Interested in linking to "The past, present and future of PLCs"?
You may use the Headline, Deck, Byline and URL of this article on your Web site. To link to this article, select and copy the HTML code below and paste it on your own Web site.
NOT ALL that long ago (OK, maybe 40 years), the general state of the art for “controllers” was driven by mechanical relay logic. There were “normally open” and “normally closed” contacts, “latching” relays, “stepping” relays, thermal time-delay relays, and so many more. Although most of us didn't realize it at the time, those often surprisingly complex control systems were based on the Boolean Logic that became so familiar as we moved to far more complex “logic gates.” These were composed, first, of individual transistors, then of single-logic gate integrated circuits — ah, those TI 7400 AND, OR, NOR... "DIP" chips (See Figure 1 below) — and finally of today's eminently flexible programmable logic controllers (thanks, Dick Morley!)
|FIGURE 1: BACK IN THE DAY...|
...you could only get a small number of switches on a chip.
Last year, we explored some of the early work that will lead to the next generations of control logic ("Think Small, Really Small"). However, given the double-exponential growth of technology, a year is a very long time, so let’s get an update.
As traditional semiconductor manufacturers move to a 65-nanometer process, “...the smallest modern transistors are [now] no more than a handful of molecules across,” wrote John Markoff in a Dec. 29, 2005, New York Times article. As research marches on, some of last year’s speculative ideas are solidifying into devices that may be in our toolkits in as little as nine years; “...The industry's roadmap [has] growing confidence in new technologies that make electronic switches from single molecules or even single electrons.”
Indeed, Intel already is planning for 10-nanometer processes that may create chips with a trillion “switches.” However, this is seen by the “International Technology Roadmap for Semiconductors, 2005 Edition,” as the most optimistic projection for continued scaling of traditional transistors. So here lies a quandary: how can the growth curve of Moore’s Law continue as our silicon processes reach fundamental physics limits?
The answer is that, as has always been the case, scientists simply refuse to be held back by any limit. They either find a way of extending the limit, or find a way completely around the limit by thinking outside the box and changing all the rules. This is just what they’re beginning to do now, as they approach what is commonly seen as a limit to how small conventional transistors can get before they will no longer work.
Unsurprisingly, this is not a smooth road. As experimental transistors shrink towards individual molecules and atoms, the rules of physics that have sustained high school and college physics and all of our manufacturing efforts to date simply refuse to play by the established rules. For example, they defy traditional beliefs that a switch must be at a specific, discrete value (such as “on” or “off”), and insist on simultaneously holding values of one, zero and every value in-between! (Don't ask; although you can begin to explore this contradiction to common sense by reading "Quantum Superposition." Imagine trying to design with something that can represent all values all the time!
Again, as in the past, scientists are working towards taming such quantum switches, so that, from the end-user (our) perspective, we simply move to yet another level of Tinker Toy complexity that hides the interior details. This is the same way we evolved from designing with relays to single-gate logic chips to PLCs.
Still, how can we visualize what this means to us? At this stage of the game it's virtually impossible to imagine the details of what the next generation of Tinker Toys will be able to do, or how we'll combine the new Tinker Toys into functional solutions. Back when we were happily designing products with TI 7400-series chips, imagine how impossible (for most of us, that is) it would have been to foresee the PLC. Now, again, we sit on the brink of another generation of control logic whose capabilities will be so far beyond that of today's premier PLCs that those devices will eventually feel like the TTL logic chips of older days.
We do know that these new devices will be far faster (due to the smaller distances between logic elements on the chip), and will be far more complex (due to the vastly larger number of logic gates that will fit in a given space.) They also will likely be non-volatile, will draw far less power, and generate far less heat, opening up completely new classes of applications. We’ll see development of switches that rely on the spin of an electron, on its magnetic state, and on its phase state. And some of our future logic seems likely to blend the realms of the inanimate and the animate, as we hijack nature’s biological creations. Already, “single-protein, wet biotransistors” have been demonstrated, and future organic molecular switches hold the potential to switch thousands of time faster than today’s. (In-depth insights into additional potential future logic technologies can be found in "Emerging Research Devices.")
So, as we begin 2006, let's remember that if a project seems too complex or otherwise impossible, most of today's projects would have seemed equally impossible when viewed at the dawn of the PLC. The next generation of control logic might similarly make today's impossible projects quite possible, even easy. And just the beginning, so don't blink!
|About the Author|
ControlGlobal.com is exclusively dedicated to the global process automation market. We report on developing industry trends, illustrate successful industry applications, and update the basic skills and knowledge base that provide the profession's foundation.