Michael Lebby, Chair in Optoelectronics at Glyndŵr University, CEO at Lightwave Logic Inc
Presently, Michael is driving new frontiers in the integrated photonics field as: CEO and Board Director, Lightwave Logic Inc. Michael is also part-time full Professor and Chair of optoelectronics at Glyndwr University in Wales, UK where he contributes to the European Commission’s programs and pilot lines in integrated photonics. Michael has been involved in photonics for his whole career which began with research for the UK Government R&D labs in 1977, and continued at AT&T Bell Labs in 1984. At that time, Michael’s activities included researching novel optoelectronic devices in III-V compound semiconductors. Michael then went to Motorola’s Corporate R&D labs in 1989 and drove the VCSEL based technology platform to product and high volume manufacturing. He continued his fiber optics roles at AMP/TE Connectivity, and then helped initiate Intel’s silicon photonics work in 1999. In 2001, he founded his own company Ignis Optics to develop OC-48/192 transceivers and subsequently sold the company to Bookham (now Oclaro). Michael then led OIDA (Optoelectronics Industry Development Association) in Washington DC to campaign on behalf of the photonics industry. At OIDA Michael coined the term ‘green photonics’ and established this as discipline in the industry. Michael also spoke on Capitol Hill representing the optoelectronics industry. Since 2010, Michael has been focusing on bringing PIC (Photonic Integrated Circuit) based technologies to market in various roles that include Solar, LED lighting, and Integrated Photonics for fiber communications. Michael is pursuing high speed polymer based integrated photonics as part of a polymer PIC platform at Lightwave Logic Inc.
Will PICs be the engine of growth over the next decade? Is the growth supported in our roadmaps world-wide?
The increasing demand for higher speed data transmission has ramifications across all network operations. Mobile operators expect 5G to meet customer demands with data rates up to 1 G/bps. The demands for fiber networks – the backbone of high capacity data conveyance – are far greater. As PICs move into 100G data center slots, the push for ever-faster, higher bandwidth intra- and inter-center communications continues. At the same time, photonic integrated circuits are relatively new technology, with automated TAP far behind state-of-the-art microelectronics manufacturing. Can PICs support advanced datacom and long-distance telecom applications as reflected in our global technology roadmaps?
How does the PIC industry deliver on the promises of size, speed, and economy with high quality?
PIC devices offer size, performance and energy advantages that have enabled rapid growth among optical component manufacturers while encouraging entrants offering new and novel insights. End users need high levels of consistent quality--the hallmarks of CMOS device fabrication--while process tool, assembly and test automation experts strive to support the unique requirements of PIC module TAP. Today’s PIC-based transceivers or PIC transceiver components are often assembled, packaged and tested manually. Is it possible to drive demand while the infrastructure needed to support it is still being conceived, designed and built?
PICs Today − Datacom, Imaging and Transport
PIC differentiation, emerging markets, and common modular platforms for assembly and test.
Ignazio Piacentini - ficonTEC
Differentiation in the assembly and test process requirements between photonic devices in emerging markets has consequences for automated production equipment. Modularity in the approach to system layout provides the tools for addressing these differences, where both common application-specific platforms and custom configurations become the norm. But the benefits don’t end there.
New VCSEL opportunities in 3D sensing and beyond
Pauline Rigby - Lightcounting
Vertical-cavity surface emitting lasers (VCSELs) have been the workhorse of datacom networks for several decades – lighting up multimode fibres at wavelengths around 850nm – but new opportunities in consumer markets require product volumes that are orders of magnitude greater - with visible effects on the revenues reported by key components vendors. Apple pioneered 3D sensors for facial recognition in smartphones and world-facing 3D sensors to enable AR/VR will be next. New opportunities for lasers in lidar systems for autonomous driving are also on the horizon.
The future and economics of PICs and PLCs in data center applications
Henk Bulthuis - Kaiam Corporation
Ewit Roos - Photon Delta
Large scale PICs, integration with InP lasers and PICs across future networks and markets
Mehrdad Ziari - Infinera
Achieving high quality 100G data center PIC Integration
Katharine Schmidtke - Facebook
Device prototyping using the CORNERSTONE platform
Graham Reed - Cornerstone, University of Southampton
As the market adoption of silicon photonics technologies continues to rise, and ever more fabless companies enter the market, there is a clear need for a flexible device prototyping foundry service that retains the ability for device level innovation, and also offers a clear path for up-scaling. The CORNERSTONE platform offers a low cost multi-project-wafer (MPW) service that enables a degree of customisation, which may not be accessible at other foundries. Through the use of projection lithography, fabrication processes can be easily transferred to other foundries for mass production. Additionally, the ability to exploit high resolution e-beam lithography mimics more advanced technology nodes for certain layers, should this be deemed necessary. This talk gives an overview of the CORNERSTONE platform.
