Semiconductor IP News and Trends Blog
Moore’s Cycle, Fifth Horseman, Mixed Signals, and IP Stress
What do all of these things have in common? They were key topics addressed by Cadence, Samsung, and others at CDNLive 2013.
What does Cadence see as future trends and challenges facing the semiconductor, EDA, and IP industries? To answer this question, I attended CDNLive2013, the company’s event for users, developers, and customers. Here are the highlights from that trip:
1. System to Silicon Verification – How It All Fits Together by Frank Schirrmeister, Group Director for Product Marketing of the System Development Suite at Cadence and blogger on the System Level Design community:
By 2015, the majority of system-on-a-chip (SoC) designs will be implemented at geometries below 90 nm. There will be fewer design starts, but each will have over 110 IP blocks with more than 70% reuse. Software will continue to dominate design activity, taking over 60% of the work effort. Software will be distributed over the entire SoC. Low power will remain a driving design constraint. SoCs will contain an ever-increasing amount of analog/mixed-signal (AMS) circuitry.
Schirrmeister discussed the challenges of sensor networks used to monitor the health of cows (bovine) in the field as but one example of the variety of mixed-signal applications. This particular design was based on the ARM Cortex MO microcontroller.
Schirrmeister noted that EDA companies have had to expand their coverage into the larger system market, thanks to changes in the semiconductor supply chain. Around 2000, the industry was very fragmented (i.e., mobile chip and IP vendors worked with handset makers, who then partnered with operating-system suppliers and finally network operators). The next 12 years resulted in various combinations of subsystem integration – the result being that EDA and IP companies like Cadence must provide software (drivers and firmware for now) to their customers. In other words, the definition of the EDA-IP “system” continues to evolve.
2. Interview about mixed-signal technology trends with Mladen Nizic, Engineering Director for Mixed Signal Solutions, and Dave DeMaria, Ecosystem Alliances, Worldwide Field Operations:
The growth of the mobile market – including wireless, networking, storage, and computing – requires integrated analog/mixed-signal (AMS) and/or RF functionality combined with the digital circuit. One example of this combination is a digitally assisted, mixed-signal device (e.g., a VCO with digital calibration).
Verification of the growing analog/mixed-signal portion of SoCs is leading to better behavioral models, which abstract the analog upward to the register transfer level (RTL). This improvement provides a more consistent handoff between the analog and digital boundaries. Another improvement is the use of real number models (RNMs), which enable the discrete time transformations needed for pure digital solver simulation of analog/mixed-signal verification. This approach enables faster simulation speeds for event-driven real-time models – a benefit over behavioral models like Verilog-A.
AMS simulations are also using assertion techniques to improve verification – especially in interface testing.
One important trend is the use of statistical analysis to handle both the analog nature of mixed signals and the increasing number of operational modes. I’ll post my detailed interview with Nizic and DeMaria in an upcoming blog.
3. Keynote presentations
Lip-Bu Tan, president and CEO of Cadence, began his keynote by showcasing many of today’s most popular consumer electronics – from Google glasses and other wearable embedded electronics to Samsung gesture recognition TVs and the latest automotive infotainment systems. All of these products were made possible by the semiconductor industry.
The consumer-electronics industry has grown, thanks to the popularity of mobile and social-media applications. These applications represent important aspects of the Internet of Things – all of those unique objects that make up the front and back end of the Internet. With over one billion users on Facebook, Tan noted that the back-end cloud computing and big-data aspects of the Internet are as critical as the front-end devices. “The semiconductor industry figures prominently in all of this,” he summarized.
Chip designers and manufacturers have had to overcome significant challenges to bring these amazing devices and infrastructure to market. But even more difficult challenges lie ahead. Tan listed several of the more critical ones – from lithography and design-rule complexity to IP integration, the proliferation of mixed-signal circuits needed to support the Internet of Things, and low-power and signal-integrity issues.
Cadences success in overcoming these challenges was due to collaboration with its partners, said Tan. For example, Cadence, ARM, and TSMC continue to collaborate on 20-nm FinFET designs. Stacked-die 3D IC technology represented another area of partnership (in this case, with TSMC’s Chip-on-Wafer-on-Substrate [CoWoS] integration process). As a final example, Tan highlighted Cadence’s 14-nm FinFET collaboration with Samsung.
On the business side of the market, Cadence has acquired several IP-rich companies over the last few years. Two recently named acquisitions – Cosmic Circuits and Tensilica – will enhance the company’s position in the mixed-signal and dataplane processing markets, respectively. (Cadence To Buy Tensilica)
In conclusion, Tan highlighted one consumer success based in part on the use of Cadence’s EDA tools and methodologies – namely, the Hero GoPro camera. Over 2.3 million units were shipped last year. He hoped that such commercial successes would help to ignite interest in the EDA industry, inspiring high-school and college students to view chip design with the same “coolness” factor as the other technology giants (e.g., Facebook and Google).
