“…. there is
no such a thing as a static electric field in a capacitor. ….”
“ …. displacement
current …. has no physical reality …. ”
http://www.ivorcatt.co.uk/x41h2.pdf
Yakovlev predicts heresy. http://www.ivorcatt.co.uk/x91b.htm
http://www.ivorcatt.co.uk/yak.pdf
http://www.ivorcatt.co.uk/x3b2.pdf
This is http://www.ivorcatt.co.uk/x8b8yak4.htm
A ten year sample of my non-peer reviewed publications during the 50
years of peer review embargo. http://www.ivorcatt.co.uk/x18j1.htm
. A professor or text book writer must not read this material. http://www.ivorcatt.co.uk/x6611.htm
. http://www.ivorcatt.co.uk/x59596.htm
Did the embargo end in October 2018?
http://www.ivorcatt.co.uk/x5cz2.htm
http://www.ivorcatt.co.uk/x6aa.pdf
This is http://www.ivorcatt.co.uk/x8b8yak4.htm
http://www.ivorcatt.co.uk/x854spargo.htm
All centenary Heaviside papers; https://royalsocietypublishing.org/toc/rsta/376/2134
Spargo/Yakovlev; https://royalsocietypublishing.org/doi/10.1098/rsta.2018.0229
Spargo; https://royalsocietypublishing.org/doi/10.1098/rsta.2017.0457
Yakovlev; https://royalsocietypublishing.org/doi/10.1098/rsta.2017.0449
http://www.ivorcatt.co.uk/x89uned.htm
http://www.ivorcatt.co.uk/x5a6.htm
http://www.ivorcatt.co.uk/x8b8yak3.html
http://rsta.royalsocietypublishing.org/content/376/2134/20170449
PHILOSOPHICAL TRANSACTIONS OF THE ROYAL SOCIETY A
MATHEMATICAL, PHYSICAL AND ENGINEERING SCIENCES
Energy
current and computing
Alex Yakovlev
Published 29 October 2018.DOI: 10.1098/rsta.2017.0449
Abstract
In his seminal Electrical
papers, Oliver Heaviside stated ‘We reverse this …' http://www.ivorcatt.co.uk/x3117.htm
referring to the relationship between energy current and state changes in
electrical networks. We explore implications of Heaviside's view upon the state
changes in electronic circuits, effectively constituting computational
processes. Our vision about energy-modulated computing that can be applicable
for electronic systems with energy harvesting is introduced. Examples of analysis
of computational circuits as loads on power sources are presented. We also draw
inspiration from Heaviside's way of using and advancing mathematical methods from
the needs of natural physical phenomena. A vivid example of Heavisidian approach
to the use of mathematics is in employing series where they emerge out of the spatio-temporal
view upon energy flows. Using series expressions, and types of
natural discretization in space and time, we explain the processes of
discharging a capacitive transmission line, first, through a constant resistor
and, second, through a voltage controlled digital circuit. We show that
event-based models, such as Petri nets with an explicit notion of causality
inherent in them, can be instrumental in creating bridges between
electromagnetics and computing.
This article is part of the theme issue ‘Celebrating
125 years of Oliver Heaviside's ‘Electromagnetic Theory’’.
1. Preface
This year
…. ….
Yet, in the year 2013, I
came across Oliver Heaviside's work in full. ….
Next, in the same 2013, by sheer coincidence
I exchanged emails with Mr Ivor Catt about the late Professor David Kinniment,
my colleague and mentor of many years, who studied an interesting and
challenging phenomenon called metastability (connected to the philosophical
problem of choice and the story of Buridan's ass) [4,5] in digital circuits during his 45-year academic
career. From David Kinniment http://www.ivorcatt.co.uk/x8bkinn.pdf
I had known that Ivor Catt was one of the early
discoverers of this phenomenon, which he called The Glitch [6]. http://www.ivorcatt.co.uk/x84gglitch.pdf
; http://www.ivorcatt.co.uk/x1bn.pdf ; http://www.ivorcatt.co.uk/x5a6.htm
. To my amazement, in my conversation with Ivor Catt,
he told me about his other passion. That other work, which had absorbed him for
nearly 40 years, was on developing and promoting his own version of electromagnetic
theory (called Catt-theory or Theory C) [7] [Note 1]. Ivor Catt sent me his book and
several articles in IEEE journals and in the Wireless World magazine.
