SAN FRANCISCO--With the International Electron Devices Meeting
(IEDM) hopping this week, a key focus
is low-power electronics, either advances in improving circuit
design or the impact of other design considerations on low power.
Toshiba researchers, for example, will describe how they
lowered power consumption in a mobile CPU by replacing from
high-performance (HP)- SRAMs to spin transfer torque (STT)-MRAMs
using perpendicular (p)-magnetic tunnel junctions.
Japan's Low-power Electronics Association & Project will
describe a new low-power phase change memory.
(You get the idea, and we've previewed some of the conference here
and will cover the proceedings daily during the week
But it seems as scaling continues in conjunction with the battle to
stop leakage current, we're running on an endless hamster wheel:
small circuits and thinner gate oxides create more problems that we
later confront with new processes or materials.
This notion occured to me when I read Steve
Leibson's post on Low-Power Design
a few weeks
ago. He marvels at the battery life of some devices in the old
HP Voyager calculator series. Some participants on an HP board
report their calculators still run, 20-30 years later, on the same
Granted, the materials were different, linewidths more generous and
performance demands not nearly as rigorous as today's handheld
devices. But one would think we'd be staying one step ahead of the leakage
gremlins during the technological march of progress. Wireless sensor
networks today are really smart but in some instances the best-case
scenario for battery life is 10 years (I know, I know: a radio
device, like Zigbee etc. are not calulators, but humor me for a second
So, with that said, here are two questions for you:
- What's the longest continuously running piece of
battery-powered electronics you own?
- Do you think, given the sophistication of "modern" electronics
that we, normalizing for application, can radically improve battery
life in the near future? (Keep in mind, as Leibson points out,
the Voyager series--which drew 0.25 milliwatts and had a
standby leakage of 5 – 10 nanoamperes--was intended to last a
user for one year on one set of batteries).
to detail trigate advances at IEDM
targets next-gen memory technologies
Calling: At IEDM, heat improves flash memory