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Faisal went into some detail on these points. The discussion then turned to application-aware IP, what is needed, and what the benefits will be. From an IP component point of view, what is needed to achieve PPA targets includes:
From a methodology point of view, what is needed includes:
Faisal then discussed some of the DesignWare IP solutions from Synopsys to address these requirements:
HPC Kit Enhanced for AI Applications
This package includes IP for object detection and recognition. There are special cells to reduce CNN power consumption up to 39%. Tradeoff tuning enables a 7% frequency boost with 28% lower power. The figure below summarizes some of the benefits of the HPC Kit. This IP is typically used for ADAS applications.
Memory Architectures
The benefits of customizing memory architectures to optimize PPA for AI designs was also discussed. Synopsys offers a wide range of architectures, bitcells, VTs and PVTs here, including:
GPIO Libraries
AI designs are typically core limited (as opposed to pad limited). Inline I/O libraries with a less height and more width form factor are optimal to reduce SoC area for this situation. Synopsys offers DesignWare IO Libraries with:
DFT
The ability to integrate an on-chip test and repair engine is important for reducing area and power in AI applications. The Synopsys STAR Memory System provides this support. Total core area can be reduced by ~7% and dynamic power can be reduced by ~12%.
Conclusion
Faisal concluded by explaining that the IP discussed is silicon-proven in volume at TSMC 7nm and test silicon proven at TSMC 5nm. You can learn more about Synopsys DesignWare IP for AI here. You can access the TSMC OIP presentations here. AI/ML SoCs truly get a boost from Synopsys IP on TSMC's 7nm and 5nm.
[post_title] => AI/ML SoCs Get a Boost from Synopsys IP on TSMC's 7nm and 5nm [post_excerpt] => [post_status] => publish [comment_status] => open [ping_status] => open [post_password] => [post_name] => ai-ml-socs-get-a-boost-from-synopsys-ip-on-tsmcs-7nm-and-5nm [to_ping] => [pinged] => [post_modified] => 2020-09-21 08:20:19 [post_modified_gmt] => 2020-09-21 15:20:19 [post_content_filtered] => [post_parent] => 0 [guid] => https://semiwiki.com/?p=291098 [menu_order] => 0 [post_type] => post [post_mime_type] => [comment_count] => 0 [filter] => raw ) [5] => WP_Post Object ( [ID] => 290760 [post_author] => 16 [post_date] => 2020-09-22 06:00:13 [post_date_gmt] => 2020-09-22 13:00:13 [post_content] => A checker tripped in verification. Is there a bug trace minimization technique to simplify manual debug? Paul Cunningham (GM, Verification at Cadence), Jim Hogan and I continue our series to highlight all the great research that’s out there in verification. Feel free to comment.
Source: https://ibex-core.readthedocs.io/en/latest/verification.html[/caption]
In the testbench SV classes are blocks with rounded corners, while SV modules are shown as square corners, finally the code to be run is depicted in blue with folded corners.
Random commands come from the Google DV generator, and the testbench also has random interrupts during testing. The co-simulation flow has both an ISS and RTL loaded with test binaries, simulations are run, then the results are compared by a Python script. You can have the same verification experience if you assemble all of the pieces:
The second half of the webinar was showing an actual, live demo of this verification flow in action, running the makefiles, scripts, simulators and comparison on a Linux platform. Batch mode verification was shown first verifying the Ibex core, then GUI mode was run next, and in both cases there were zero mismatches between the ISS and Riviera-PRO simulator results.
The GUI for Riviera-PRO had multiple windows: Source code, Classes, Assertions, Messages. In the upper right is the Classes Window, showing instances and hierarchy, methods, properties, derived classes and base classes.
A very useful documentation feature was how a UVM graph could be auto-generated within Riviera-PRO, as it showed memory interface agents, one interrupt agent, connections, and then stepped into instances for more details to understand connectivity.
An assertions window showed all assertions in one place, without having to look at multiple files, while seeing any failures, passes, and the time when it last happened, quite useful for debugging.
Next, the waveform viewer was invoked after restarting simulation, and they added waveforms from the DUT.
Finally, they showed the RTL code coverage after simulation had finished, then generated an HTML cumulative summary.
Murilo Pilon Pessatti is an Electrical Engineer with a MSEE in Analog IC design. He studied in Brazil at São Paulo University (USP) and earned a masters at Campinas State University (UNICAMP). Murilo then moved to Lisbon in Europe to work for ChipIdea, in the early 2000's when the smartphone era was just taking off.
