Category Archives: Packaging and Testing

MEMSIC announced the launch of its latest addition, the INS380, to its portfolio of Inertial Systems enabled with SmartSensing technology targeted to a broad range of precision motion sensing applications. The portfolio offering consists of Inertial Measurement Units (IMU), Vertical Gyros (VG), Attitude and Heading Reference Systems (AHRS), Inertial Navigation Systems (INS) and Tilt measurement systems in a variety of packages suited for system designers to end equipment manufacturers.

The latest product from MEMSIC, the INS380SA, is a complete inertial navigation system with a built-in 48-channel GPS receiver. The SmartSensing technology enables a turnkey system with better than 0.01 m/s velocity measurement accuracy. The integrated 3-axis magnetometer allows for accurate operation when the GPS signal is lost or when the vehicle comes to a stop.

SmartSensing technology provides users with sensor fusion and performance in critical motion sensing applications. SmartSensing combines enhanced and patented Kalman-based algorithm with proprietary temperature, motion and alignment calibration for consistent and high accuracy performance over a wide range of extreme operating conditions. Applications include unmanned ground and aerial vehicles, platform stabilization, avionics, precision agriculture, construction, and more.

“With over 400 man-years of design and development experience and knowledge in designing IMUs and sophisticated MEMS sensor solutions,” said Masoud Beheshti, VP and General Manager of MEMSIC’s system division. “MEMSIC is in a very unique position in the industry to help enable designer’s unprecedented size, accuracy and cost, with our SmartSensing technology.”

Suppliers of MEMS-based devices rode a safety sensing wave in 2014 to reach record turnover in automotive applications, according to analysis from IHS, the global source of critical information and insight.

Mandated safety systems such as Electronic Stability Control (ESC) and Tire Pressure Monitoring Systems (TPMS) – which attained full implementation in new vehicles in major automotive markets last year – are currently driving revenues for MEMS sensors. Those players with strong positions in gyroscopes, accelerometers and pressure sensors needed in these systems grew as well, while companies in established areas like high-g accelerometers for frontal airbags and pressure sensors for side airbags also saw success.

Major suppliers of pressure sensors to engines similarly blossomed – for staple functions like manifold absolute air intake and altitude sensing – but also for fast-growing applications like vacuum brake boosting, gasoline direct injection and fuel system vapor pressure sensing.

Bosch was the overall number one MEMS supplier with US$790 million of devices sold last year, close to three times that of its nearest competitor, Sensata (US$268 million). Bosch has a portfolio of MEMS devices covering pressure, flow, accelerometers and gyroscopes, and also has a leading position in more than 10 key applications. The company grew strongly in ESC and roll-over detection applications, and key engine measurements like manifold absolute pressure (MAP) and mass air flow on the air intake, vacuum brake booster pressure sensing and common rail diesel pressure measurement.

Compared to 2013, Sensata jumped to second place in 2014 ahead of Denso and Freescale, largely on strength in both safety and powertrain pressure sensors, but also through its acquisition of Schrader Electronics, which provides Sensata with a leading position among tire pressure-monitoring sensor suppliers.

While Sensata is dominant in TPMS and ESC pressure sensors, it also leads in harsh applications like exhaust gas pressure measurement. Freescale, on the other hand, is second to Bosch in airbag sensors and has made great strides in its supply of pressure sensors for TPMS applications.

Despite good results in 2014, Denso dropped two places compared to its overall second place in 2013, largely as a result of the weakened Yen. Denso excelled in MAP and barometric pressure measurement in 2014, but also ESC pressure and accelerometers. Denso has leadership in MEMS-based air conditioning sensing and pressure sensors for continuous variable transmission systems, and is also a supplier of exhaust pressure sensors to a major European OEM.

Secure in its fifth place, Analog Devices was again well positioned with its high-g accelerometers and gyroscopes in safety sensing, e.g. for airbag and ESC vehicle dynamics systems, respectively.

The next three players in the top 10, in order, Infineon, Murata and Panasonic, likewise have key sensors to offer for safety. Infineon is among the leading suppliers of pressure sensors to TPMS systems, while Murata and Panasonic serve ESC with gyroscope and accelerometers to major Tier Ones.

