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The Newest Advances in EDA: Modular Electronics Design

Zachariah Peterson
|  Created: October 15, 2019  |  Updated: April 5, 2021

Engineer creating a draft for a circuit board

EDA has come a long way since the 1960’s. Image source: Autodesk

Before the birth of EDA, circuit boards and integrated circuits were all designed by hand or some other manual process. The need for more advancement in electronics design made clear the need for automation, a transition which took roughly 10 years and began with drafting in the mid-1970s. The publication of “Introduction to VLSI Systems” by Carver Mead and Lynn Conway in 1980 paved the way for chip design with programming languages that compiled to silicon. From there, EDA became a formidable industry which remains with us to this day.

Since 1981, the year of the birth of commercial EDA, there’ve been several innovations in this industry that have made it easier to build powerful electronics systems. With the continued growth of the semiconductor industry, the importance of EDA cannot be overemphasized. Since that time, we’ve seen innovation in EDA feature sets, as well as integration of existing feature sets into complete platforms. However, one can argue that there has been no radical innovation in the realm of EDA until only recently.

Innovation Challenges in the EDA Software Industry

Today’s EDA tools, when coupled with traditional PCB manufacturing processes, are in many ways responsible for limiting design freedom and limiting innovation. In the early days, electronics and circuit boards were something of an art form, and the layout was designed with fewer limitations or constraints. Engineers were free to design the way they wanted, and eye-catching circuits were beautifully laid out. Today’s EDA tools make it possible to automatically draw our circuits. Although the results may not be as artistic as circuits from decades past, it sure is more efficient, and we can pack more on an electronics board.

The course of innovation in the EDA industry has followed a similar path for a number of companies. It all started as schematic capture, followed by automated and semi-automated PCB routing, simulation capabilities, and 3D rendering. The UX across multiple tools has become roughly homogenized, depending on the level of integration. These innovations have spread across multiple platforms, but little innovation has happened since these critical features were incorporated into popular desktop applications.

The lack of innovation among EDA companies has created an interesting phenomenon in the industry. If you take a look at most EDA tools and platforms, you will observe something familiar with all of them. These platforms all basically do the same thing, and most have roughly the same interface. These platforms are primarily differentiated by the level of integration and compatibility with other design and data management tools they offer. To be fair, the most innovative EDA companies are expanding their capabilities into other areas like FPGA design, real-time MCAD collaboration, and more powerful simulations.

PCB layout between a BGA and a connector

If you’re not an experienced PCB designer, then creating this type of layout can be very time-consuming

Even EDA platforms like Classic Upverter, which differentiates itself by providing a complete browser-based EDA and component management platform, is still in danger of falling into the same loop as desktop EDA applications. Placing these tools online and building a web-based version of desktop tools is a natural innovation in that it provides support for collaboration. Zak Homuth, the founder and CEO of Classic Upverter, has stated that the EDA industry is hostile to innovation in a recent article on Medium.

Modular Electronics Design Tools are Bringing Change

With design reuse becoming more important, EDA tools have allowed designers to package portions of a PCB into libraries, allowing designers to layout boards from different functional blocks with greater productivity. This naturally leads us to modular electronics design, where different modules can be quickly connected together on a single board with predefined routing and component placement.

The new Upverter (previously known as Geppetto) brings a new experience and perspective to the design and development of electronics. Just like other web-based EDA platforms, Upverter is web-based EDA platform, but now Upverter takes design automation to a new level. The modular electronics design tools in Upverter allow anyone to create a board by defining links between premade modules on a PCB.

This provides a simple way for a product designer to focus on the functionality and capabilities of their system, rather than getting mired in the finer points of PCB design. Designers don’t need to worry about how copper connections between each module are laid out on the board; these connections are already well-defined at the board level. The UX in Upverter is unlike the UX in most EDA platforms, and it comes with a simple drag and drop builder that allows you to build powerful boards in a fraction of the time you would spend in other EDA tools.

Geppetto’s modular electronics design UX

The modular electronics design UX in Upverter

Upverter focuses on speed, giving designers first-mover advantage with their new products. The industry-standard COMs available in Upverter can be used in applications ranging from industrial systems to AI, IoT, medical devices, and 5G systems. Because the on-board interconnects between COMs are so well defined, you’ll know that your design will be production-ready and will function as desired.

The modular electronics design tools in Upverter are helping to change the EDA landscape, allowing any engineer to streamline the design and production process for new products. You’ll be able to quickly place industry-standard COMs and modules in your board and easily link them together when you work with Upverter. Your designs will also be production ready and adaptable for nearly any application.

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About Author

About Author

Zachariah Peterson has an extensive technical background in academia and industry. He currently provides research, design, and marketing services to companies in the electronics industry. Prior to working in the PCB industry, he taught at Portland State University and conducted research on random laser theory, materials, and stability. His background in scientific research spans topics in nanoparticle lasers, electronic and optoelectronic semiconductor devices, environmental sensors, and stochastics. His work has been published in over a dozen peer-reviewed journals and conference proceedings, and he has written 2500+ technical articles on PCB design for a number of companies. He is a member of IEEE Photonics Society, IEEE Electronics Packaging Society, American Physical Society, and the Printed Circuit Engineering Association (PCEA). He previously served as a voting member on the INCITS Quantum Computing Technical Advisory Committee working on technical standards for quantum electronics, and he currently serves on the IEEE P3186 Working Group focused on Port Interface Representing Photonic Signals Using SPICE-class Circuit Simulators.

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