore, the co-packaged optical-electrical module includes a plurality of chiplet dies disposed densely along a peripheral region of the module substrate. Each chiplet die is configured to be self-packaged light engine on a sub-module substrate with a minimum lateral dimension to allow a maximum number of chiplet dies on the module substrate with a distance of any chiplet die from the main die smaller than 50 mm for extra-short-reach interconnect operation.
The present invention achieves these benefits and others in the context of known waveguide laser modulation technology. However, a further understanding of the nature and advantages of the present invention may be realized by reference to the latter portions of the specification and attached drawings.
The following diagrams are merely examples, which should not unduly limit the scope of the claims herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. It is also understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this process and scope of the appended claims.
The present invention relates to optical telecommunication techniques. More particularly, the present invention provides an in-packaged optical-electrical module assembling multiple sub-modules on a single line card, each being configured as a multi-channel light engine containing an optical-electrical transceiver based on silicon-photonics platform. Merely by example, the present invention discloses a sub-assembly for the sub-module integrating multiple laser chips providing multiple optical channels on a single silicon photonics substrate, a compact package for multiple such sub-assemblies of sub-modules on a single line card providing 0.4 Tbit/s or higher per sub-module for building desired switching capacity in various applications of high-speed data communication with different interconnect lengths, though other applications are possible.
The following description is presented to enable one of ordinary skill in the art to make and use the invention and to incorporate it in the context of particular applications. Various modifications, as well as a variety of uses in different applications will be readily apparent to those skilled in the art, and the general principles defined herein may be applied to a wide range of embodiments. Thus, the present invention is not intended to be limited to the embodiments presented, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
In the following detailed description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. However, it will be apparent to one skilled in the art that the present invention may be practiced without necessarily being limited to these specific details. In other instances, well-known structures and devices are shown in block diagram form, rather than in detail, in order to avoid obscuring the present invention.
The reader's attention is directed to all papers and documents which are filed concurrently with this specification and which are open to public inspection with this specification, and the contents of all such papers and documents are incorporated herein by reference. All the features disclosed in this specification, (including any accompanying claims, abstract, and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features.
Furthermore, any element in a claim that does not explicitly state “means for” performing a specified function, or “step for” performing a specific function, is not to be interpreted as a “means” or “step” clause as specified in 35 U.S.C. Section 112, Paragraph 6. In particular, the use of “step of” or “act of” in the Claims herein is not intended to invoke the provisions of 35 U.S.C. 112, Paragraph 6.
Please note, if used, the labels left, right, front, back, top, bottom, forward, reverse, clockwise and counter-clockwise have been used for convenience purposes only and are not intended to imply any particular fixed direction. Instead, they are used to reflect relative locations and/or directions between various portions of an object.
In an aspect, the present disclosure provides an integrated optical-electrical sub-module based on silicon photonics platform and an in-packaged optics assembly of four or more sub-modules on one module substrate with 1.6 Tbit/s or higher optical lane speeds for PAM backplane/optical reach for various interconnect ranges of data communication. As data transmission-capacities increase in WDM systems, demand on high-speed, compact optical transceiver based on silicon photonics platform increasingly attract more and more interest over the recent years. For example, a pluggable optical transceiver in compact form factor. Yet, the compact optical transceiver is still a stand-alone device that needs to be coupled with separate passive optical devices like Mux/Demux and one or more gear box or retimer chips to connect with an electrical switch device to form a functional light engine, which requires a fairly large package size and high power-consumption.