The top 10 represents 78 percent of the automotive MEMS market volume, which reached $2.6 billion in 2014. By 2021, this market will grow to $3.4 billion, a CAGR of 3.4 percent, given expected growth for four main sensors — pressure, flow, gyroscopes and accelerometers.  In addition, night-vision microbolometers from FLIR and ULIS and humidity sensors from companies like Sensirion and E+E Elektronik for window defogging will also add to the diversity of the mix in 2021.

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DLP chips from Texas Instruments for advanced infotainment displays will similarly bolster the market further in future. More details can be found in the IHS Technology H1 2015 report on Automotive MEMS.

Read more: 

What’s next for MEMS?

Growing in maturity, the MEMS industry is getting its second wind

CEA-Leti plays a role in the development of the Internet of Things as a provider of key underlying technologies that help its partners take advantage of the opportunities the IoT will offer. These technologies include new sensors, energy-harvesting systems, ultra-low-power communication technologies and ultra-low-power digital processors.

Building on this foundation, the 17th annual LetiDays Grenoble on June 24-25 will expand the conversation with presentations about Internet of Things-augmented mobility, which is revolutionizing the way we interact with appliances, infrastructure and countless common objects that are part of our daily lives.

Another conference theme that includes the IoT and broader markets is Leti’s breakthroughs in silicon technologies, sensors, telecommunications, power management in wearable systems, health applications, transportation and cities of the future. We will focus on how to bring increases in performance, efficiency and security to these fields and markets.

The two-day event will feature more than 40 conferences, many networking opportunities, plus showroom and exhibition halls.

Speakers include:

  • Leti CEO Marie-Noëlle Semeria
  • Suresh Venkatesan, SVP technology development, GLOBALFOUNDRIES
  • Jean-Pierre Cojan, Director, Strategy and Transformation, Safran and
  • Christophe Fourtet, Chief Science Officer and co-founder, SIGFOX. 

In addition, Prof. Alim Louis Benabid will give a keynote address on June 24 at 6 pm. Benabid is a neurosurgeon and board chairman of the Edmond J. Safra Biomedical Research Center Clinatec on the Minatec campus in Grenoble. He has won multiple awards for his pioneering work in the treatment for Parkinson’s disease, including the Albert-Lasker Prize in 2014 and the Breakthrough Prize in Life Sciences in 2015.

Leti also will host technology workshops during the week of June 22:

Xcerra Corporation today announced that Nordic Semiconductor, a company that specializes in ultra-low power (ULP) 2.4GHz transceivers, notably for the Bluetooth Smart and wearables segments, has selected the Diamondfrom Xcerra’s semiconductor tester group, LTX-Credence, for high volume production test of their Internet of Things (IoT) products. Nordic will use the Diamondx in combination with NighthawkCT, an industry leading instrument for low cost RF test of connectivity devices.

“We are delighted to once again see LTX-Credence come out of this type of benchmarking exercise with the best overall fit for our testing needs,” notes Ole-Fredrik Morken, Supply Chain Director at Nordic Semiconductor, and adds, “While our strategy in this arena is mainly driven by a requirement for highest possible throughput per test cell, we also value a long-term relationship with LTX-Credence and their consistent focus on providing best-in-class test solutions for our product segment. We are currently running high volume production on Diamondx systems at multiple OSATs in Asia.”

Frank Berntsen, Chief Scientist at Nordic, commented, “After analyzing the data we determined that the Diamondx and NighthawkCT configuration features a superior combination of instrument performance, infrastructure speed and allows for a significant increase in parallel test. This is critically important for us as the application of Bluetooth Smart and emerging technologies for all types of IoT and wearables will further fuel Nordic’s growth, driving the need for high volume, low cost test solutions.”

Steve Wigley, vice president of the semiconductor tester group at Xcerra Corporation commented, “The growth in IoT applications is expected to be a major contributor to semiconductor unit volumes over the next several years. The combination of Diamondx and NighthawkCT was specifically designed to offer a new level of test capability for these types of applications. This new level of capability provides RF connectivity performance testing, as well as, a significantly reduced cost of testing RF enabled devices used in IoT applications. This is one of the drivers of the large installed base of Diamondx systems at the major OSATs. The selection of Diamondx and NighthawkCT for high volume production test by a key IoT player such as Nordic validates that our test solutions are well aligned to the needs of these fast growing applications.”

