Asynchronous Static RAM demo video

It is now possible to see the video of our demo of the Self-timed SRAM, as it works (Write and Read) under a wide range of power supply conditions:

(1) stable levels of Vdd in the range from 1.2V down to 0.4V; and

(2) with a run-time varying supply from our Capacitor-Bank power supply (second box in the setup).

 

Showcase event of Holistic Project 11 Feb 2013 in London

We are preparing ourselves for a showcase event in London (Imperial College) next Monday 11th February 2013:

http://www.nmi.org.uk/events/event-details/277

This showcase marks the completion of a large EPSRC project jointly with Southampton, Imperial and Bristol.

 Newcastle will feature with two talks and two demos there.

Talks:

(1) Summary of Project Outputs (Theme B) –  Alex Yakovlev (Theme B Leader, Newcastle University) at 11:30

(2) Technical Seminar 4: Energy Modulated Computing- Prof Alex Yakovlev (Newcastle University) at 14:30

Demos (at 12:00)
(1) Self-Timed SRAM for Energy Harvesting Systems (Delong Shang and Abdullah Baz)

(2) Reference free Voltage Sensing (Reza Ramezani)

 The SRAM is our key demo, which will involve showing a number of technologies developed in our group, particularly:

– a fully self-timed SRAM, which operates under a wide range of supply voltages (Delong Shang and Abdullah Baz)

– a controllable power supply based on switched cap converters, to produce a wide range of Vdds that can be applied to the SRAM (Xuefu Zhang)

towards survival instincts in computing systems

I have recently talked about developing survival instincts in computing systems. This opens up an interesting paradigm for designing autonomous systems for applications that require them to be on earth, underwater and in space. The conditions for operation of such systems are often harsh, unpredictable and it seems most natural to look for analogies to envisage the ways of their design in the nature, in animals and humans, particularly looking at the nervous systems. Another important pathway to such systems would be to look how energy affects their behaviour and how power levels activate various layers of instinct mechanisms …

These were the ideas that I discussed in my keynote talk at NoCArc’12 in Vancouver  (http://www.unikore.it/nocarc/index.html).

Here are the slides http://www.unikore.it/nocarc/slides/yakovlev.pdfand and video http://www.youtube.com/watch?v=lgcugX44EIg&feature=youtu.befrom

 

SAVVIE: A follow-on to Holistic project

Staying alive in variable, intermittent, low-power environments (SAVVIE)

EPSRC Joint Research Grant: EP/K012908/1 & EP/K011979/1
Institutions: University of Bristol and Newcastle University
Start Date: 1 December 2012Today’s low-power electronic systems are designed to handle a high variability in the power demand, for example during transmissions from miniature wireless sensors. However these systems cannot cope with a highly variable power supply. If they are powered by an ambient energy harvester in an environment where the available power is low and sporadic, the system dies once the energy storage becomes depleted or damaged, with start-up being impossible if the power is not increased to a higher steady level.

This project researches how to design robust and reliable electronics for situations where there is a variable, unreliable source of energy. A number of situations, or states, have been defined, according to the level of depletion of on-board energy storage, and how variable the power supply is. In the most challenging states, for example where the input power is sporadic and spread over a wide range from nW to mW, modern electronics fails. We call this the “survival zone” and are investigating a combination of techniques from the areas of power electronics and asynchronous microelectronic design to allow devices to operate in this zone. Techniques include control circuits that are able to ride through variable voltages, the detection of states, and reconfigurable hardware resources and control algorithms to suit sporadic and sub-microwatt input power. The chief aim of this project is to produce survival zone design methods for the microelectronic design community.

See the project web site:

http://www.bristol.ac.uk/engineering/research/em/research/savvie.html

 

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