Referring to
Optionally, the modulator 160 in any one of first branch 01 is configured in a linear waveguide-based Mach-Zehnder modulation scheme. Each modulator 160 includes two waveguide branches with desired phase delay configured to match with respective one of four wavelengths 1270 nm, 1290 nm, 1310 nm, and 1330 nm of the four CWDM channels. Optionally, the four wavelengths can be selected from a group of 1270 nm, 1280 nm, 1290 nm, and 1300 nm or a group of 1300 nm, 1310 nm, 1320 nm, and 1330 nm with smaller channel spacing. Optionally, each wavelength is selected from a range from 1270 nm to 1330 nm as one CWDM channel to support the optical signal transmission in high-speed (e.g., 100 Gbit/s or higher) data communication. A Driver module 150 is provided as a separately fabricated CMOS or SiGe chip flip-mounted on the same silicon photonics substrate 100. Optionally, a redundant or a replicate driver module 150′ (not shown in
Referring to
In another aspect, the present disclosure provides a fabrication process for the integrated optical-electrical sub-module based on silicon photonics platform such as the transceiver sub-module 1000. In some embodiments, the fabrication process includes wafer level assembly of 2.5D silicon photonics substrate involving 2.5D silicon interposer and 220 nm silicon-on-insulator (SOI) substrate. The process includes monolithic formation of multiple silicon or silicon nitride waveguides in the silicon photonics substrate 100 for connecting or aligning with several different silicon photonics devices including power splitters, SiGe or Ge high-speed photodetectors, and Si/SiN-based Mach-Zehnder interferometer modulator devices formed in the same silicon photonics substrate 100. The process also includes coupling the silicon waveguides with passive PLC devices such as optical multiplexers and demultiplexers formed on a glass or sapphire substrate and mounted onto the silicon photonics substrate as PLC block 200. The process further includes flip-mounting active devices such as laser chips to the silicon photonics substrate as an in-packaged design and align the laser chips directly to the waveguides in the silicon photonics substrate or PLC devices in the PLC block. Optionally, some of the silicon photonics components mentioned above are also silicon waveguides themselves monolithically formed in a same manufacture process for preparing the silicon photonics substrate to integrate the optical-electrical transceiver sub-module 1000.
Additionally referring to
In yet another aspect, the present disclosure provides an in-packaged optical-electrical module assembling four optical-electrical sub-modules as mentioned above.
Each of the four sub-modules in
Optionally, each of the four sub-modules in
The PLC block 200 associated with each of the four sub-modules 2000A (through 2000D) includes at least a first optical multiplexer (see
In the embodiment, the PLC block 200 associated with the same one of the four sub-modules, e.g., 2000A (through 2000D), also includes a built-in optical receive path configured to receive incoming light signals via optical fibers from network. The PLC block 200 includes at least a first optical demultiplexer to demultiplex an incoming light signal from one fiber (carrying 4 wavelengths) to four individual light signals with the respective four CWDM channel wavelengths. Each optical demultiplexer in the PLC block 200 is a planar waveguide formed on a glass or sapphire substrate properly coupled to one optical fiber. Each of the four individual light signals is coupled from planar waveguide in the PLC block 200 to the waveguides in the silicon photonics substrate and delivered to a photodetector block (referred to
In this embodiment, PLC block 200 contains two 4-to-1 multiplexer and two 1-to-4 demultiplexer to create two sets of four light paths. For the multi-channel light engine 3000 that packages total four optical-electrical sub-modules 2000A, 2000B, 2000C, 2000D, it can detect different input light signals in 32 channels. In a case that each channel carries data in a rate of 50 Gbit/s, each quadrant sub-module delivers 400 Gbit/s in data rate with 4 CWDM lasers. The in-packaged optical-electrical module 3000 can provide 1.6 Tbit/s data switching communication capacity. In another case with improved modulators, driver chip, TIA chip, and DSP chip, each channel can carry 100 Gbit/s speed even though each quadrant sub-module uses the same 4 CWDM lasers. As a result, the in-packaged optical-electrical module 3000 can expand its data switching communication speed up to 3.2 Tbit/s.
