7:30am - 8:30am | Registration and Continental Breakfast |
8:30am - 8:45am | Welcome & Outlook - Jim Feldhan, Semico Research Corp. |
8:45am - 9:15am | Michael Gay, Isola -- Abstract |
9:15am - 9:45am | Daniel DeAraujo, Mentor Graphics -- Abstract |
9:45am - 10:15am | Break |
10:15am - 11:30am | Panel: How Do We Get to Next-Generation High Speed Data Transfer Rates? Moderator: Brian Fuller, ARM Lee Ritchey, Speeding Edge Scott McMorrow, Samtec Geoffrey Hazelett, Polar Instruments Daniel DeAraujo, Mentor Graphics Nathaniel Unger, Altera |
11:45am - 12:30pm | Lunch - Sponsored by Isola |
12:30pm - 1:30pm | Keynote: Chesley B. "Sully" Sullenberger, III |
Afternoon Session: Innovation Spotlight | |
1:30pm - 1:50pm | Robert L. Sankman, Intel -- Abstract |
1:50pm - 2:10pm | Margaret Schmitt, Ansys -- Abstract |
2:10pm - 2:30pm | Break |
2:30pm - 3:45pm | Panel: Boards, Chips & Packaging: Meeting Market Requirements Moderator: Mike Noonen, Ambiq Micro Jason Marsh, Insulectro Heidi Barnes, Keysight Technologies Nathapong Suthiwongsunthorn, Ph.D., UTAC Tom Whipple, Cadence |
3:45pm - 4:00pm | Closing Remarks |
Panel 1- How Do We Get to Next-Generation High Speed Data Transfer Rates?
The need for more bandwidth is continuing to drive the Internet infrastructure. Rapid growth of server, network and internet traffic is fueling the need for higher data rates. Key contributors to data demand include Internet consumer applications, cloud-based computing and storage, virtual servers, advances in scientific and financial computing and the Internet of Things. While fiber optic cables are capable of delivering data rates into terabits/sec, the main bottleneck continues to be the last critical mile solution. Deployment of FTTH (Fiber To The Home) and the emerging 60 GHz point-to-point microwave links, which enable Gb/s rates to the home, are seen as viable last mile solutions.
As a result:
The panel will be comprised of a Lee Ritchey, Speeding Edge; Scott McMorrow, Samtec; Geoffrey Hazelett, Polar Instruments; Daniel DeAraujo, Mentor Graphics; and a representative from Altera. Brian Fuller, ARM, will moderate this panel.
Panel 2- Boards, Chips & Packaging: Meeting Market Requirements
The Internet of Things promises an unprecedented opportunity for the electronics industry. From front-end devices like roadway sensors to back-end network equipment supporting the rush of new data inputs, electronics are the integral foundation of this new era. More than ever, pressure is on the electronics industry to deliver the right solution at the right time and at the right price.
Product design is the foundation for each successive stage of the product development process and every player in the electronics ecosystem feels the pressure from the interdependence each time a product hand off occurs. Delivering market tested electronics with precise designs demands coordination at all levels of product development. All players are recognizing the need to collaborate throughout the design process including chip design, package design, material selection and board design to solve problems they all face together.
Designers across the electronics ecosystem must come to the table to address issues such as:
Products are more complex than ever before, with unique design requirements ranging from high performance to low power. Well-defined product development specifications are critical to getting a product that performs right the first time. Collaboration involving each step of the process—from chip design, package design, material selection to board design—will help us all achieve our shared goal of delivering first-time-right products.
This panel will wrap up the event with insights and solutions that will help you implement successful product launches and grow your markets.
Autonomous Driving: Who’s Behind the Wheel?
The advanced driver assist systems applications used in current and future generation automobiles cover a broad spectrum of performance and feature enhancements. Elements currently in use today include a fusion of technologies such as: adaptive cruise control, collision avoidance, blind spot detection, lane departure warning, stop-and-go systems, side impact warning, cross traffic alert, evasion maneuver, pedestrian protection, front collision warning, proximity warning and parking assist functions. These systems use a variety of technologies at varying frequencies to achieve the specific system performance.
Currently systems operate in the 24 GHz and 77-81 GHz frequency spectrum and could very well exceed 100 GHz in the future as the technology evolves.
Autonomous driving is viewed as the next stop on the road to automotive innovation. The ultimate goal for these unique technologies is first and foremost safety, with the ultimate goal of assisting in achieving an autonomous driving experience.
Currently five technologies are considered to be essential enablers for autonomous driving, which include lidar, radar, sonar, optical and vehicle-to-vehicle communication systems. With the advantages associated with 77 - 81 GHz technology, these requirements may distill down to three essential technology platforms namely Radar, Optical and Vehicle-to-Vehicle communications.
These questions and more will be addressed by panel participants from an IC manufacturer, a major auto manufacturer, a material supplier and a Tier I auto supplier.
RF/Digital Hybrid boards
Advanced chip manufacturing technology and new design techniques have enabled the integration of RF chips with digital circuitry creating a RF/MW circuitry solution. Building boards using different dielectrics and routing digital wave forms and RF signals through specific layers enable a reduced footprint. Chip manufacturers are working to pack more and more functionality into the ICs resulting in a reduced number of features on the dielectric. All the attempts at integration are resulting in higher power density leading to requirements for higher power dissipation, lower thermal resistance and the need for stability of dielectric properties in regard to temperature and frequency. Further, the use of turbo coding and signal processing techniques has made the communication bandwidth approach the theoretical Shannon limit. This has led to focusing on increasing the bandwidth through smaller cells. These networks will be comprised of macro base stations coupled with smaller micro, Femto and Pico cells that form the heterogeneous networks, or Hetnet. Heterogeneous networks rely on very small cells which can cater to a group, office, building or a set of buildings. The communication is mainly digital and could be fed through point-to-point links or wireless links. The circuitry required is hybrid to a certain extent with RF or digital on the receiving or transmitting end. The reliability needs for such hybrid boards are driven by extremely tight pitches on the components leading to concerns relative to CAF, delamination, drilling, plating and other processes. These reliability requirements, coupled with the HDI designs and requirements for high heat dissipation, are making RF/high speed digital board manufacturing increasingly complex.
This panel will be comprised of RFIC manufacturers, wireless infrastructure manufacturers and board manufacturers that will address the challenges posed by these new hybrid, single-board requirements.
Phased Array Antenna Solutions
Conventional satellite communications require that a narrow radio frequency (RF) beam be directed on a receiver (usually a parabolic dish). If either the sender or the receiver is moved, the direction of the narrow beam must be kept by pointing the beam to the accurate position on the satellite. This positioning is achieved through the use of a motorized mechanical gimbal that moves the parabolic dish such that the beam remains focused on the satellite. In contrast, phased array antennas provide an enhanced level of performance by pointing or steering the beam from an array of fixed antennas eliminating the mechanical hardware and increasing the speed of movement. Increased performance characteristics of phased array antennas include:
This panel will discuss the hardware required for phased array antennas, the challenges in building them and the future potential of the antennas.
For more information contact:
Jim Feldhan
602-997-0337 Opt #1
jimf@semico.com
Joanne Itow
602 997-0337 Opt #2
joannei@semico.com
Kella Knack
707-328-6865
kjspeedingedge@cs.com