They showed how
this theory advanced Heaviside's theory (Theory H) of
transverse electromagnetic (TEM) waves and the concept of energy current. I managed to organize a seminar on Electromagnetism
at Newcastle on 9 October 2013 to which I invited Mr Ivor Catt and Dr David
Walton, who worked with Ivor Catt on various parts of his theory, particularly
on demonstrating that a capacitor is a transmission line (TL) [8] http://www.ivorcatt.co.uk/x3b2.pdf
. Coincidentally, David Walton obtained both of his Physics degrees from
Newcastle University, and on the same day of 9 October 2013 there was a
historical 50th anniversary reunion of Electrical Engineering graduates of
1963, some of whom had known David Walton (moreover some again, by coincidence
had known Ivor Catt), so the date was truly momentous. Ivor Catt himself
gave a 2 h lecture [9] [actually 3 hour] which was followed by
an hour-long lecture by David Walton [10]. These lectures showed a demonstration
of the physics of some phenomena, ordinarily known to engineers, such as
charging a capacitor, in an unconventional form—namely by applying a step
voltage to a TL. The well-known exponential charging was the result of an
approximated series of discrete steps http://www.ivorcatt.org/icrwiworld78dec1.htm
caused by the cyclic process of the travelling TEM wave. This theory was supported
by an experiment, known as Wakefield experiment [11], http://www.ivorcatt.co.uk/x343.pdf
; http://viewer.zmags.co.uk/publication/3796f068#/3796f068/74
(p72) which led to the conclusion that there is no such
a thing as a static electric field in a capacitor. [What does “a capacitor” mean? Are
some electric fields static and others dynamic? Horses for [career] courses? - IC] In other words, a capacitor is a form of [!] TL http://www.ivorcatt.co.uk/x3b2.pdf
in which a TEM wave moves with a single fixed
velocity, which is the speed of light in the medium. [Schools and colleges
teach the other form of capacitor, the ones that are not a TL - the better
behaved square ones entered at the middle, like the symbol, which support all
the mathematics.] Below we reproduce both the
derivation of the TL-based capacitor discharge and the description of the Wakefield
experiment.
Those lectures triggered my deep interest in studying
Oliver Heaviside's work and, even more, his whole life. And this very interest
drew me to (then PhD student but now Dr) Christopher Donaghy-Spargo, with whom
we founded NEMIG—northeast Electromagnetics Interest Group, which since 2013
has enjoyed a formidable series of seminars given by scientists, engineers,
historians and entrepreneurs, driven by the ideas and lives of Maxwell,
Heaviside and generally by the exciting field of electromagnetism.
Coming back to the main object
of this paper, which is the relationship between energy current and computing,
I must admit that I had drawn most of inspiration from my familiarization with
Heaviside's work, his legacy in the work of others, and to a great extent by
the fact that both Ivor Catt and David Walton came to studying electromagnetic
theory from the point of view of energy current through their experiences in
dealing with high-speed digital electronics. [ http://www.ivorcatt.co.uk/x66111.pdf
] This electronics does not deal with sine waves. It deals with digital pulses,
which are physical enough to be dealt with in a ‘more physical way' rather than expressing them as an algebraic sum of sine wave harmonics
stretching in the time domain from −∞ to +∞. http://www.ivorcatt.co.uk/x18j197.pdf
. Such pulses have a clear starting point in time and endpoint in time. They
naturally lend themselves to causality between actions, such as a rising edge of
one pulse causes a falling edge of another pulse, for example, as the signal
passes through a logic NOT element (inverter). As I spent most of my own 40
working years exploring asynchronous self-timed digital circuits, and such
circuits could work directly when the power is applied to their vdd lines, I
was firmly attracted by the natural beauty of the ideas of the electromagnetic
theory approach relying basically only on energy current, Poynting vector (S = E × H,
vector product of the electrical field vector and magnetic field vector, representing
the directional energy flux, measured in Watt per square metre; note that it is
sometimes referred to as Umov–Poynting vector) and TEM wave—particularly by its
compactness and parsimony of Occam's Razor.
Another important aspect of my fascination of the energy-current
approach to computational electronics is associated with the fundamental role
that mathematical series play there.
Series, so much loved and revered (to the poetic level!)
by Heaviside, are at the core of the vision of all electromagnetic phenomena
because they relate all state changes in the electromagnetic field with the
geometry of the space and medium.
….
Setting the scene, I would
like to finish this preface with a quote from David Walton's lecture abstract [10]:It is normally recognised that the
postulation of Displacement current by James Clerk Maxwell was a vital step
which led to the understanding that light was an electromagnetic wave. I will
examine the origins of displacement current by consideration of the behaviour
of the dielectric in a lumped capacitor and will show that it has no physical reality. [ http://www.ivorcatt.org/icrwiworld78dec1.htm
] In the absence of an ether there is no rationale for displacement current. We
are then left with a theory which works mathematically but has no basis in
physical reality. I will discuss the remarkable property of empty space in that it has the
ability to accommodate energy. http://www.forrestbishop.mysite.com/EMTV2/EMTvol2p236-7.jpg
. I will then show that Faraday's law and conservation of charge lead to
the existence of electromagnetic energy which travels at a single fixed velocity and has a determined relationship between the
electric and magnetic fields. Because this mathematics is reversible it follows
that these two physical laws can be considered to be consequences of the nature
of electromagnetic energy rather than the reverse.