In still another aspect, the present disclosure provides a packaging assembly of the in-packaged optical-electrical module of
As shown in
Referring to
Referring to
Referring to
In one embodiment, as illustrated in
In the embodiment, the same SiPho chip also includes a receiver unit configured to use a set of photodetectors to detect multi-channel optical signals received in an optical receive path and demultiplexed in the optical interface block from an incoming multiplexed optical signal and use the TIA chip to convert the detected multi-channel optical signals to current signals which are digitized and processed in the electrical interface block before being delivered as N to N lanes of digitized signals for electrical host. including an optical transmit path and an optical receive path in the same silicon photonics substrate 100. One driver chip 150 and one TIA chip 140 in the SiPho chip are involved in handling transmission of four light signals from the four laser chips to the optical transmit path and detecting four incoming light signals from the optical receive path. Another driver chip 150′ and another TIA chip 140′ are separately involved in handling transmission of four replicate light signals from the four laser chips to the optical transmit path and detecting four additional incoming light signals from the optical receive path. These TIA/Driver chips in each SiPho chip of the packaged sub-assembly 2000A are configured to handle reception and transmission of light signals in two replicate sets of 4 CWDM channels with respective wavelengths centered at 1270 nm, 1290 nm, 1310 nm, and 1330 nm. Optionally, the electrical interface block comprises a digital signal processing (DSP) chip 2030 configured to process N to N Lanes of digitized signals with a data rate of 25 Gbit/s per lane. Optionally, the electrical interface block comprises a digital signal processing (DSP) chip 2030 configured to process N to N Lanes of digitized signals with a data rate of 50 Gbit/s per lane. Optionally, the electrical interface block comprises a digital signal processing (DSP) chip 2030 configured to process N to N Lanes of digitized signals with a data rate of 50 Gbit/s per lane. Optionally, the electrical interface block comprises a replicate digital signal processing (DSP) chip 2030′ and a microcontroller chip 2040.
Additionally referring to
Furthermore referring to
Referring to
Optionally, the interposer plate 3040 is a passive interposer provided with four quadrant grids of conductor-filled through-substrate via (TSVs) bumps respectively formed on four quadrant regions of the interposer plate projected to the four sub-module substrates. For example, the quadrant grid of TSV bumps 3044A is designed for forming electrical connections between the sub-module substrate 2300A to direct bonding interconnects (DBI) contacts 3052A in a corresponding quadrant region of the module substrate 3050. Optionally, each quadrant grid of TSV bumps (e.g., 3044A) is provided to surround a quadrant hollow region (e.g., 3042A) of the interposer plate 3040 to yield the space for optional ASIC chip (e.g., 2050 in
Optionally, the interposer plate 3040 is an active interposer that contains four quadrant grids of TSV bumps to connect IOs and supply as well as to provide active regions with embedded circuit devices to pass electrical signals using buffers between two DBI contacts. Optionally, the interposer plate 3040 is a 2.5D silicon interposer. Optionally, the interposer plate 3040 is a 3D silicon interposer.
Referring to
In still another aspect, the present invention provides a light engine chiplet that integrates a silicon photonics (SiPho) chip with opto-electrical interfaces to form a multi-channel transceiver in a compact package on a single substrate. Optionally, the light engine chiplet is provided as one integrated optical-electrical module outlined in
Referring to part B of the
Referring to part C of the
Optionally, the SiPho chip of the light engine chiplet 8000 still integrates 4 laser chips 110′ on the silicon photonics substrate 100′. But all laser chips are redesigned for emitting laser light with higher power. In the silicon photonics substrate 100′, several waveguide-based 1-to-4 optical splitters can be formed to yield 4 replicate channels per one laser. Thus, each light engine chiplet 8000 can provides 16 channels or 4 sets of 4 CWDM channels to yield total 1.6 Tbit/s capacity if each channel is provided with 100 Gbit/s capacity under PAM-4 56 Gbaud data modulation. Optionally, the high-power laser chips could be mounted on the silicon photonics substrate 100′, or mounted externally and coupled into the waveguide-based devices in the silicon photonics substrate 100′. Optionally, the SiPho chip of the light engine chiplet 8000 can integrate 8 laser chips when each laser chip is coupled to a 1-to-2 optical splitter. Optionally, the light engine chiplet 8000 still just integrate 4 laser chips 110′ on the silicon photonics substrate 100′ respectively coupled to four 1-to-2 optical splitters, giving 8 channels per chiplet. Optionally, a next generation modulation scheme using PAM-6 or PAM-8, or using higher Gbaud rate under PAM-4, a 200 Gbit/s per wavelength capacity can be provided so that each light engine chiplet in a 10 mm×10 mm package can still yield 1.6 Tbit/s capacity. Optionally, coherent polarized light signal can be implemented to provide directly 200 Gbit/s or 400 Gbit/s per wavelength in bandwidth to allow each chiplet to support extra-high data rate communication. Optionally, the light engine chiplet 8000 can be provided as one independent unit assembled within a multi-unit optical-electrical module or directly integrated on a same switch substrate with multiple chiplets and a switch processor.