AIM Photonics’ role in developing next generations of PICs and TAP manufacturing expertise
Michael Liehr - American Institute for Manufacturing Photonics
AIM Photonics is a Manufacturing USA institute whose mission is to provide cost-effective and easy-to-use access to state-of-the-art silicon photonics processing. AIM Photonics is providing access to a Multi-Project-Wafer program enabled with a highly competitive component library and offers Assembly and Packaging services starting 2019. AIM is supporting consortium projects with the intent to enable new manufacturing technology for reduced assembly cost, but is also developing custom processes in support of industry or government funded PIC products. AIM has a Si Photonics process available at SUNY Poly and an InP offering at Infinera and potential application examples will be discussed.
PIC Innovation − EPDA, TAP & PICs Beyond Datacom
Photonics and EDA – Round Hole and Square Pegs
Tom Daspit - Mentor, a Siemens Business
IC designers & tool developers have lived in an orthogonal world for 60 + years. Hundreds of thousands of man years have been invested developing EDA tools for IC design. This investment representing 100’s of millions of lines of code. Photonics and MEMS have changed this. For integrated photonics to take off, commercial EDA tools are needed that can implement and physically verify curved shapes. Throughout the design flow, support is needed for coexistence of both electrical and photonic designs. Layout automation is required to enable the expected growth in the size of photonics designs.
Hybrid PICs - Technology Alternatives and Design Implications
André Richter - VPIphotonics
Hybrid integrated photonics attracts growing attention, as it enables complete and cost-efficient optical chip solutions for silicon, silicon nitride, and polymer photonics in combination with III-V active optoelectronic devices. We present different practical examples of hybrid PICs, discuss associated design challenges and our approaches to their solution. We illustrate a smoothly elaborated common design workflow, which is based on standard simulation compact models and a layout-aware design approach. We demonstrate user-friendly optoelectronic circuit simulation, optimization and analysis, as well as performance verification on system-level.
Scalable PIC design: increasing yield of components, circuits and systems
James Pond - Lumerical
Tremendous progress has been made in recent years in PIC design and manufacturing. Nonetheless, manufacturing variations and the inevitable impact on yield remains a significant challenge. Active tuning can sometimes be a solution, but the necessary system complexity and power budgets can be prohibitive. We discuss design methods to maximize yield that account for a knowledge of design variations from specific foundry processes. These methods include inverse design approaches at the component level to large scale statistical simulation of circuits using calibrated compact models.
Open access integration platform: versatile solution for photonic integrated circuits
Luc Augustin - Smart Photonics
InP based photonic components have been around for some time and have proven to be a reliable source for communication systems. InP offers the possibility to monolithically integrate high performance active and passive components. These aspects, and the introduction of generic platforms: highly standardized industrial photonic integration processes that enable realization of a broad range of applications, will lead to a dramatic reduction of the development costs of PICs which will bring them within reach for many. This talk will address the integration platform from a foundry perspective: the integration technology, the opportunities and the scale-up to large volumes.
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Martijn Heck - ePIXfab – European Silicon Photonics Alliance
VCSELs in 3D facial recognition
David Cheskis - IQE
VCSEL technology and manufacturing capabilities have advanced dramatically in the last several years with the adoption of high volume applications. The establishment of 6-inch GaAs VCSEL manufacturing processes has opened the door to new opportunities – and provided new challenges. This presentation will discuss VCSEL manufacturing advances that have allowed the industry to scale fabrication to meet these challenges and provide more capacity than ever before. We will also introduce new Photonic Quasi-Crystal (PQC) technology that will enable additional photonic component integration directly onto VCSEL wafers.
Rethinking the photonics IC design flow to make high-quality PIC design easier, cheaper and faster
Ronald Broeke - BRIGHT Photonics
The Emergence of Non-Position Positioning in Fast Manufacturing Automation
Scott Jordan - Physik Instrumente
Requirements have escalated for perfect relative positioning of manufactured components. Examples: In Silicon Photonics, orientation of components to extreme tolerances is needed in multiple test and assembly steps. In Smartphone camera manufacturing, more elements are assembled to tighter tolerances with each generation. Previously this demanded exceptional dimensional control and fixturing, or painstaking positioning. But a new branch of intelligent control now provides fast, automatic, nanoscale-accurate orientation optimization in test and assembly. This improves process economics and yield by eliminating time-consuming steps and decoupling alignment from position metrology. The key is leveraging device optimization physics to reduce dependence on position commandability. A universal implementation is now commercially available and fab-proven. Process cost reductions of 99% are seen.