"I had the distinct pleasure to work in one of the first first Analog IP companies, where I had the chance to learn a lot and very fast about Power Management for portable devices. I came back to Brazil and after spending 2 years in a public semiconductor company and decided to start Chipus."
Please tell me about Chipus
Chipus is a mixed-signal IC design company. We have strong analog expertise, mixed up with significant know-how in digital state-of-the-art technologies. We help our customers to develop the next generation of key IoT, Industrial, Sensors, AI and RF/Optical Communication ASICs. In these almost 12 years since we started the company we had the opportunity to develop almost 400 IPs in mixed-signal areas, tapeout lots of projects, develop very interesting full turn-key ASICs and have a lot of fun working with very challenging and smart customers -- something that really motivates us!
What problems does Chipus solve?
Chipus was born with the power-aware mindset. Since the beginning in 2009 when we started building our IP portfolio, we pushed the limits to deliver the lowest power IPs and ASICs. So definitely, when the whole IoT and AI wave hit the market, we were very well positioned to solve all the power related problems based on the IPs and experience we accumulated in the last decade. The key approach and differentiation we have is based on our solid expertise and know-how in operating transistors in weak and moderate inversion. We have both practical ( many tape-outs our team have done dealing with very low power circuits) and solid theoretical experience and background in this field (we are lucky to have a group of researchers in the university very close to us that has developed one of the most accurate charge-based physical models operating in all-region). Adding all of this on top of the portfolio of IPs we have created in the last decade put Chipus in the lead position to solve key power-related problems in IoT and AI to the edge systems and ASICs.
We started back in early 2009 building our IP portfolio and as we start gaining credibility from the market by licensing our IPs, our customers start to ask us to help them integrate ours and 3rd Party IPs in their SoCs. We end up not only helping them but also start providing a kind of differentiated design services for customers that really need a high quality team working very close and collaboratively with their SoC architects. At the same time, we start expanding our IP offering, to the point that nowadays we also have high-speed and high-precision building block IPs. Because all these IPs and SoCs had also significant digital blocks, we also built a very experienced digital team that gained a lot of traction in the recent years providing full RTL-to-GDSII flow in state-of-the-art technologies. Last but not least, it was very natural in the last years for Chipus to extend our high quality integration IP services to a complete full ASIC offer, that we start to see a big momentum in different market segments, not only in IoT, industrial but also RF/optical communication.
How has the market changed for Chipus in the past 10 years?
I see all of the high dynamics in the semiconductor M&A area as a big opportunity to Chipus. But the most important thing for us is to continue doing our high quality work for our customers, even when these customers are merged or acquired by other companies, most of the time we keep working with them, and sometimes our business even grows as they merge with other bigger companies. We are always searching for new challenges and to find out how we can give the best support to our customers, so that all of this market consolidation did not really affect our business and goals as a company.
I do believe that IoT, AI to the edge and optical communication are very promising market segments. It is easy to understand: more and more all these "things" are portable and more functionalities need to be done on the edge to be real time. On the other hand, all those things end up putting lots of bits on the internet, which simply cannot afford to use copper anymore. All of this with just some "pico-joules" of energy to make sure batteries last long. That is for me a big opportunity to solve key problems.
What type of customers does Chipus look for?
We have all types of customers, we never give up to offer the best quality, does not matter the size of the customer, we will be there. We have worked with some small start-ups that end up having very significant exits and become part of big companies. Sometimes we have customers that we license some IPs, sometimes we have customers that need help in a key project in which we come in and increase their capability to solve problems, and sometimes we have customers that want us to develop a full turn-key ASIC. The common point is that in almost all the cases, those customers come back and ask us again for our support. We have some long term customers for who we work constantly and for a long term period. We always see our customers and the business as a relationship and not as a transaction. We expect for a typical customer the same.
Time-to-market, first-time-right and price are for sure a big concern from customers. Especially when we have the first interactions with the customers these requirements are more prominent. As far we start the engagement and the trust is developed, things tend to go more smoothly and the most important thing is to be lined up with the long term objectives and goals of the customers. We usually work in very close relationships with our customers long term goals.