Referring to part C of
Referring to
Referring to
Referring to
Referring to
Referring to part C of
In still another aspect, the present disclosure provides a co-packaged optical module with a switch processor and multiple light engine chiplets commonly mounted on a switch substrate for extra short reach interconnect or equivalent protocol in high-speed data communication. With obvious benefit of reduced interconnect loss (<10 dB) in sight, optics based on silicon photonics platform is brought closer and closer to a switch processor for meeting demands on increasing data rate in high-speed data communication. As shown in
In a specific embodiment, each packaged light engine chiplets 9201 includes an optical connector port for plugging-in an optical connector head that is coupled to a PLC block to serve its optical line interface for the multi-channel optical-electrical transceiver. Optionally, each chiplet integrates four laser chips in a silicon photonics substrate to provide four CWDM wavelengths corresponding to four optical channels of the optical-electrical transceiver. Optionally, four 1-to-2 splitters can be added to split each laser light to two to provide four more replicate optical channels with the same four CWDM wavelengths. Optionally, each chiplet can integrate four more laser chips or choose four 1-to-4 splitters for four high-powered laser chips to yield 8 or 16 channels. Each light engine chiplet can fully be operated independently with its own controller and driver. Thus, in the co-packaged optics configuration as shown in
In an embodiment, a goal of moving optical-electrical module closer and closer to the switch processor from using pluggable optical module with gear box or retimer to on-board in-package optics and further to the co-packaged optical module that eliminates the gear box or retimer is to reduce power loss (from 20 to 35 dB down to <10 dB) depended on the range of interconnect and substantially reduce power consumption per bit from about 5.0 pJ/bit to <1.8 pJ/bit. Since the switch processor has its own limits on package size especially when its operation capacity is increased to 51.2T generation, a requirement for smaller total module package size and push for smaller distance between the switch processor and each light engine co-packaged naturally put limitations on both the size of switch substrate and the size of light engine (or sub-module) substrate.