Large scale assembly and packaging foundry for PICs
Albert Hasper - Phix
PHIX mission is to become world leader foundry in packaging and assembly of Photonic Integrated Circuits (PIC’s) by supplying PIC based components and modules in scalable production volumes. PHIX photonics assembly is a new initiative to facilitate our customers in the assembly of all packaging challenges for PICs including product design for manufacturing. The talk will highlight the roadmap from pilot line production towards HVM-production. Key is to have the right capabilities and capacities needed to serve our customers. Further, automated tools and machines are needed to address the future needs, this will also be discussed
PICs Reimagined − Hybrids and Materials Innovation
Additive manufacturing by two-photon-polymerization for photonic integration
Jochen Zimmer - Nanoscribe
Two-photon-polymerization can be used for the direct printing of complex micro- and mesoscale 3D parts. These parts can be transparent, have optical-quality surfaces, and be printed on pre-structured surfaces such as PICs. Each part can be printed with parameters optimized for the individual assembly it is printed on. Thus, this technology offers an interesting way to integrate components from different sources.
Vertical integration in SiN based foundry enables new applications
Arne Leinse - LioniX International
The integration of Photonic Integrated Circuits (PICs) in functional modules enables endusers to use PICs in a variety of applications. Due to the hybrid integration of multiple platforms in a single module a variety of new applications can be addressed. For the silicon nitride based TriPleX platform these range from 5G to virtual reality and sensing. The main benefit is in the low loss properties over a large wavelength range enabling these different applications. In this talk we will show the capabilities of these modules and the necessity for vertical integration. It is all about module functionality and not about PICs.
Polymer PIC opportunities in Applications Beyond 100G
Michael Lebby - Lightwave Logic
New advances in Silicon Nitride (siN) PIC Applications
Michael Geiselmann - LIGENTEC
Silicon nitride photonic integrated circuits offer new possibilities for existing and emerging applications. Application such as Beamforming, Augmented Reality, Quantum and nonlinear integrated photonics and Bio-sensing benefit from a transparency window from the visible to the Mid-Infrared and the ultra-low losses in those wavelength ranges.
LIGENTEC's fabrication process is based on the all-nitride-core technology and designed from the bottom up for photonics and modularity. In the all-nitride-core, most of the optical mode energy is in the waveguide material, which reduces loss and makes small bending radii possible. Latest developments on further integration of active elements and modules are presented.
Optical passive device platform to enhance photonics performances
Arnaud Rigny - Teem Photonics
One optical component integration challenge is to bring together active and passive functions with very different technical constraints. Compromise is often hard to come on single technology platform making multi-platform solutions attractive. The glass platform is a solution of choice to make the optical link between source and fiber by integrating low-loss, temperature-stable passive interface solutions. Teem photonics, expert in ion exchange technology on glass ( IoNext ) , is developing an innovative solution providing a unique low-loss collective coupling technology integrating passive functions (taps, splitter, multiplexer, ... ), compatible with most of active photonic integration platforms (SiPh, PIC, SiN ...)
PIC ROI − Show Me the Money
Coherent DWDM router interfaces: Opportunities for photonic integration
Dirk Van Den Borne - Juniper
III-V Lasers directly grown on Silicon
Kei May Lau - Hong Kong University of Science & Technology
To support an energy-efficient optical interconnect technology enabled by silicon photonics, development of low-power-consumption active devices and associated integration technologies is needed. Most communication wavelength lasers with excellent device performance have been grown on III-V substrates and bonded to silicon. For monolithic integration, growth and fabrication of such lasers on III-V/ Si compliant substrates is another option. QDs grown on compliant III-V/Si substrates and laser characteristics of whispering-gallery-mode (WGM) micro-lasers, and conventional Fabry Perot lasers will be discussed. Another approach involves nano-ridge lasers with embedded quantum wells grown on stripe patterned on-axis Si substrates or SOI. Room temperature lasing inside nano-cavities at telecom bands is challenging and has only been demonstrated up to the E band. We have achieved InP/InGaAs nano-ridge lasers resulting in emission wavelengths ranging from the O-, E-, S- to C-band operating at room temperature with ultra-low lasing thresholds. These energy-efficient micro-lasers are excellent candidates for on-chip integration with silicon photonics.