In 2014, the MEMS sector represented an $11.1B business for Si-based devices. According to Yole Développement (Yole) latest MEMS report “Status of the MEMS Industry”, the MEMS industry is preparing to exceed $20B by 2020.

“We have seen different market leaders in the past and the competition is still very open,” said Jean-Christophe Eloy, President & CEO, Yole. “But 2014 will be remembered for the emergence of what could be a future “MEMS Titan”: Robert Bosch (Bosch),” he added.

Under this new analysis entitled, “Status of the MEMS Industry” report Yole proposes a deep understanding of the MEMS markets trends and players dynamics. The More than Moore market research and strategy consulting company announces its 2014 MEMS manufacturers and foundries ranking and proposes an overview of the future game-changers including new devices, disruptive technologies, 300mm wafers, sensor fusion and new markets.

mems market forecast

Bosch’s MEMS revenues have increased by 20 percent to top $1.2B, driven by consumer sales. STMicroelectronics’ revenue is thus now lagging $400M behind. Compared to 2013, the top five companies remain unchanged and together they earn $3.8B, around a third of the total MEMS business. However, Bosch’s dominance is clear, as its revenues now account for around one-third of that figure. Among the 10 or so MEMS titans that are currently sharing most of the MEMS market, Yole distinguishes the “Titans with Momentum” from the “Struggling Titans”

Titans with Momentum group includes Bosch, InvenSense and others.

“Bosch’s case is particularly noteworthy as it is today the only MEMS company in dual markets – namely automotive and consumer – that has the right R&D/production infrastructure,” said Dr Eric Mounier, Senior Technology & Market Analyst, MEMS devices & Technology at Yole.

STMicroelectronics, Texas Instruments, Knowles, Denso and Panasonic are part of the second group, “Struggling Titans.” These companies are currently struggling to have an efficient value growth engine.

A third family is the upcoming “Baby Titans” like Qorvo and Infineon that have grown significantly in the past couple of years and could become serious MEMS players.

Yole has analyzed the three “Brick Walls” players have to overcome to develop a significant MEMS business. The first is to launch a first MEMS product on the market. The second is moving from one to multiple MEMS product lines to diversify a company’s portfolio. The last is the move from being a device maker to a system maker with a successful MEMS business. So far, only Bosch has achieved a very successful transition.

Yole also announces: “New MEMS devices are emerging.” Under its analysis, the consulting company considers gas and chemical sensors. Such devices are based on semiconductor technologies. But MEMS is a further improvement that can reduce size by half or more and also cut costs, thus opening up new opportunities. According to Yole’s analysis, MEMS-based gas sensors will be increasingly used in applications with formfactor/cost issues, particularly in wearables and then consumer applications such as smartphones.

Another example is MEMS micro mirrors. Yole explains: “They are attracting new interest from the market for optical datacom, with Calient achieving impressive growth, or human-machine interfaces, as demonstrated by Intel’s acquisition of Lemoptix.”

Under its analysis on the MEMS & Sensors industry, Yole and its team took the opportunity to exchange with Jeanne Forget, Global Marketing Director, Bosch Sensortec and Dr Frank Schafer, Senior Manager of product management for automotive micro-electro-mechanical sensors (MEMS) at Robert Bosch on the evolution of the MEMS markets and the ability of Bosch, in the last 20 years and for the next decade, to build and maintain its unique leadership on MEMS industry. Full discussion is available on i-micronews.com, MEMS & Sensors news.

MEMS Industry Group (MIG), the trade association advancing micro-electromechanical systems (MEMS) and sensors across global markets, today announced the creation of a new TSensors division headed by TSensors Summit, Inc. Founder Dr. Janusz Bryzek. MIG’s new division will extend TSensors Summit’s visionary efforts to accelerate a world in which everyone has access to “Abundance” — food, safe water, clean air, healthcare and other vital resources — through the foundational use of sensors and MEMS.

“TSensors has proven itself to be vibrant and incredibly innovative, with initiatives designed to positively change the human experience through the widespread adoption of sensors,” said Karen Lightman, executive director, MEMS Industry Group. “Clearly this is an ambitious goal — but with the success of past TSensors Summits, combined with MIG’s global membership base and organizational structure, I am confident that this goal has a greater potential for realization. We are thrilled to welcome Janusz Bryzek and the TSensors community to MIG. Together we aim to realize the vision of trillions of sensors improving the quality of people’s lives.”