About Chipus
Chipus Microelectronics (ISO 9001:2015 certified) is a semiconductor company focused on the development of mixed-signal ASICs, intellectual property (IP) blocks and IC design services. The company has more than 200 analog IP blocks in process nodes from 22nm to 0.35um of various foundries. Since its foundation in 2008, Chipus has worked with customers worldwide (South and North America, Europe, and Asia) with firm commitment and flexible client support.
Besides analog and mixed-signal expertise, Chipus also offers custom digital IC design services having successfully delivered designs in 7nm from RTL to backend. Headquartered in Florianópolis, Brazil, Chipus has a US subsidiary in Silicon Valley and sales teams in both USA and Europe.
For additional information on Chipus or its services, please contact us here.
[post_title] => CEO Interview: Murilo Pilon Pessatti of Chipus Microelectronics
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No-one likes being put on the spot and yet we all like a forecast…and as we all know, the only guarantee with a forecast is that it is wrong. Sports commentators have carved out a special niche for themselves with the ‘commentators curse’, just as they extol the virtues of an individual or a team, the sporting gods prove them wrong in spectacular fashion! Governments are no better…economic forecasts don’t usually hold for more than a quarter, which is what makes Gordon Moore’s prediction all the more impressive.
I’m sure everyone in our industry is familiar with Moore’s Law… while at Fairchild Semiconductor in 1965 he was asked to contribute to the 35th anniversary Electronics Magazine with a prediction for the future of the semiconductor components industry over the next 10 years…his response was ‘the number of transistors in a ‘dense IC’ would double every two years’! What a prediction, it was correct for the next 50 years and is only now starting to ‘fade’, surely the SWAG* to beat all SWAGs?!
So what has Moore’s Law got to do with Moortec?
Broadly speaking he predicted that over time transistor density would increase, so more could be put on anyone device…and predictably devices would grow. This wasn’t really an issue in the early days, when geometries were measured in micrometres, in fact all the way down to 40nm there weren’t any major issues, it was the transition from planar to FinFET technology where things started to change. The bit Gordon wasn’t too explicit on was the change in leakage current as we ride the geometry wave, leakage current starts to become an issue in FinFET and is just plain ugly sub 7nm, add to which the chip sizes grow significantly as the applications of the day try to maximise the benefits of these plentiful transistors.
Ok, big deal…chips get bigger, leakage increases, power density is now also increasing with the ‘end’ of Dennard Scaling, you don’t need to be Nostradamous to predict that things will start to warm up a little. Yet that isn’t the only effect you’ll be seeing, temperature is a first order effect…as the heat rises so data throughput drops, power consumption increases and so the cycle builds on itself. Second order effects then come into play, the silicon starts to age, reliability takes a hit and can have knock-on effects into your system reliability and overall performance.
Great man though he was, Gordon didn’t mention any of that.
So here is where Moortec’s Law comes in (just for the record, I’m not claiming it will last 50 years!)…‘the number of sensors used in a ‘dense IC’ will (at least) double per geometry shrink’. There is a second Law (as with Gordon, he too had a second, less well known Law), ‘the number of sensors used in individual designs will rise exponentially as engineers appreciate the information they can divulge in mission mode’!
The proliferation of sensors in SoCs will not only be driven by better understanding of the value of the data they provide, but also a deeper appreciation of the type of data they can provide in different areas of a design. Imagine baking a souffle in an oven without a glass door, you are blind to what is happening inside. You’ve followed a recipe and yet you can’t be sure the eggs were a uniform size or the flour was a consistent strength or that the oven holds it’s temperature evenly throughout the cooking process…until you open the oven door, you don’t know what to expect…open it too soon and it will sink, too late and it will have burnt!
SoCs are no different, except the cost of failure is many orders of magnitude greater, that ‘mission mode’ visibility the glass door provides is no different from having 10s, 100s or even 1000s of sensors in your device.
*Scientific Wild-Ass Guess
In case you missed any of Moortec’s previous “Talking Sense” blogs, you can catch up HERE.
WEBINAR: Addressing the Challenges of Hyper-scaling within Data Centers with Advanced Node Embedded Sensing Fabrics
[post_title] => From Moore’s Law to Moortec’s Law!
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Many times i notice people "kind of afraid" of some protocol, trying to avoid the usage because "it's complicated", I decide to go in-depth in one and show that maybe it's not so complicated after all. First challenge is choosing the protocol and decide about the Ethernet, because this protocol has many challenges in my mind, and it's well-known, old, has many standards, have misconceptions that another protocol, like USB or HDMI don't.
