The Thin-Film Flexible 6502

While our attention is mostly directed towards ever smaller-integrated silicon circuits providing faster and faster computing, there's another area of integrated electronics that operates at a much lower speed which we should be following. Thin-film flexible circuitry will provide novel ways to place electronics where a bulky or expensive circuit board with traditional components might be too expensive or inappropriate, and Wikichip is here to remind us of a Leuven university team who've created what is claimed to be the fastest thin-film flexible microprocessor yet. Some of you might find it familiar, it's our old friend the 6502.

The choice of an archaic 8-bit processor might seem a strange one, but we can see the publicity advantage -- after all, you're reading about it here because of it being a 6502. Plus there's the advantage of it being a relatively simple and well-understood architecture. It's no match for the MHz clock speeds of the original with an upper limit of 71.4 kHz, but performance is not the most significant feature of flexible electronics. The production technology isn't quite ready for the mainstream so we're unlikely to be featuring flexible Commodore 64s any time soon, but the achievement is the impressive feat of a working thin-film flexible microprocessor.

Meanwhile, if you're curious about the 6502, we took a look at the life of its designer, [Chuck Peddle].

#parts #retrocomputing #6502 #flexiblecircuits #tft

Arm Researchers Announce the PlasticArm

If the Cortex family of embedded microprocessors aren't flexible enough for your designs, an article published this week (click here for the PDF version) in the journal Nature might be of interest. We're not talking flexibility in terms of features, but real, physical flexibility of the microprocessor itself. A research team from Arm Ltd. has developed the PlasticArm, which is a 32-bit processor derived from the Cortex-M0+ family.

They accomplished this by constructing a CPU from metal-oxide thin-film transistors (TFT) on a polyimide substrate, the resultant chip being called a natively flexible microprocessor. While much of the hype focuses on the flexibility aspect, we think the real innovation here is the low cost. The processes used to deposit transistors onto silicon wafers is much more expensive than those on this flexible substrate.

Don't get too excited just yet, because there were some compromises made along the way. Modern microprocessor silicon dies are measured in the tens of microns, but the PlasticArm total die size is a comparatively whopping 9 mm square. The researchers were appropriately focused on the core CPU, and the auxiliary building blocks such as ROM and RAM seem almost an afterthought. With only 456 bytes of program store and 128 bytes of RAM, only the tiniest of applications are suited to this chip. Other compromises were made, such as no internal registers -- they are mapped to the external RAM -- and the CPU runs a lot slower than we're used to, topping out at 29 kHz (note: k not M).

There are certainly some challenges with this new technology, and we won't be designing with these chips any time soon. But it has the potential to offer benefits in certain niche applications where low-cost and/or flexibility is more important than processor speed and performance.

#arm #news #armm0 #flexible #flexiblecircuits