“One of the greatest strengths of TSensors Summit has been our visionary speakers, who have given TED-like talks while outlining an amazing future enabled by new sensor-based systems,” said Dr. Janusz Bryzek, TSensors Summit founder, now heading MIG’s TSensors division. “By joining MEMS Industry Group — with its depth in promoting MEMS commercialization — we will be able to increase the momentum and breadth of TSensors’ initiatives. This will help to both accelerate solutions to major global problems through the use of sensor-based systems as well as to bring unprecedented business opportunities to member companies involved in the design and production of sensor-related products and services.”

TSensors Summit – a MEMS Industry Group® Enterprise will take place on December 9-10, 2015 in Orlando, FL.

Intel Corporation today announced plans to develop integrated products with eASIC Corporation that combine processing performance and customizable hardware to meet the increasing demand for custom compute solutions for data centers and the “cloud.” The new parts will enable acceleration of up to two times that of a field programmable gate array (FPGA) for workloads like security and big data analytics while also speeding the time to market for custom application specific integrated circuit (ASIC) development by as much as 50 percent.

The tremendous growth of cloud computing has spurred greater demand for customized chips that make a particular application or workload run faster. To enable this, eASIC plans to integrate its eASIC platform technology with future Intel Xeon processors, providing cloud service providers a highly customized, integrated hardware solution for their particular workload.

eASIC’s technology can increase flexibility and fast-time-to-market when compared to traditional ASICs and increase performance and lower power consumption when compared to FPGAs. By integrating hardware accelerator solutions with the eASIC platform, Intel can deliver much faster and more flexible systems for cloud customers.

“Having the ability to highly customize our solutions for a given workload will not only make the specific application run faster, but also help accelerate the growth of exciting new applications like visual search,” said Diane Bryant, senior vice president and general manager of Intel’s Data Center Group. “This announcement helps broaden our portfolio of customized products to provide our customers with the flexibility and performance they need.”

This collaboration is part of Intel’s strategy to integrate reprogrammable technology with Intel Xeon processors to greatly improve performance, power and cost.

“We believe our eASIC technology has unique characteristics that will benefit cloud service providers to get the most from their applications,” said Ronnie Vasishta, president and chief executive office at eASIC. “The combination of eASIC and Intel technology will help bring break through cost and performance to our customers.”

SEMI has announced that executives from MEMS giants Bosch and STMicroelectronics, MEMS largest fabless Invensense and dominating IC foundry TSMC will be delivering the keynote talks at the European MEMS Summit (Sept 17-18, 2015 – Milan, Italy).

For the first installment of SEMI’s European MEMS Summit, themed “Sensing the Planet, MEMS for Life,” Stefan Finkbeiner, GM and CEO of Bosch Sensortec, Benedetto Vigna, Executive VP and General Manager of the Analog, MEMS & Sensors group of STMicroelectronics, Behrooz Abdi, CEO and President of Invensense, and Maria Marced, President of TSMC Europe will join SEMI to share their vision of the current challenges facing the MEMS industry and their recipes for success. With these headliners, SEMI’s European MEMS Summit promises to be a powerhouse of MEMS experts, both from a technological standpoint and from a business standpoint.

“We are very excited to offer attendees a high-profile collection of international speakers for this first edition of our European MEMS Summit,” commented Yann Guillou, business development manager at SEMI. “Elaborated with the support of industry representatives, we have made an effort to address the most crucial industry issues with the belief that this conference program will be a positive contribution to the MEMS industry and will help MEMS actors collectively shape their industry’s progress. Above all, our hope is that attendees will leave the Summit with a better understanding of the crucial technological and business challenges faced by the MEMS value chain as well as an idea of the solutions that are being proposed today to address those problems.”

The Summit’s conference will bring together a diversity of high caliber MEMS technology experts, including representatives of ARM, ASE Group, CEA-Leti, Freescale, IHS, Infineon, SITRI, Tronics Microsystems, X-FAB, Yole Développement and more. The event will insist on the importance of understanding the dynamics of the marketplace in perpetuating a global comprehension of the evolution of MEMS. Speakers will provide their outlooks on the MEMS market, their expectations for future marketplace trends and their assessment of the changes in business models, the supply chain, and the ecosystem. One full day of the event will be dedicated to “Applications” to give attendees a more global vision of how MEMS are being applied in the automotive, consumer electronics, wearable and industrial sector as well as the importance of MEMS in the growth of the Internet of Things. Despite a strong focus on business-related aspects, technology will not be forgotten; speakers will address topics such as new detection principles, innovation in materials, new packaging solutions, MEMS on 300mm wafers and more.

