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Estimated reading time: 5 minutes
Elementary, Mr. Watson: The Paradigm Shift of Silicon-to-System Design
Imagine you were asked to build a city. What approach would you take? In the old way, city planners designed each building independently. They focused on making each building strong, aesthetically pleasing, and valuable. But they didn't always consider how all the buildings would fit together in the city. Roads, power lines, and parks were added later, sometimes making the city confusing or complicated to get around.
What if city planners changed their approach? Instead of just focusing on individual buildings, they would plan the entire city simultaneously. They would decide where each building should go, how people would move between them, where to put roads, and how to get electricity and water to every building. By thinking about everything together from the start, the city would be easier to live in, more organized, and better for everyone.
This change in how cities are planned is similar to what's happening in electronics with silicon-to-systems design.
In the past, engineers focused on making each part of a computer or device (like the processor or memory) work as well as possible. They didn't initially think about how these parts would work together in the more extensive system. That could make the final product less efficient, just like a poorly planned city.
Engineers are taking a new approach. Instead of focusing on making each part great, they're thinking from the beginning about how all the parts will work together in the system. That means they consider how the processor, memory, and other parts will connect, how information will flow, and how they will share power and manage heat. Furthermore, they are considering how all those individual parts will fit together into a mechanical enclosure; this new way of designing makes devices work better, use less power, and fit into smaller spaces.
One big reason for this change is that modern devices, like smartphones and laptops, are getting increasingly complicated. The old way of designing each part separately doesn't work either. As I mentioned, engineers now have to think about the entire system to ensure everything works perfectly together.
This silicon-to-systems paradigm shift is a new way of thinking; it’s changing how we build our devices. It helps us create more powerful, efficient, and smaller gadgets that fit into our lives better. Just like a well-planned city makes life easier for the people there, a well-designed electronics system makes our devices work better for us. This change is helping us move forward into a future with more innovative, faster, and more efficient technology.
This paradigm shift is becoming more necessary due to several factors related to the evolution of technology, market demands, and innovation cycles.
Complexity of Modern Electronic Systems
As technology improves, the devices we use daily are becoming more complicated. For example, a modern smartphone has replaced (and this is my short list): Landline phones, alarm clocks, cameras, MP3 players, GPS devices, portable game consoles, calendars and day planners, notebooks and diaries, e-readers, and calculators.
Acceleration of Time-to-Market
They want to get them into stores as quickly as possible. That is called "time-to-market." The faster a new product is available, the sooner people can buy and use it.
In the world of technology, getting your new shiny product to market quickly is very important. Companies want to be the first to offer the newest and coolest technology to attract customers. To do this, they need to work fast and be very organized.
By focusing on silicon to systems, companies can catch problems early and fix them quickly. This way, they don't waste time making changes or dealing with surprises later.
By the way, another method to improve your time-to-market is using new tools and technology. For example, engineers now have advanced computer programs that help them design and test different project phases faster. These tools allow them to see how everything will work before they build it so that they can spot and fix problems early.
A Look at Advanced Packaging
Advanced packaging is the backbone of the silicon to systems. I warn you that I will do an injustice to this topic simply by focusing on a single area. The primary principle of using silicon in a system is to look at the entire product. Silicon to systems includes the chip design (silicon), hardware integration, system architecture, software and firmware, system engineering, user experience and interface, testing and validation, and manufacturing and production. Each area is interweaved with each other.
Advanced packaging, which refers to a collection of manufacturing processes combining multiple semiconductor chips into a single electronic package, is an exciting area with a massive impact on silicon to systems; it is revolutionizing the very foundation of every product on a chip design level—where this all begins. It's a crucial part of the design and manufacturing of chips.
Advanced packaging involves creating a compact and reliable connection between these chips and the rest of the device. Look at this conventionally: In a computer you would have separate chips for the CPU, RAM, I/O controller, storage controllers, etc. Advanced packaging technology combines all those different pieces of silicon into a single chip. Advanced packaging technology has become essential for embedding more functionality into various advanced electronic devices by providing high device density in a small footprint.
Furthermore, advanced packaging is an incredible technology that helps make electronic devices better. Here are several significant advantages:
- Faster and better performance: Advanced packaging helps electronic devices work faster because it lets different parts talk to each other quickly.
- Smaller and lighter devices: We can fit more parts into a smaller space with advanced packaging. That makes your product lighter.
- Cost savings: Although it might cost a bit more initially, advanced packaging can save money in the long run. It makes manufacturing and assembling devices cheaper by using fewer parts and simplifying the process.
- Reliability: Advanced packaging helps make devices more durable and less likely to break. It can protect the electronic parts from heat, moisture, and other damage.
Of course, the big reason is better battery life. Advanced packaging helps extend the battery life of portable devices like phones and laptops by using power more efficiently.
In conclusion, the "silicon to systems" approach is essential for creating modern, high-performance electronic devices. Engineers ensure that each part works together seamlessly by carefully designing and integrating every component—from the tiny silicon chips to the entire system. This approach enhances the performance, efficiency, and reliability of devices and drives technological innovation. Whether it's making smartphones faster, enabling new features, or creating compact and powerful gadgets, silicon to systems ensures that technology meets the demands of today's advanced applications while continuing to evolve for the future.
John Watson is a professor at Palomar College, San Marcos, California.
More Columns from Elementary, Mr. Watson
Elementary, Mr. Watson: Debunking Misconceptions in PCB DesignElementary, Mr. Watson: Mechatronics—The Swiss Army Knife of Engineering
Elementary, Mr. Watson: Cultivating a Culture of Collaboration
Elementary, Mr. Watson: Pushing Design Boundaries
Elementary, Mr. Watson: Why PCB Design Enthusiasts Should Attend IPC APEX EXPO 2024
Elementary, Mr. Watson: Ensuring Design Integrity
Elementary, Mr. Watson: Know the Tradeoffs With Embedded Designs
Elementary, Mr. Watson: Consider Physics When Designing Non-traditional Geometries