Cadence® system design and verification solutions, integrated under our System Development Suite, provide the simulation, acceleration, emulation, and management capabilities.
System Development Suite Related Products A-Z
Cadence® digital design and signoff solutions provide a fast path to design closure and better predictability, helping you meet your power, performance, and area (PPA) targets.
Full-Flow Digital Solution Related Products A-Z
Cadence® custom, analog, and RF design solutions can help you save time by automating many routine tasks, from block-level and mixed-signal simulation to routing and library characterization.
Overview Related Products A-Z
Driving efficiency and accuracy in advanced packaging, system planning, and multi-fabric interoperability, Cadence® package implementation products deliver the automation and accuracy.
Cadence® PCB design solutions enable shorter, more predictable design cycles with greater integration of component design and system-level simulation for a constraint-driven flow.
An open IP platform for you to customize your app-driven SoC design.
Comprehensive solutions and methodologies.
Helping you meet your broader business goals.
A global customer support infrastructure with around-the-clock help.
24/7 Support - Cadence Online Support
Locate the latest software updates, service request, technical documentation, solutions and more in your personalized environment.
Cadence offers various software services for download. This page describes our offerings, including the Allegro FREE Physical Viewer.
Get the most out of your investment in Cadence technologies through a wide range of training offerings.
This course combines our Allegro PCB Editor Basic Techniques, followed by Allegro PCB Editor Intermediate Techniques.
Virtuoso Analog Design Environment Verifier 16.7
Learn learn to perform requirements-driven analog verification using the Virtuoso ADE Verifier tool.
Exchange ideas, news, technical information, and best practices.
The community is open to everyone, and to provide the most value, we require participants to follow our Community Guidelines that facilitate a quality exchange of ideas and information.
It's not all about the technlogy. Here we exchange ideas on the Cadence Academic Network and other subjects of general interest.
Cadence is a leading provider of system design tools, software, IP, and services.
A 3D multi-gate transistor called the FinFET promises tremendous power and performance advantages at 16nm and 14nm process nodes (and was adopted at 22nm by Intel) -- but nobody can use FinFETs without an accurate compact model. Fortunately, the BSIM-CMG model available from the University of California at Berkeley provides just that, and Cadence and other industry partners helped develop it.
The term FinFET was coined by Prof. Chenming Hu and other U.C. Berkeley researchers to describe a new type of multi-gate, non-planar transistor. In a FinFET, the FET gate wraps around three sides of the transistor's elevated channel, or "fin," forming conducting channels on three sides of the vertical fin structure. This new 3D structure requires a new model, and that's why the BSIM Group of the U.C. Berkeley Device Group developed BSIM-CMG.
The BSIM-CMG model was developed to model the electrical characteristics of multi-gate structures. It considers finite body doping, volume inversion, electro-static potential in the body of multi-gate MOSFETs, electrostatic control from the end-gates, and many other effects. The model is implemented in Verilog-A and has been verified with experimental industrial data.
Different FinFET structures that can be modeled by BSIM-CMG (Source: Navid Paydavosi via Wikimedia Commons)
BSIM-CMG 106.0.0 was officially released March 1, 2012. This was the first standard model for FinFETs. The current release, BSIM-CMG 106.1.0, was released Sept. 11, 2012. A number of "unofficial" releases preceded these two releases. You can download the 106.1.0 release and view a technical manual here.
What are the advantages of BSIM-CMG over BSIM4? A FAQ compiled by the BSIM Group lists these BSIM-CMG features:
Input from Industry
A model such as BSIM-CMG doesn't only happen in academia. Input from industry is crucial, and the technical manual for the 106.1.0 release includes acknowledgements for (in alphabetical order) Accelicon, Cadence, Freescale, GLOBALFOUNDRIES, IBM, Proplus Solutions, Qualcomm, Silvaco, Synopsys, Texas Instruments, and TSMC. I talked with Jushan Xie, engineering director for the circuit simulation team at Cadence, about the Cadence role in FinFET device model development.
Xie noted that Cadence works with Berkeley on all kinds of models. "Whenever Berkeley has a new model or a new version, they talk to us," he said. "We share our expertise on how to implement the model and improve performance. We work with Berkeley on bug fixing and model improvement."
Xie said that Cadence started working with Berkeley on FinFET device modeling about four years ago, beginning with "research work" before there was much foundry involvement. This work became more intensive within the past three years, and it included early releases up to the latest release. Cadence worked with both U.C. Berkeley and foundries to ensure that the BSIM-CMG model was accurate and had good simulation performance. "We really did a lot of work," Xie said. And the work goes on, with 10nm and 7nm in sight.
So how is the FinFET device model different from planar transistor models? Because the FinFET has a 3D structure, the modeling concept is quite different from planar CMOS, Xie said. Now you have to add several gates together (three for tri-gate) to get the width; consider resistance and capacitance parasitics from fin extensions; and use a surface potential modeling approach that is more physical. One limitation of FinFETs is that continuous transistor sizing is not supported - designers can't change the width or height of a fin. (That's why the HFIN parameter mentioned above is currently treated as a model parameter rather than an instance parameter - fin height is expected to remain constant for a given technology.)
Work has also been ongoing inside of Cadence to ensure that tools support BSIM-CMG FinFET models. Cadence simulation, timing, extraction, and cell characterization tools support the models.
Earlier this month I wrote about a 14nm FinFET test chip tapeout in which ARM, Cadence and Samsung accomplished the digital implementation in about 8 weeks. This kind of success could not have happened without the R&D effort to develop an accurate device model. BSIM-CMG is just one part of a massive, industry-wide R&D effort to enable FinFET technology, an effort that deeply involves Cadence and many of its partners.
Note: Prof. Hu visited Cadence in 2009 and 2011 and gave well-attended technical talks introducing FinFETs. For a detailed review of the 2011 talk, see Steve Leibson's EDA360 Insider blog post.
Related Blog Posts
Cadence, ARM, Samsung 14nm Test Chip - Collaboration Eases FinFET Digital Implementation
ARM TechCon: Inside Story of a 14nm FinFET Tapeout
ARM TechCon: Design at 14nm (or 10nm) - What's Going to Change
TSMC Forum: An Update on 20nm, 3D-IC, and 16nm FinFETs
FinFETs, Tri-Gate Transistors Promise Low Power - But Pose Some Design Challenges
My understanding is that the FinFET that Intel has produced has been found in SEMs by ChipWorks to have a more trapezoidal shape as opposed vertical sidewalls. How well does this model capture the performance of a trapezoidal based structure in lieu of the more ideal rectangular structure? GSS has studied the two structures and compares the I-V performance of the two at URL:www.goldstandardsimulations.com/.../simulation-analysis-of-the-intel-22nm-finfet