WARNING
I'll try to show the protocol in low-level (bit level) in few words possible, many things will be missing in this text, so don't use this text to do any ethernet work related.
The Ethernet was started in 1973, but only in 1990 was released the standards IEEE 802.3i that is known as Ethernet 10BASE-T or "10Mbit Ethernet", and the first point is that there were some standards before, like the DIX Ethernet, StarLAN and LattisNET. I don't think theses protocols are used today, so I'll ignore them and focus only on the IEEE 802.3i, that I'll call "Ethernet".
Other point is the IEEE 802.3 standard, is a collection of standard so, we have Ethernet over Coax cable, twisted pair, Fiber-Optic, and many other options. Again the focus is the 10BASE-T (10 is refer of 10Mbit, the BASE refer signaling BASE or BROAD and T refer twisted pair).
The ethernet standard 802.3i will cover only the physical and data link of the OSI model, but in the data link layer will be divided into MAC (media access control) and LLC (logical link control), the 802.3i only cover the MAC layer, don't cover the LLC layer, this is cover in 802.2.
For a designer that want to include the ethernet in your project (Considering a IC Designer) you will need design theses.
Physical layer (Mostly Analog IC Designer)
All communication is transmitted by a differential driver and will have the deal with some encoded data in and out as the control in and out.
All data will be encoded in Manchester encode and will communicate in full-duplex or half-duplex.
Media Access Control Layer (Digital IC Designer)
Uses CSMA/CD control access and will receive and send a frame that will be describe below:
1 - Preamble
2 - SFD
3 - Destination Address
4 - Source Address
5 - Length/Type
6 - MAC Client data / PAD (Payload)
7 - Frame Check Sequence
8 - Extension (optional)
1 - Preamble is a 7 bytes(56 bit) that is sent to allow the PHY layer reaches a steady state, these bytes is:
10101010 10101010 10101010 10101010 10101010 10101010 10101010
2 - SFD is the Start Frame Delimiter show the start of the frame, this is one byte (8 bit):
10101011
3 and 4 - Destination and Source Address, both is an 6 bytes (48 bit), that theoretically represent a unique identifier for each equipment.
5 - This can represent two types of data, in 2 bytes (16 bits) the length or type of the following data.
6 - This is the data to be sent, or message, can be 46 to 1500 bytes long (368 to 12000 bits) and at the end is included a PAD. Any other protocol will be in it.
7 - This is a CRC calculation of the Destination and source address, length/type field and data/pad field, and is attached in the end of data/pad field, that has 4 bytes (32 bits) long.
8 - It's not transmitted in half-duplex mode, is transmitted until complete the time frame.
There are many controls and processes that the MAC Layer will execute, but i don't think this will very interesting to show in this post. And there is no way that i can show every detail of the standard in some small internet post.
But as you can see, isn't complicated to implement, sometimes it's hard to get some information if it's old, or maybe pay for the standard and understand it.
It's totally possible to a designer implement any standard, the most complicated is understand the standard that is written not in a very practical way, this need practice to understand it.
[post_title] => Protocol in Depth - Ethernet
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This is another installment covering TSMC’s very popular Open Innovation Platform event (OIP), held on August 25. This event presents a diverse and high-impact series of presentations describing how TSMC’s vast ecosystem collaborates with each other and with TSMC. Not all SerDes are the same. The presentation covered here, from Cadence, discusses the various flavors of LR, MR/VSR and XSR high speed SerDes and where they fit best. When it comes to 112G/56G SerDes, you really need to select the right PAM4 SerDes for your application.
The presentation was given by Wendy Wu, product marketing director at Cadence. Wendy has also worked in marketing and applications engineering at NetLogic Microsystems, Broadcom and Cavium. Wendy speaks with strong authority on the topic. She began her talk discussing a semiconductor law that is somewhat less know than Moore’s Law, but very relevant. Rent’s rule is based on internal memoranda at IBM from 1960. It basically says that the number of I/O pins tracks the number of gates/transistors. So, functionality increase requires I/O bandwidth to increase. This is why the topic is inherently important.
Wendy then discussed how high-speed interconnect is the backbone of cloud data centers. Higher throughput with lower latency and flat power describe the challenge. Wendy shared an interesting statistic – 85% of the traffic in a typical data center is between compute nodes in that data center. Data communications is clearly a key item for continued growth in this huge market.