The next speaker was Samsung Electronic’s CEO, Young Sohn. He provided a customer view of the semiconductor market. Samsung’s goal is to be seen as a part of the global consumer community. One measure of the success of Samsung’s branding campaign was the company’s placement among the top 10 traditional consumer brands, replacing traditional products like software drinks.
Today’s post-PC era is dominated by non-Windows operating systems like Apple’s iOS and Google’s Android, said Sohn. This is one indicator of the popularity of mobile devices. Not surprisingly, most of the growth at Samsung has occurred in the mobile and cloud markets. If those market segments were removed, growth in the global semiconductor market would have been flat.
Mobile is big and getting bigger. Sohn said that the company’s vision was to create products that would share data and applications among all devices – from smartphones to smart sensors. To show that mobile is much bigger than just web access, he shared a video clip where wireless nanobots were used to kill cancer cells.
Sohn was cautious about the traditional cost and form-factor reduction enabled by the semiconductor market. “Moore’s Law is an observation. In the future, cycle times (of Moore’s Law) may increase,” he speculated.
What technologies would smartphones utilize seven years from now? A good bet would be fifth-generation (5G) cellular, low-power WiFi-based dust networks with environmental sensing and high-definition, flexible organic LED displays – all running at 13 Wh. Today’s smartphones run on 8 Wh of power or less. Sohn conceded that many innovations will be needed to achieve these features – especially in low-power design and improved energy storage (i.e., battery technology).
Sohn echoed Tan’s litany of challenges facing chip designers and manufacturers – from continued device scaling to double and triple patterning and EUV lithography obstacles for the lowest nodes. He observed that there is always a cost-versus-risk tradeoff with new technologies.
One alternative to leading-edge, lowest-node technology is 3D stacked-die ICs. For now, 3D chip packaging is as expensive as the design of the SoC. But compressing form factors in mobile is important, as with system-in-package (SiP) technologies. Sohn issued the common desire that EDA tools need to do a better job with 3D stacking designs. 3D SoC designs are like housing urbanization, said Sohn. Chips need to be denser, but also must handle the increased traffic load. This is another area where innovation is required to find a solution.
Designing chips of ever-increasing complexity is not an easy task. Neither is making those chips. Manufacturing SoCs at leading-edge foundries has become a very exclusive club. The few winners that have the money and resources to create these fabs will take the biggest share of the revenue. This creates a very high barrier for startup innovation. Sohn recommended that chip designers focus on what they do best. This approach is why the development of outside, non-internal IP is a growth segment. The challenges of manufacturing and design force IP, EDA, and foundries to work together to build successful products.
Innovations are needed to overcome future design and manufacturing issues. This innovation will probably lead to disruptive technologies. To encourage this innovation, the company recently launched the Samsung Strategy and Innovation Center (SSIC), which will invest $1.1B in existing and disruptive technologies. Such an investment will help the company maintain its position as the so-called “fifth horseman” alongside Amazon, Apple, Facebook, and Google in Silicon Valley. “We need to innovate outside of Korea with Silicon Valley,” Sohn concluded.
Rounding off the keynote presenters was Martin Lund, Senior VP of the SoC Realization Group at Cadence. He explained that, while SoCs were everywhere from smartphones to the cloud, the new thing was the growing application space in which these chips must exist.
Lund focused on the design of the SoC, but with this twist: The application space for chips is growing to encompass the Internet-of-Things universe – from smartphones and new application devices to the cloud.
A key challenge presented by expanding application spaces was the IP verification of ever-changing standards. “There are hundreds of pages of requirements for just the latest PCIe, Gen. 3 specification,” he noted. “All of these dynamic requirements affect the IP on the SoC.”
The traditional idea of IP reuse was that once IP was created, it could be reused over and over again. Lund said that this idea was being challenged. He used the evolving Ethernet standard as an example, where 45 cumulative additions had occurred since the standard’s origin in 1983. Such constant changes meant that the IP-reuse model was under stress.
To meet this challenge, IP must be designed for change. He explained that IP must be optimized for the application (i.e., from a software perspective). This approach also addresses the fact that software often decides if a design will achieve the critical time-to-market (TTM) window.
IP must be built to fit the SoC. To achieve this end, Lund said that next-generation IP must be optimized for the end application. It also must be part of an intelligent subsystem. Furthermore, IP must be pre-verified. This is why Cadence provides a growing number of design cores and verification IP tools, he concluded.
For more details, read Richard Goering’s blog: Martin Lund CDNLive Keynote: Why SoCs Need “Application Optimized” IP.
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