The Summit will be held at the grandiose Palazzo Lombardia, in Milan, Italy. At the heart of the Palazzo and in complement to the conference, SEMI will organize a MEMS Exhibition, giving companies with MEMS activities a chance to reach out to other participants who are coming from the same sector. The European MEMS Summit will include numerous networking opportunities – a gala dinner, a networking cocktail hour and numerous coffee and lunch breaks.

For any question regarding the event, contact Yann Guillou from SEMI ([email protected]).

Interconnecting transistors and other components in the IC, in the package, on the printed circuit board and at the system and global network level, are where the future limitations in performance, power, latency and cost reside.

BY BILL CHEN, ASE US, Sunnyvale, CA; BILL BOTTOMS, 3MT Solutions, Santa Clara, CA, DAVE ARMSTRONG, Advantest, Fort Collins, CO; and ATSUNOBU ISOBAYASHI, Toshiba Kangawa, Japan.

Heterogeneous Integration refers to the integration of separately manufactured components into a higher level assembly that in the aggregate provides enhanced functionality and improved operating characteristics.

In this definition components should be taken to mean any unit whether individual die, MEMS device, passive component and assembled package or sub‐system that are integrated into a single package. The operating characteristics should also be taken in its broadest meaning including characteristics such as system level cost-of-ownership.

The mission of the ITRS Heterogeneous Integration Focus Team is to provide guidance to industry, academia and government to identify key technical challenges with sufficient lead time that they do not become roadblocks preventing the continued progress in electronics that is essential to the future growth of the industry and the realization of the promise of continued positive impact on mankind. The approach is to identify the require- ments for heterogeneous integration in the electronics industry through 2030, determine the difficult challenges that must be overcome to meet these requirements and, where possible, identify potential solutions.

Background

The environment is rapidly changing and will require revolutionary changes after 50 years where the change was largely evolutionary. The major factors driving the need for change are:

  • We are approaching the end of Moore’s Law scaling.
  • The emergence of 2.5D and 3D integration techniques
  • The emerging world of Internet of Everything will cause explosive growth in the need for connectivity.
  • Mobile devices such as smartphones and tablets are growing rapidly in number and in data communications requirements, driving explosive growth in capacity of the global communications network.
  • Migration of data, logic and applications to the cloud drives demand for reduction in latency while accommodating this network capacity growth.

Satisfying these emerging demands cannot be accomplished with the current electronics technology and these demands are driving a new and different integration approach. The requirements for power, latency, bandwidth/bandwidth density and cost can only be accomplished by a revolutionary change in the global communications network, with all the components in that network and everything attached to it. Ensuring the reliability of this “future network” in an environment where transistors wear out, will also require innovation in how we design and test the network and its components.

The transistors ‘power consumption in today’s network account for less than 10 percent of total power, total latency and total cost. It is the interconnection of these transistors and other components in the IC, in the package, on the printed circuit board and at the system and global network level, where the future limitations in performance, power, latency and cost reside. Overcoming these limitations will require heterogeneous integration of different materials, different devices (logic, memory, sensors, RF, analog, etc.) and different technologies (electronics, photonics, plasmonics, MEMS and sensors). New materials, manufacturing equipment and processes will be required to accomplish this integration and overcome these limitations.

Difficult challenges

The top‐level difficult challenges will be the reduction of power per function, cost per function and latency while continuing the improvements in performance, physical density and reliability. Historically, scaling of transistors has been the primary contributor to meeting required system level improvements. Heterogeneous integration must provide solutions to the non‐transistor infrastructure that replace the shortfall from the historical pace of progress we have enjoyed from scaling CMOS. Packaging and test have found it difficult to scale their performance or cost per function to keep pace with transistors and many difficult challenges must be met to maintain the historical pace of progress.

