EDACafe Weekly Review September 26th, 2017

Well, summer has been and gone; and for most of us it was a time to relax and reflect on our working practices. What can we do to achieve better results? And what can we do to break out of the routine of working on so many revisions?

For me, one of my summer break ponderings was thinking back on a trick I learned while working with my colleagues at the Silesian University of Technology.

CMOS technology is the one that has dominated all applications of digital circuits. Power consumed by a CMOS digital circuit is the sum of two components: static power and dynamic power. The static power is a characteristic feature of the technology process used, and is associated with leakage currents in steady state. The dynamic power consumed by a CMOS gate is proportional to average switching activity at the output of the gate, which describes how often the state at the gate output is changing. The dynamic power component can thus be considered and minimized in the appropriate process of logic synthesis.

The essence of logic synthesis oriented toward energy-efficiency requires finding a circuit structure in which the number of state transitions is minimized.

Switching global clock networks are responsible for a significant part of the total power dissipated by a CMOS VLSI circuit. That’s why many engineers try to block the clock signal to achieve power reductions in synchronous circuits.

Programmable Logic Devices (PLDs), and especially Field Programmable Gate Arrays (FPGAs), constitute a relatively new and rapidly developing branch of digital electronics. Constantly growing logic capacities at moderate prices make PLDs an attractive platform for not only prototyping but also short- and medium-volume production.

It is not always obvious though how best to map logic structures (resources) within a given PLD architecture when designing with energy-efficiency in mind. In particular, implementing clock gating is difficult, as PLD circuits contain dedicated clock networks, which do not contain any gating elements. “Disabling” the clock signal in PLD structures can be accomplished in two ways: firstly, by utilizing the “Enable Clock” inputs of memory elements or, secondly, by distributing the clock signal using local clock lines or general-purpose routing resources (which enable the insertion of logic gates). For the rest of this article, visit the Aldec Design and Verification Blog.


Blue Pearl: Best kept Secret in EDA
September 21, 2017  by Peggy Aycinena


Silicon Valley based Blue Pearl Software
is the quintessential EDA company: privately held, run by a seasoned team of EDA experts, and with a portfolio that includes tools for generating timing constraints, CDC analysis, both synchronous and asynchronous, RTL verification tools for methodology standards and design rules, and design management tools.

Similarly, Blue Pearl’s Ellis Smith is the quintessential CEO in EDA. Before founding his current company, Smith was CEO and President of Orora Design Technologies, CEO at TransEDA through that company’s IPO in 2000, and CEO at Exemplar Logic through its merger with Mentor Graphics in 1995. His experience also includes a stint as CEO at CrossCheck Technology, and years spent at Duet Technologies, CADAM, Versatec, Dictaphone, and 3M. Pretty much the whole history of the EDA industry in one CV.

It would be an excellent idea to sit down for a very long conversation with Ellis Smith to discuss his take on the history of this oh-so-interesting industry. Unfortunately, time was of the essence when I did get the chance to talk with him earlier this month, and the focus was principally on Blue Pearl.

Don’t be a Slave to the Documentation
September 20, 2017  by Janusz Kitel

Are you a requirements engineer but your main goal is to provide well organized documentation? Do you have a great knowledge about the industry, business analysis and systems but you are struggling with the shape and look of your documentation? Do you still hear, for instance, that the specification document is not easy to read and difficult to use?


Requirements first

Requirements are the starting point of all other activities in a project lifecycle. So the specification document is crucial for the project. The document has many audiences such us stakeholders, designers, verification engineers and other groups involved in the project. This forces the author of the document to take care of the structure and organization of the document. It is not a big deal to prepare such a document. The problem is that the document has to be modified many times. The requirements are constantly changing, with new features appearing, some being modified and some being removed. Reclassification and reorganization must be repeated many times. In which case, I am pretty sure you will be contending with issues such as auto numbering, indentation, paragraph styles as well as tables and drawings that just do not fit the page.

Another kind of trouble comes from collaboration. Requirements should be developed by more than one engineer but working together on the same document is really a challenge. Forgetting to enable Track Changes, using the wrong version of a document or even using different version of Office tools are the most common collaboration issues.

Finally, there may be a situation in which you focus on a document’s structure and aesthetics more than its content. In the end your document may be well prepared but there is a serious risk that the requirements will be ambiguous, incomplete and/or inconsistent. This can happen when huge amounts of energy are spent solely on keeping the document organized and current. For the rest of this article, visit the Aldec Design and Verification Blog.

Verific: SystemVerilog & VHDL Parsers

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