Assessing the long-term growth and market potential for PIC devices in datacom, transport and networks
Eric Higham - Strategy Analytics
Historically, growth of optical markets was sinusoidal; periods of sharp contraction followed times of booming expansion in a repeating pattern. While the past was not for the faint of heart, recent performance shows that the optical market has gotten far less volatile, with a strong upward growth trajectory. This presentation will explore the shift in drivers for optical market growth and the trends for the future. It will also address the advantages and disadvantages of Photonic Integrated Circuits (PIC), their most likely applications and the use of compound semiconductor technologies in PICs, as well as the broader optical market.
PICs Beyond 100G − Evolution and Revolution
Driving the PIC Revolution, Case Scenarios
Twan Korthorst - Synopsys
Synopsys is driving the photonic integrated circuit (PIC) revolution with design automation solutions for a wide range of application requirements, from data communications to sensors and biomedical devices. Synopsys’ PIC Design Suite – which includes the OptSim Circuit and OptoDesigner tools – offers a seamless PIC design flow from concept to manufacturable design, as well as access to a single, world-class support channel.
Where are pluggable modules going?
Martin Zirngibl - Finisar
Currently all short and medium reach fiber optics communications are based on pluggable modules because they make systems easily serviceable and minimize upfront cost. However the ever increasing I/O capacity is a challenge to the pluggable model because of the power and footprint penalties that this architecture incurs. We will discuss fundamental limits and how PICs can help addressing them. We will also will review the pro and cons of co-packaged solutions where the pluggable modules are replaced by a direct optical link to the processor package.
The benefits of low-barrier access to new production services for PICs today and tomorrow
Jose Pozo - EPIC
The requirement for new technologies able to support faster, more efficient and less consuming devices has triggered the adoption of Photonic Integrated Circuits (PICs) for many different applications. The Pilot Lines in Photonics provide a fast service for prototyping and low-volume production of Photonic Integrated Circuits (PIC)-based products helping companies to reduce the time-to-market. The Pilot Lines, PIXAPP – for packaging and assembly PICs, MIRPHAB – for developing QCLs based chemical sensors, and PIX4LIFE – Si3N4 PICs for life sciences cover a wide range of applications from telecom to healthcare, including environmental monitoring and industrial sensing.
Photonic Integration Opportunities for Next-Generation Coherent High-Capacity Systems
Martin Guy - Ciena Corporation
Next-generation high-capacity optical coherent transmission systems at 400G and above will demand different set of requirements depending on the target applications. Long haul and ultra-long haul systems such as submarine and inter-continental links will have to be optimized for fiber capacity and reach. Shorter-reach applications such as metro, DCI and 5G access links will need low power and high density pluggable modules. From an optical components perspective, the right combination of photonic integration technologies will be mandatory to address all the stringent requirements related to bandwidth, size, power and cost. In this presentation, we will review the opportunities associated with InP and Silicon Photonics optical material platforms and photonic packaging technologies to address the challenges of next-generation high-capacity optical coherent transmission systems.
The critical role that EC support for photonics and PIC devices plays in our manufacturing future.
John Magan - European Commission Photonics Unit
Recognising the importance of photonics and PICs, the EU’s ICT research programme has worked with the photonics industry and research community to run a series of actions to build up a technology base in Europe, particularly in PIC manufacturing. This presentation will review these actions, consider the lessons learned, and look to further opportunities for support and the next research programme beyond 2020: Horizon Europe.
Presentation Title TBC
Nicolas Psaila - Optoscribe
Integrated Silicon Photonics for future Datacenter Applications
Thomas Liljeberg - Intel
The rapid growth in data center traffic is driving accelerating requirement to the bandwidth and performance of networking equipment, including optical interfaces and Ethernet switches. Looking ahead, bandwidth scalability challenges are looming in terms of density, cost, and power; challenges that require tighter integration of optics and networking silicon. We will review motivation for integration and the enabling technology elements, and discuss how co-packaged Silicon Photonics enables higher density, reduced power per bit, and ultimately the continued scalability of network bandwidth and performance.
Theme To Be Decided
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Speaker Name TBC - Luceda Photonics
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Ruth Houbertz - Multiphoton Optics
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Tyndall Presentation - Title TBC
Peter O'Brien - Tyndall
Presentation TBC - HPE
Di Liang - Hewlett Packard Enterprise
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