[space …. has the ability
to accommodate energy. Perhaps the lack of this concept is why I cannot understand either side
in the “debate” over whether the aether exists. Prior to Yakovlev today, where
has this key idea been discussed during the “debate”? Is it irrelevant? - IC]
@@@@@@@@@@@@@@@
Setting the scene, I would like to finish this
preface with a quote from David Walton's lecture abstract [10]:
It is normally recognised that the postulation of Displacement current by James Clerk Maxwell was a vital step which led to the understanding that light was an electromagnetic wave. I will examine the origins of displacement current by consideration of the behaviour of the dielectric in a lumped capacitor and will show that it has no physical reality. In the absence of an ether there is no rationale for displacement current. We are then left with a theory which works mathematically but has no basis in physical reality. I will discuss the remarkable property of empty space in that it has the ability to accommodate energy. I will then show that Faraday's law and conservation of charge lead to the existence of electromagnetic energy which travels at a single fixed velocity and has a determined relationship between the electric and magnetic fields. Because this mathematics is reversible it follows that these two physical laws can be considered to be consequences of the nature of electromagnetic energy rather than the reverse.
2. Energy-modulated
computing
….
….
3. Computing
by accumulating and dividing energy
(a) On the creative role of series
….
(b) Capacitor as transmission line
The configuration that
we want to consider here is shown in figure 4.
Figure 4
Circuit for charging and discharging a capacitor seen as a transmission
line. (Online version in colour.)
Assume, first, that the capacitor
was charged via resistor R to the voltage V (via
switch S1). Then we disconnect S1 and connect S2. The capacitor is a (e.g. coaxial
cable) TL with a characteristic impedance Z0. Let us assume that R ≫ Z0, and
we assume that R is constant. The reflection coefficient at the
right-hand side terminals of the open-ended
….
(c) The Wakefield experiment
An experimental evidence
of the stepwise discharge process for a capacitor modelled by a co-axial cable has
been presented by Ivor Catt in Electronics World in
April 2013 [11]. Here is only a brief recap of this description.
The experiment bears the name of Mr Tony Wakefield of Melbourne, who actually
built the configuration and performed all the measurements. Catt wrote: We now have experimental proof that the so-called steady charged
capacitor is not steady at all. Half the energy in a
charged capacitor is always travelling from right to left at the speed of
light, and the other half from left to right [see figure 5]. The Wakefield experiment
uses a 75-ohm coax 18 meters long. The left-hand end is an open circuit. The
right-hand end is connected to a small, 1 cm long, normally open reed
switch. On the far side of the reed switch is a 75-ohm termination resistor
simulating an infinitely long coaxial cable. A handheld magnet is used to
operate the switch.The coax is charged from a 9 V battery via
2 × 1 megohm resistors, close-coupled at the switch to centre and
ground. The two resistors are used to isolate the relatively long battery wires
from the coax. High value resistors are used to minimize any trickle charge
after the switch is closed.A 2-channel HP 54510B digital sampling scope set to
2 V div−1 vertical and
20 ns div−1 horizontal is used
to capture five images.
Figure 5.
Wakefield experiment set-up: coaxial cable as a cap with tapping points.
(Online version in colour.)
For the reasons of copyright,
I cannot copy these images from Catt's paper. But,
they were taken in the following points: (A) across the terminator 75-ohm
resistor, (B) 25% to the left of the reed switch (4.5 m), (C) 50% to the
left of the reed switch (9 m), (D) 75% to the left of the reed switch
(13.5 m), (E) at the extreme left of the open end of the cable (figure 6).
Figure 6.
Signal plots for the Wakefield experiment, in five different locations. (Online
version in colour.)
….
….
In this analysis, performed
in a Heaviside way, an intermediate factor, called a switching index n,
was introduced
….
(e) On quantization and discretization:
hypotheses
In this section, I will consider
some rather interesting, and possibly controversial, implications of the
transients that we visited above thanks to Catt, Davidson and Walton's derivations.
The artefact that those transients had envelopes that were exponential or
sine/cosine curves was the result of having them been sums of series of steps
in the first place. Furthermore, they originated as series of steps from one,
rather simple but fundamental, postulate—that of the existence of energy
current that is never stationary but always moves with the speed of light
(Catt's Theory of [7]).