In order to identify the difficult challenges we have selected seven application areas that will drive critical future requirements to focus our work. These areas are:

  • Mobile products
  • Big data systems and interconnect
  • The cloud
  • Biomedical products
  • Green technology
  • Internet of Things
  • Automotive components and systems

An initial list of difficult challenges for Heterogeneous Integration for these application areas is presented in three categories; (1) on‐chip interconnect, (2) assembly and packaging and (3) test. These are analyzed in line with the roadmapping process and will be used to define the top 10 challenges that have the potential to be “show stoppers” for the seven application areas identified above.

On-chip interconnect difficult challenges

The continued decrease in feature size, increase in transistor count and expansion into 3D structures are presenting many difficult challenges. While challenges in continuous scaling are discussed in the “More Moore” section, the difficult challenges of interconnect technology in devices with 3D structures are listed here. Note that this assumes a 3D structure with TSV, optical interconnects and passive devices in interposer substrates.

ESD (Electrostatic Discharge): Plasma damage on transistors by TSV etching especially on via last scheme. Low damage TSV etch process and the layout of protection diodes are the key factors.

CPI (Chip Package Interaction) Reliability [Process]: Low fracture toughness of ULK (Ultra Low‐k) dielectrics cause failures such as delamination. Material development of ULK with higher modulus and hardness are the key factors.

CPI (Chip Package Interaction) Reliability [Design]: A layout optimization is a key for the device using Cu/ULK structure.

Stress management in TSV [Via Last]: Yield and reliability in Mx layers where TSV land is a concern.

Stress management in TSV [Via Middle]: Stress deformation by copper extrusion in TSV and a KOZ (Keep Out Zone) in transistor layout are the issues.

Thermal management [Hot Spot]: Heat dissipation in TSV is an issue. An effective homogenization of hot spot heat either by material or layout optimization are the key factors.

Thermal management [Warpage]: Thermal expansion management of each interconnect layer is necessary in thinner Si substrate with TSV.

Passive Device Integration [Performance]: Higher Q, in other words, thicker metal lines and lower tan dielectrics is a key for achieving lower power and lower noise circuits.

Passive Device Integration [Cost]: Higher film and higher are required for higher density and lower footprint layout.

Implementation of Optical Interconnects: Optical interconnects for signaling, clock distribution, and I/O requires development of a number of optical components such as light sources, photo detectors, modulators, filters and waveguides. On‐chip optical interconnects replacing global inter- connects requires the breakthrough to overcome the cost issue.

Assembly and packaging difficult challenges

Today assembly and packaging are often the limiting factors in performance, size, latency, power and cost. Although much progress has been made with the introduction of new packaging architectures and processes, with innovations in wafer level packaging and system in package for example, a significantly higher rate of progress is required. The complexity of the challenge is increasing due to unique demands of heterogeneous integration. This includes integration of diverse materials and diverse circuit fabric types into a single SiP architecture and the use of the 3rd dimension.

Difficult packaging challenges by circuit fabric

  • Logic: Unpredictable hot spot locations, high thermal density, high frequency, unpredictable work load, limited by data bandwidth and data bottle‐necks. High bandwidth data access will require new solutions to physical density of bandwidth.
  • Memory: Thermal density depends on memory type and thermal density differences drive changes in package architecture and materials, thinned device fault models, test & redundancy repair techniques. Packaging must support low latency, high bandwidth large (>1Tb) memory in a hierar- chical architecture in a single package and/or SiP).
  • MEMS: There is a virtually unlimited set of requirements. Issues to be addressed include hermetic vs. non‐hermetic, variable functional density, plumbing, stress control, and cost effective test solutions.
  • Photonics: Extreme sensitivity to thermal changes, O to E and E to O, optical signal connections, new materials, new assembly techniques, new alignment and test techniques.
  • Plasmonics: Requirements are yet to be determined, but they will be different from other circuit type. Issues to be addressed include acousto‐ magneto effects and nonlinear plasmonics.
  • Microfluidics: Sealing, thermal management and flow control must be incorporated into the package.

Most if not all of these will require new materials and new equipment for assembly and test to meet the 15 year Roadmap requirements.

Difficult packaging challenges by material

Semiconductors: Today the vast majority of semiconductor components are silicon based. In the future both organic and compound semiconductors will be used with a variety of thermal, mechanical and electrical properties; each with unique mechanical, thermal and electrical requirements.

