Chris Spargo’s talk on Heaviside at NEMIG seminar on August 4, 2014

NEMIG Seminar: Oliver Heaviside FRS: The Man, His Work and Memorial Project

13:45 – 14:30, 4th August 2014, Room: M4.13 (CPD Room) Merz Court

A talk followed by discussion session will be held by NEMIG co-founder Christopher Spargo.

The talk will briefly outline Heaviside’s life from childhood until his death, his friendships, relations and recognitions. The talk will then proceed to discuss some of his major achievements such as the reformulation of Maxwell’s equations into today’s known form, the problem of Victorian telegraphy and Heaviside’s solution due to the development of his distributed transmission line model through to some little known aspects of his work but which have major impact. The talk will conclude with an introduction to the Heaviside Memorial Project of which the speaker is the founder and project director. Questions and discussion amongst the group afterwards are most welcome.

Newcastle Electromagnetism Seminar with Ivor Catt and David Walton

I have just held (on Wed. 9th October 2013) a unique research event at Newcastle, a seminar on Electromagnetism, with Ivor Catt and David Walton speaking about their unconventional electromagnetic theory (based on Oliver Heaviside’s notion of energy current).

What motivated me to organize this seminar:

Why Electromagnetism? It is because there is quite a lot of interesting knowledge in the work of Ivor Catt’s team on TEM that could and should be discussed with academics and young researchers working with one or another side of electromagnetic theory in their specific areas, including Power Electronics and Microsystems.

Why Newcastle? Because there is a close connection between David Walton with Newcastle, facts that Oliver Heaviside sent his Morse pulses from Newcastle, good research community here, who have natural curiosity and are not afraid of controversy.

The details of the seminar and the videos of the lectures can be found here:

http://async.org.uk/IvorCatt+DavidWalton.html

 

 

Profile for Horizon 2020 and opportunities for electronics for survival

My article about building computer systems that will live without batteries, by taking energy
from the environment, in Pan European Networks Horizon 2020 series

http://horizon2020projects.com/wp-content/uploads/2013/09/ST8-Microelectronics-System_11254-Pro.pdf

Here is my research group’s partner profile for Horizon 2020 project ideas

http://horizon2020projects.com/partner-profile/partner-profile-h30130/

 

 

ARM’s drive to a near-threshold voltage processor for Internet-of-Things

http://www.eetimes.com/document.asp?doc_id=1319229&

Interesting article.

Though my vision for IoT goes beyond simple energy-efficiency, because it is the same old story – you can be very efficient in perfect conditions (narrow band of power supply).

Instead, it should be about operating in a wide dynamic power range. Therefore energy-modulated computing is a way. Scoop some energy from the environment and drive your logic from a cap! There maybe nothing left for computation if you start to apply smart power regulation. As we say in Russian – “ne do gribov” (no chance for luxury)!

Technical report about survival instincts in electronic systems

 

http://async.org.uk/tech-reports/NCL-EEE-MSD-TR-2013-181.pdf

I wrote this article as a chapter to Peter Cheung’s 60th birthday Festschrift.

Here is the abstract:

The writing of this paper has been inspired by the motivating ideas of
incorporating self-awareness into systems that have been studied by
Prof Cheung in connection to dealing with variability and ageing in
nano-scale electronics. We attempt here to exploit the opportunities for
making systems self-aware, and taking it further, see them in a
biological perspective of survival under harsh operating conditions.
Survivability is developed here in the context of the availability of
energy and power, where the notion of power-modulation will navigate
us towards the incorporation into system design of the mechanisms
analogous to instincts in human brain. These mechanisms are
considered here through a set of novel techniques for reference-free
sensing and elastic memory for data retention. This is only a beginning
in the exploration of system design for survival, and many other
developments such as design of self-aware communication fabric are
further on the way.

Making the most of energy

An article about my group’s research on energy-modulated computing has been published by International Innovation. 

http://async.org.uk/p41-43-Alex-Yakovlev.pdf

International Innovation is the leading global dissemination resource for the wider scientific, technology and research communities, dedicated to disseminating the latest science, research and technological innovations on a global level. More information and a complimentary subscription offer to the publication can be found at: www.researchmedia.eu

New hybrid electronics (caps and async switching logic) as a computing engine for many fractal (power law) processes in nature …

Image

In the simple example of connecting a charged capacitor to a self-timed switching circuit, say a ring oscillator (Fig.1)

we have the process of discharging the cap shown in Fig. 2 (this is taken from the testing of the real silicon – 180nm CMOS). A simple mathematical analysis of this behaviour considers the discretisation, shown in Fig. 3 and 4, which is captured by the hyperbola function in Fig. 5 for V vs time (if we only look at the super-threshold region of the transistors in the inverters). Here K is a ratio of charge sharing between the main cap and a small parasitic cap that is charged at every step of the switching process in the ring chain. A is a constant determined by the inherent parameters of the transistors in the inverters in the oscillator.

One can generalise this analysis to considering a situation with a capacitive source of energy and an arbitrary asynchronous circuit being powered by such a cap. The math characetrisation of such systems will involve use of power laws. Indeed, a simple huperbola described by y=a/x is already a power law. Consider x and y both in log scale, this will be log(y)=log(a)-log(x), which is a straight descending slope lifted up to log(a).

My conjecture is that most of the processes in biology (such a development of biogradients from concentrations of nutrient molecules), economics (bank accounts being debited by its users) etc., they all fit similar patterns. So, isn’t the system of caps and async switching circuits an adequate computational paradigm (and a new type of computers!) for many processes in real life?