Looking at AI requirements for high-speed comms, 7nm and 5nm are the preferred nodes today, with 3nm around the corner. We are at the cutting edge here. Wendy then discussed the various applications for 56G and 112G SerDes. She touched on four areas:
Long reach: backplane applications – between processors and racks. Drive, performance and signal loss are key parameters here.
Medium reach: chip-to-chip and mid-range backplanes.
Very short reach: chip to module applications.
Extra short reach: die-to-die, system in package applications.
With regard to die-to-die communications, three methods were discussed. This technology is also an enabler for the growing chiplet market. There is the previously discussed PAM4 SerDes approach. NRZ serial interface is another approach. Finally, a parallel interface can be considered, similar to what is used for HBM stacks with a silicon interposer. Each of these approaches has its strengths and weaknesses.
Next, Wendy examined analog vs. digital equalizer architectures. An analog solution delivers better density and lower power but is susceptible to channel noise and can equalize up to 20db of loss. Analog-to-digital, DSP-based approaches are more stable and reliable. They can equalize up to 40db of loss. Traditionally, these solutions have been higher power than analog. Starting at 7nm and below, the power requirements of digital solutions are very similar to analog. With all this background, what is the best approach? Clearly that depends on the application. Wendy provided a good overview of where each technology fits. This is captured in the diagram below.
Wendy then discussed the 56G and 112G offerings from Cadence, built by a best-in-class engineering team that is strong in both analog and digital techniques. The IP is fully compliant with relevant industry standards. She also pointed out that Cadence works with connector, cable and optical module suppliers to ensure good interoperability. Both 56G and 112G parts are proven with multiple test chips. She explained that the portfolio can support requirements from LR to XSR. These points are illustrated by the graphic at the top of this post.
Wendy went into some detail on the Cadence 112G-LR DSP SerDes. The key advantages are summarized in the figure below.
Wendy concluded with a discussion of the Cadence UltraLink D2D PHY IP. This IP can connect two designs through a multi-chip module or an organic substrate. The figure, below, summarizes the performance parameters of this IP.
You can learn more about how to select the right PAM4 SerDes for your application and the Cadence IP portfolio here.
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This is another installment covering TSMC’s very popular Open Innovation Platform event (OIP), held on August 25. This event presents a diverse and high-impact series of presentations describing how TSMC’s vast ecosystem collaborates with each other and with TSMC. Not all SerDes are the same. The presentation covered here,… Read More
SSD memory is enjoying a new resurgence in datacenters through NVMe. Not as a replacement for more traditional HDD disk drives, which though slower are still much cheaper. NVMe storage has instead become a storage cache between hot DRAM memory close to processors and the “cold” HDD storage. I commented last year on why this has become… Read More
Mentor Graphics, a Siemens Business, has completed their acquisition of EDA company Avatar Integrated Systems. I recently spoke with Joe Sawicki, Executive VP of the Mentor IC EDA segment, about the acquisition strategy and IC Design platform goals for integration of the Avatar products.
Avatar (formerly ATopTech) focused… Read More
On the eve of the Innovative Designs Enabled by Ansys Semiconductor (IDEAS) Forum I spoke with Vic on a range of topics including his opening keynote: Accelerating Moore and Beyond Moore with Multiphysics. You can register here.
Vic Kulkarni is Vice President and Chief Strategist, Semiconductor Business Unit, Ansys, San Jose.… Read More
This is another installment covering TSMC’s very popular Open Innovation Platform event (OIP), held on August 25. This event presents a diverse and high-impact series of presentations describing how TSMC’s vast ecosystem collaborates with each other and with TSMC. The presentation covered here from Synopsys focuses on the… Read More
A checker tripped in verification. Is there a bug trace minimization technique to simplify manual debug? Paul Cunningham (GM, Verification at Cadence), Jim Hogan and I continue our series to highlight all the great research that’s out there in verification. Feel free to comment.
This month’s pick is Simulation-Based… Read More
Oh, our semiconductor industry just loves acronyms, and the title of my blog packs three of the most popular acronyms together at once. I attended a webinar hosted by Aldec last week on this topic, “UVM Simulation-based environment for Ibex RISC-V CPU core with Google RISC-V DV“. Verification engineers have been … Read More
Murilo Pilon Pessatti is an Electrical Engineer with a MSEE in Analog IC design. He studied in Brazil at São Paulo University (USP) and earned a masters at Campinas State University (UNICAMP). Murilo then moved to Lisbon in Europe to work for ChipIdea, in the early 2000’s when the smartphone era was just taking off.