Conductors: Cu has replaced Au and Al in many applications but this is not good enough for future needs. Metal matrix composites and ballistic conductors will be required. Inserting some of these new materials will require new assembly, contacting and joining techniques.

Dielectrics: New high k dielectrics and low k dielectrics will be required. Fracture toughness and interfacial adhesion will be the key parameters. Packaging must provide protection for these fragile materials.

Molding compound: Improved thermal conductivity, thinner layers and lower CTE are key requirements.

Adhesives: Die attach materials, flexible conductors, residue free materials needed o not exist today.

Biocompatible materials: For applications in the healthcare and medical domain (e.g. body patches, implants, smart catheters, electroceuticals), semiconductor‐based devices have to be biocompatible. This involves the integration of new (flexible) materials to comply with specific packaging (form factor) requirements.

Difficult challenges for the testing of heterogeneous devices

The difficulties in testing heterogeneous devices can be broadly separated into three categories: Test Quality Assurance, Test Infrastructure, and Test Design Collaboration.

Test quality assurance needs to comprehend and place achievable quality and reliability metrics for each individual component prior to integration, in order to meet the heterogeneous system quality and reliability targets. Assembly and test flows will become inter- twined and interdependent. They need to be constructed in a manner that maintains a cost effective yield loss versus component cost balance and proper component fault isolation and quantification. The industry will be required to integrate components that cannot guarantee KGD without insurmountable cost penalties and this will require integrator visible and accessible repair mechanisms.

Test infrastructure hardware needs to comprehend multiple configurations of the same device to enable test point insertion at partially assembled and fully assembled states. This includes but is not limited to different component heights, asymmetric component locations, and exposed metal contacts (including ESD challenges). Test infrastructure software needs to enable storing and using volume test data for multiple components that may or may not have been generated within the final integrators data domains but are critical for the final heterogeneous system functionality and quality. It also needs to enable methods for highly granular component tracking for subsequent joint supplier and integrator failure analysis and debug.

Test design collaboration is one of the biggest challenges that the industry will need to overcome. It will be a requirement for heterogeneous highly integrated highly functional systems to have test features co‐designed across component boundaries that have more test coverage and debug capability than simple boundary scans. The challenge
of breaking up what was once the responsibility of a wholly contained design for test team across multiple independent entities each trying to protect IP, is only magnified by the additional requirement that the jointly developed test solutions will need to be standardized across multiple competing heterogeneous integrators. Industry wide collaboration on and adherence to test standards will be required in order to maintain cost and time effective design cycles for highly desired components that traditionally has only been required for cross component boundary communication protocols.

The roadmapping process

The objective of ITRS 2.0 for heterogeneous integration is to focus on a limited number of key challenges (10) that have the greatest potential to be “show stoppers,” while leaving other challenges identified and listed but without focus on detailed technical challenges and potential solutions. In this process collaboration with other Focus Teams and Technical Working Groups will be a critical resource. While we will need collaboration with other groups both inside and outside the ITRS some of the collaborations are critical for HI to address its mission. FIGURE 1 shows the major internal collaborations in three categories.

FIGURE 1. Collaboration priorities.

FIGURE 1. Collaboration priorities.

We expect to review these key challenges and our list of other challenges on a yearly basis and make changes so that our focus keeps up with changes in the key challenges. This will ensure that our efforts remain focused on the pre‐competitive technologies that have the greatest future value to our audience. There are four phases in the process detailed below.

1. Identify challenges for application areas: The process would involve collaboration with other focus teams, technical TWGs and other roadmapping groups casting a wide net to identify all gaps and challenges associated with the seven selected application areas as modified from time to time. This list of challenges will be large (perhaps hundreds) and they will be scored by the HI team by difficulty and criticality.

2. Define potential solutions: Using the scoring in phase (1) a number (30‐40) will be selected to identify potential solutions. The remainder will be archived for the next cycle of this process. This work will be coordinated with the same collabo- ration process defined above. These potential solutions will be scored by probable success and cost.

3. Down select to only the 10 most critical challenges: The potential solutions with the lowest probability of success and highest cost will have the potential to be “show stopping” roadblocks. These will be selected using the scoring above and the focus issues for the HI roadmap. The results of this selection process will be commu- nicated to the relevant collaboration partners for their comments.