Note, for each 10 mm×10 mm 1.6T light engine, 4 (or even 8) laser chips can still be integrated inside the chiplet package (
In some other scenarios (C through F) of the embodiment, the switch processor is co-packaged with multiple light engines in a much closer distance on a same switch substrate to form a co-packaged optical (switch) module which can be deployed to a network system in a single rack chassis. No gear box or retimer is required while host FEC is used in digital signal processing with 56 Gbaud electrical interface. Each light engine in the scenario C of the embodiment includes a silicon photonics chip packaged with a TIA chip and modulation driver chip and stacked up with a digital signal processing (DSP) chip above or under the silicon photonics chip. Optionally, the DSP chip is configured with a host interface, PCS/PMA layers, and a line interface for PAM optical reach operation. The switch processor in this scenario is configured with DSP interface for 51.2T operation (see
Alternatively, the scenarios D through F illustrate options of pushing the light engine closer and closer to the processor with switch substrate or light engine substrate sizes being adjusted depending on individual light engine chiplet die sizes. Each light engine chiplet is assumed to maintain 100 Gbit/s per wavelength in each optical lane. In a specific embodiment, the light engine in the scenario D includes a silicon photonics chip and transimpedance amplifier with externally coupled laser sources driven by analog driver and external multiplexer/demultiplexer optical interface to connect via on-board fibers to an optical connector, while eliminating retimer function within the light engine. Optionally, each light engine can be provided in a packaged chiplet form with a smaller individual die size. Optionally, the light engine includes an external SiGe-based modulation driver with relatively higher power consumption. Optionally, the light engine includes an external CMOS driver integrated in the switch processor to reduce the power consumption. The switch processor in the scenario D incorporates the DSP host interface only without FEC function while implementing PAM optical reach. Optionally, the switch substrate size can be reduced further depending on individual light engine die size and throughput setting per light engine. In an example, each light engine still provides 1.6 Tbit/s, thus, the switch module still needs 32 light engines to have 51.2 Tbit/s total throughput. In another example, each light engine is expanded to 3.2 Tbit/s, the co-packaged switch module needs just 16 light engines to have 51.2 Tbit/s total throughput. As the result, a maximum distance between the switch processor and one of the multiple light engine chiplets co-packaged in the scenario D may be reduced further. In an example, the distance is smaller than 15 mm to push even lower optical power loss in the XSR interconnect operation.
Additionally, in the scenario E, the light engine includes a silicon photonics chip packaged with a TIA chip only while moving the modulation driver into CMOS chip associated with the switch processor. The individual die size may be further reduced as the lasers and optical interface can all be coupled externally. The switch processor in the scenario E incorporates the DSP host interface to interact with electrical host yet without FEC function and analog modulation driver to control laser signals while implementing PAM optical reach. As the result, a maximum distance between the switch processor and one of the multiple light engine chiplets co-packaged in the scenario E may be reduced even further. In an example, the distance is smaller than 5 mm to push even lower optical power loss in the extra-short-reach (XSR) or equivalent protocol in data interconnect operation and lower power consumption per module with the same 51.2 Tbit/s total throughput.
Furthermore, in the scenario F, the light engine is packaged by integrating the silicon photonics chip with a Serializer/Deserializer (SerDes) block and a TIA chip in the packaged chiplet. The SerDes block provides data transmission over a single line or a differential pair in order to minimize the number of I/O pins and interconnects. The data speed per line can be 56 Gb/s or 112 Gb/s. Optionally, the SerDes block includes digital encoding/decoding blocks. Accordingly, the switch processor in this scenario F employs Advanced Interface Bus (AIB) or parallel bus with packages to allow heterogeneous integration of multiple die into a single package to connect the analog front-end, signal pre-processing, to interface with Ser/Des block in each light engine chiplet for ultra-short-reach (USR) interconnect operation. In the scenario F, between the switch processor and the multiple light engine chiplets, an active Si interposer is inserted. The active Si interposer extends the concept of Chip-on-Wafer-on-Substrate (CoWoS) technology based on a 2.5D or 3D integrated circuit employing through-silicon via (TSV) interposer-based packaging technology to provide reticle matching the total module size and to hold the main switch processor die and all chiplet dies. Optionally, the active Si interposer contains a grid of TSVs to connect IOs and supply plus active regions to pass signals using buffers between two grids of conductive contacts formed according to the design of the main processor die and multiple dies of light engine chiplets as shown in
While the above is a full description of the specific embodiments, various modifications, alternative constructions and equivalents may be used. Therefore, the above description and illustrations should not be taken as limiting the scope of the present invention which is defined by the appended claims.
Claims
1. A packaged chiplet of a multi-channel light engine comprising:
- a lid member connected with a periphery member having one side with a socket port;
- a sub-module substrate having a peripheral region configured to be attached with the periphery member to form an enclosure with the lid member;
- a first die comprising an application-specific integrated circuit (ASIC) chip configured to at least serve as a digital signal processing (DSP) interface; and
- a second die comprising a silicon photonics chip including Si-based waveguide devices coupled to multiple laser chips to respectively provide multiple different wavelengths for multiple channels of an optical transceiver, the second die being electrically coupled and physically stacked with the first die in the enclosure.