“I… Read More
No-one likes being put on the spot and yet we all like a forecast…and as we all know, the only guarantee with a forecast is that it is wrong. Sports commentators have carved out a special niche for themselves with the ‘commentators curse’, just as they extol the virtues of an individual or a team, the sporting gods prove them wrong in … Read More
Many times i notice people “kind of afraid” of some protocol, trying to avoid the usage because “it’s complicated”, I decide to go in-depth in one and show that maybe it’s not so complicated after all. First challenge is choosing the protocol and decide about the Ethernet, because this protocol… Read More
The Aprisa SAPR input data is a simple LEF/DEF design model from a (physical-aware) logic synthesis toolset. From the synthesis netlist, Aprisa applies optimizations that focus on ensuring subsequent routability – e.g., congestion avoidance, pin access, adherence to multipatterning decomposition coloring. An internal physical DRC verification engine is applied. A diverse set of clock tree design styles are available, including useful clock skew timing optimizations throughout.
An internal synthesis engine allows for further optimization. The input netlist placement assumptions may not accurately reflect the route impact of congestion, R*C delays, and clock skews. Logic restructuring based on the routing model may be needed. The tool incorporates static timing, noise, IR, and EM analysis algorithms to guide placement and route assignment decisions.
Joe indicated, “Designers of complex SoCs at advanced nodes are seeking the following from their APR flow – better synthesis-to-post route timing correlation, no coupling noise issues, no DRC violations, in short, fewer APR iterations and faster time to closure. We benchmarked Aprisa, and found the PPA results to be excellent. The learning curve was extremely quick. We had competitive evaluation data within a few weeks.”
The figure above illustrates the pre-route (Steiner estimate) to post-route timing correlation on the Mentor benchmarks at the 7nm node.
Joe then described the IC Design product strategy. “The Nitro-SoC platform will be supported through the 16/14nm node. Going forward, Aprisa will be the SAPR solution for 7nm and below. The DRC engine that was internal to Aprisa will be replaced by Calibre InRoute.”
Joe continued, “The strength of the combined engineering and support teams will offer roadmap stability and continuity to customers, who may have been anxious given the relatively small size of Avatar’s team. Mentor will leverage its relationship with the foundries to extend the Aprisa product certification for advanced process nodes.”
With regards to the competitive position of the new offering, relative to the integrated platforms available for physical implementation, Joe said, “Designers want an APR tool that is feature-rich and easy to use. The route-centric data model and optimization algorithms in Aprisa provide faster closure and signoff accurate results. The use of a physical-aware (placement-centric) synthesis flow is a good start, but the set of optimizations available is a key differentiator, specifically route-aware logic re-synthesis. Refinement is where you get considerable value. We’ve already flipped customers from other products.”
It will be interesting to track how Aprisa emerges in the reference flow certification from the foundries, and how the route-centric with logic re-synthesis methodology evolves as a point tool solution. Mentor’s acquisition of Avatar expands the scope and future development of SAPR offerings. More competition among EDA providers is always a good thing for the IC design community.
[post_title] => Update on Mentor’s Acquisition of Avatar Integrated Systems
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On the eve of the Innovative Designs Enabled by Ansys Semiconductor (IDEAS) Forum I spoke with Vic on a range of topics including his opening keynote: Accelerating Moore and Beyond Moore with Multiphysics. You can register 
Q: Tell me more about your upcoming opening keynote for the IDEAS Digital Forum.
Vic took me through his presentation which is a great set-up for the first day. He starts with a brief overview of the Ansys Multiphysics Simulation Platform and moves into the benefits of a simulation-driven design from Concept to Design to Validation and the resulting savings. ANSYS has a broad range of customers so these numbers are VERY impressive.
Vic then talks about custom chips by systems companies for differentiation and faster TTM, semiconductor megatrends and technology challenges. The airplane graphic above explains it quite well (ANSYS tools are on the wings).
Bottom line: ANSYS is an important part of the leading edge semiconductor ecosystem for simulation, AI/ML, HPC, 5G, hardware security and autonomous vehicles. And while I miss the ANSYS live events (great food and networking) the ANSYS virtual events are must attend, absolutely.
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VLSI Symposium 2020 – Imec Monolithic CFET