4. Develop a roadmap of potential solutions for “show stoppers”: The roadmap developed for the “show stopping” roadblocks shall include analysis of the blocking issue and identification of a number of potential solutions. The collaboration shall include detail work with other units of the ITRS, other roadmapping activity such as the Jisso Roadmap, iNEMI Roadmap, Communications Technology Roadmap from MIT. We are continuing to work with the global technical community: industry, research institutes and academia, including the IEEE CPMT Society.

The blocking issues will be specifically investigated by the leading experts within the ITRS structure, academia, industry, government and research organizations to ensure a broad based understanding. Potential solutions will be identified through a similar collaboration process and evaluated through a series of focused workshops similar to the process used by the ERD iTWG. This process is a workshop where there is one proponents and one critic presenting to the group. This is followed by a discussion and a voting process which may have several iterations to reach a consensus.

The cross Focus Team/TWG collaboration will use a procedure of iteration to converge on an understanding of the challenges and potential solutions that is self‐ consistent across the ITRS structure. An example is illustrated in FIGURE 2.

FIGURE 2. Iterative collaboration process

FIGURE 2. Iterative collaboration process

It is critically important that our time horizon include the full 15 years of the ITRS. The work to anticipate the true roadblocks for heterogeneous integration, define potential solutions and implement a successful solution may require the full 15 years. Among the tables we will include 5 year check points of the major challenges for the key issues of cost, power, latency and bandwidth. In order for this table to be useful we will face the challenge of identifying the specific metric or metrics to be used for each application driver as we prepare the Heterogeneous Integration roadmap chapter for 2015 and beyond.

BILL CHEN is a senior technical advisor for ASE US, Sunnyvale, CA; BILL BOTTOMS is President and CEO of 3MT Solutions, Santa Clara, CA, DAVE ARMSTRONG is director of business development at Advantest, Fort Collins, CO; and ATSUNOBU ISOBAYASHI works in the Toshiba’s Center for Semiconductor Research & Development, Kangawa, Japan.

SIGFOX and Texas Instruments (TI) announced the two companies are working together to increase IoT deployments using the Sub-1 GHz spectrum. Customers can use the SIGFOX network with TI’s Sub-1 GHz RF transceivers to deploy wireless sensor nodes that are lower cost and lower power than 3G/cellular connected nodes, while providing long-range connectivity to the IoT.

Targeting a wide variety of end-user applications, including environmental sensors, smart meters, agriculture and livestock sensors, asset tracking and smart cities, the SIGFOX and TI collaboration maximizes the many benefits of narrowband radio technology and reduces barriers to entry for manufacturers wanting to connect their products to the cloud. Using the SIGFOX infrastructure reduces the cost and effort to get sensor data to the cloud and TI’s Sub-1 GHz technology provides years of battery life for less maintenance and up to 100 km range.

“TI’s Sub-1 GHz technology is an excellent fit for the SIGFOX network, because it supports long-range and high-capacity connectivity in a system-cost-optimized way that users everywhere require to fully benefit from the potential of the Internet of Things,” said Stuart Lodge, executive vice president of global sales at SIGFOX. “TI technology that leverages our ultra-narrowband technology is a powerful endorsement and will be a key part of our rapid network deployment in key global markets.”

SIGFOX’s two-way network is based on an ultra-narrowband (UNB) radio technology for connecting devices, which is key to providing a scalable, high-capacity network with very low energy consumption and unmatched spectral efficiency. That is essential in a network that will handle billions of messages daily.

“Narrowband technology is the superior option for a global Internet of Things network, because it offers the lowest-cost, most energy-efficient connectivity, along with the data capacity and robust coexistence, that competing technologies just cannot match,” said Oyvind Birkenes, general manager, Wireless Connectivity Solutions, TI. “We are excited to be working with SIGFOX to expand their network deployments and bring the benefits of narrowband Sub-1 GHz technology to users worldwide.”

TI’s CC1120 Sub-1 GHz RF transceiver uses narrowband technology to deliver the longest-range connectivity and superior coexistence to SIGFOX’s network with strong tolerance of interference. Narrowband is the de-facto standard for long-range communication due to the high spectral efficiency, which is critical to support the projected high growth of connected IoT applications. The CC1120 RF transceiver also provides years of battery lifetime for a sensor node, which reduces maintenance and lowers the cost of ownership for end users.