2. The packaged chiplet of claim 1 wherein the ASIC chip comprises a digital signal processing (DSP) chip formed in a first component substrate through a CMOS process to provide a host interface and a line interface.
3. The packaged chiplet of claim 2 wherein the DSP chip is configured to perform extra-short-reach (XSR) interconnect operation through the host interface and support PAM optical reach (POR) operation for the line interface.
4. The packaged chiplet of claim 1 wherein the ASIC chip comprises an integrated modulator driver and a microcontroller.
5. The packaged chiplet of claim 2 further comprises a middle die comprising an ASIC control chip and a transimpedance amplifier chip respectively formed in a second component substrate and a third component substrate, respectively coupled to bottom conductive contacts of the first component substrate.
6. The packaged chiplet of claim 4 wherein the integrated modulator driver is configured to drive optical signal modulation using pulse-amplitude modulation PAM-4 or PAM-6 or PAM-8 format.
7. The packaged chiplet of claim 4 wherein the Si-based waveguide devices in the silicon photonics chip comprise multiple power splitters and multiple modulators integrated in a transmitter unit coupled to the multiple laser chips and the integrated modulator driver and the DSP interface, and comprise multiple photodetectors integrated in a receiver unit coupled to a transimpedance amplifier and the DSP interface and a replicate set of photodetector block configured to detect optical signals from a replicate optical receive path, the replicate optical receive path comprising waveguides in a silicon photonics substrate aligned respectively with the one or more demultiplexing planar waveguide in a planar light circuit (PLC) block which are coupled with another input optical fiber.
8. The The packaged chiplet of claim 7 further comprising the PLC block integrated in an optical connector interface coupled externally via the socket port at the one side of the periphery member to the Si-based waveguide devices in the silicon photonics chip in the packaged chiplet.
9. The The packaged chiplet of claim 8 wherein the PLC block comprises at least a multiplexer and a demultiplexer based on planar waveguide on a glass substrate, the multiplexer being coupled to the transmitter unit for combining multiple different wavelengths for multiple channels into one optical path coupled to an output optical fiber, the demultiplexer being coupled to the receiver unit for separating an incoming optical signal carrying multiple different wavelengths from an input optical fiber to multiple optical paths respectively being detected by the multiple photodetectors.
10. The packaged chiplet of claim 8 wherein each of the multiple channels represents one optical lane with a wavelength selected from 1270 nm, 1290 nm, 1310 nm, and 1330 nm CWDM channels to deliver data in a rate of 100 Gb/s or 200 Gb/s or higher.
11. The packaged chiplet of claim 1 wherein the sub-module substrate comprises a micro land grid array (LGA) including a matrix array of conductive socket contacts for chip testing and surface-mount packaging assembly.
12. The packaged chiplet of claim 1 further comprises a socket base member configured to receive the sub-module substrate attached with the periphery member connected to the lid member to allow the enclosure being clamped.
13. A co-packaged optical-electrical module comprising:
- a module substrate with a minimum lateral dimension no greater than 100 mm;
- a main die with a processor chip disposed at a central region of the module substrate, the processor chip being configured to operate with a digital-signal processing (DSP) interface for extra-short-reach data interconnect;
- a plurality of chiplet dies disposed densely along a peripheral region of the module substrate, each chiplet die being configured to be self-packaged light engine on a sub-module substrate with a minimum lateral dimension to allow a maximum number of chiplet dies on the module substrate with a distance of any chiplet die from the main die smaller than 50 mm for extra-short-reach interconnect operation.
14. The co-packaged optical-electrical module of claim 13 wherein the main die and the plurality of chiplet dies co-packaged on the module substrate comprise a multi-channel optical-electrical switch enabled with a total data throughput of 51.2 Tbit/s as each light engine therein is independently configured to be a multi-channel optical-electrical transceiver.
15. The The co-packaged optical-electrical module of claim 14 wherein the plurality of chiplet dies co-packaged on the module substrate comprises total 32 self-packaged light engines, or eight self-packaged light engines disposed on each peripheral side of the module substrate, each self-packaged light engine comprising the multi-channel optical-electrical transceiver formed on the sub-module substrate of 10 mm×10 mm with data capacity of 1.6 Tbit/s higher.
16. The co-packaged optical-electrical module of claim 15 wherein each self-packaged light engine comprises a silicon photonics chip comprising 4 waveguide-based 1-to-4 optical splitters respectively coupled to 4 laser chips to generate 4 sets of 4 wavelength channels of a 16-channel optical-electrical transceiver, each wavelength channel serving as an optical line for transmitting data in 100 Gibt/s under PAM-4 modulation format.
17. The co-packaged optical-electrical module of claim 15 wherein each self-packaged light engine comprises a silicon photonics chip comprising 4 waveguide-based 1-to-2 optical splitters respectively coupled to 4 laser chips to generate 2 sets of 4 wavelength channels of a 8-channel optical-electrical transceiver, each wavelength channel serving as an optical line for transmitting data in 200 Gibt/s under PAM-4 or PAM-6 modulation format.
18. The co-packaged optical-electrical module of claim 15 wherein each self-packaged light engine comprises 4 remote laser sources split in 8 ways and respectively coupled to 32 100 Gibt/s optical lines to provide 3.2 Tbit/s per light engine.
19. The co-packaged optical-electrical module of claim 15 wherein each self-packaged multi-channel light engine is clamped in a socket base member of about 10 mm×10 mm in lateral dimension, the socket base member including two register pins for mounting the respective chiplet die into one peripheral site on the module substrate.
20. The co-packaged optical-electrical module of claim 15 wherein each self-packaged light engine comprises an optical socket port for coupling a planar light circuit block integrated in an optical connector interface, the planar light circuit block comprising at least a multiplexer and a demultiplexer formed on a glass substrate to serve as an optical interface of the multi-channel optical-electrical transceiver.
21. The co-packaged optical-electrical module of claim 13 wherein the processor chip in the main die is configured to incorporate a DSP interface using PAM optical reach for data interconnect with each light engine in the plurality of chiplet dies and to couple an external analog modulator driver to reduce die size of each chiplet die so that the distance of any chiplet die from the main die is smaller than 15 mm for extra-short-reach interconnect operation.
22. The co-packaged optical-electrical module of claim 13 wherein the processor chip in the main die is configured to integrate a CMOS modulator driver and a DSP interface using PAM optical reach in line interface for data interconnect with each light engine in the plurality of chiplet dies to further reduce die size of each chiplet die so that the distance of any chiplet die from the main die is smaller than 5 mm for extra-short-reach interconnect operation.
23. The The co-packaged optical-electrical module of claim 13 wherein the processor chip in the main die is configured to adopt Advanced Interface Bus (AIB) or parallel bus in the DSP interface to communicate with a Serializer/Deserializer block in each chiplet die so that die size of each chiplet die is further reduced and the distance of any chiplet die from the main die is smaller than 1 mm for ultra-short-reach interconnect operation.
24. The co-packaged optical-electrical module of claim 23 further comprising an active Si interposer inserted between the main die and the plurality of chiplet dies on top and the module substrate at bottom.
Type: Application
Filed: Jun 5, 2020
Publication Date: Dec 9, 2021
Inventors: Radhakrishnan L. NAGARAJAN (Santa Clara, CA), Liang DING (Singapore), Mark PATTERSON (Santa Clara, CA), Roberto COCCIOLI (Santa Clara, CA), Steve ABOAGYE (Santa Clara, CA)
Application Number: 16/894,611