Understanding this postulate and the various analyses
of transients in electrical systems is important. It is crucial for settling
with the idea of the world being quantized by virtue of energy currents being
trapped between some reflection points, and the continuous pictures of the
transients are just the results of some step-wise processes.
I deliberately use word ‘quantized' ….
….
For example, from my discussions
with Prof Werner Hofer of Newcastle University, I came to the understanding
that electron is a portion of space, surrounding the nucleus of an atom, which
has trapped energy current, pretty much analogous to a capacitor!
4. Mathematical
models for energy-modulated computing
(a) Modelling Wakefield
experiment in Petri-nets
In this section,
….
….
There is a distinct similarity
with the waveforms from the scope in the Wakefield experiment shown in figure 6. Some discrepancy is caused by
a bit coarse level of granularity
5. Conclusion
More than 125 years ago Oliver
Heaviside stated that energy current was the primal standpoint. In this paper,
we looked at the potential impact of the idea of energy current on the connection
between electromagnetic theory and computing. This connection is manifold. It
permeates through the notion of energy-modulated computing. It also drives the
research into computing which is based on physical phenomena such as causality
and encourages the engineers to develop or use the ‘right kind' of mathematics
to build the bridge between the behaviour of signals in physics and exploiting
this behaviour in computations. The bridge between the physics of
electromagnetism and computing fundamentally lies in Time domain analysis and
appropriate forms of discretization of processes in space and time (cf.
geometric approach of Galileo and Newton [27]). Immediate switching to Frequency domain
analysis for pulse-based signals (and this is what we deal with in computers!)
would bring a ‘wrong type' of mathematics on the way of physics and reality.
This sounds controversial but this is what we could and should learn from
Heaviside.
What about more specific methodological innovation of
this paper? We have now explored two types of step-wise physical processes that
we can link with computing. One is associated with energy-current—this is a
fast computing paradigm associated with the speed of light. An example is the energy-division
in TLs—here we can form oscillations at super-Gigahertz frequencies on a chip.
Another form is associated with the switching of logic gates, where we rely on
mass effects such as movement of charge, and division of electrical energy
associated with it. This is illustrated by the capacitor discharge via digital
switching logic. Here our typical speeds are sub-Gigahertz. These two forms are
orthogonal but can work together, for example in a nested way, like the second
and minute hands of the clock. We could combine the TL discharge (step-wise
discretization of an exponential—inner loop) with a logic circuit switching
(step-wise discretization of hyperbolic discharge—outer loop).
This is a conjecture with which I conclude this
paper. It is based on the stepwise process of TL models of capacitors by Ivor
Catt and his associates and our stepwise processes with a ring oscillator
discharging a capacitor, even a lumped one. These are two orthogonal
discretization operators. The study of their superposition is a subject of our
future work. This will open up some new dimensions for energy-modulated
computing!
Besides, a potentially useful result of this paper in
terms of modelling is the fact that Petri net unfolding can be interpreted as a
waveform of signals whose states are associated with some places in the net.
Acknowledgements
I am grateful to Dr Christopher Donaghy-Spargo of
Durham University for numerous stimulating interactions on the life and work of
Oliver Heaviside and our regular chats about electromagnetism. I would also like to thank Mr Ivor Catt and Dr David Walton for opening the
world of electromagnetics to me in 2013 through the prism of Catt Theory. I am also indebted to my research group at
Newcastle, with whom we are exploring the arcades of energy-modulated
computing. Last but not least, many thanks to the two anonymous reviewers for
their thorough reading of the paper and producing invaluable comments and
corrections.
Footnotes
·
One contribution of 13 to a theme issue
‘Celebrating
125 years of Oliver Heaviside's ‘Electromagnetic Theory’’.
·
Accepted June 9, 2018.
·
© 2018 The Authors.
Published by the Royal Society
under the terms of the Creative Commons Attribution License http://creativecommons.org/licenses/by/4.0/,
which permits unrestricted use, provided the original author and source are credited.
References
1. ↵
1. Yakovlev A
. 2011 Energy-modulated
computing. In Proc. Design Automation & Test in Europe
(DATE), Grenoble, pp. 1–6. Piscataway, NJ: IEEE. (doi:10.1109/DATE.2011.5763216)
2. ↵
1. Yakovlev A,
2. Ramezani R,
3. Mak T
. 2011 Apparatus
and method for voltage sensing. US Patent application US13638330,
28.02.2011, granted US9121871B2 01.09.
3. ↵
1. Ramezani R,
2. Yakovlev A
. 2013 Capacitor
discharging through asynchronous circuit switching. In Proc. IEEE 19th
Int. Symp. on Asynchronous Circuits and Systems, Santa Monica, CA,
pp. 16–22. Piscataway, NJ: IEEE. (doi:10.1109/ASYNC.2013.11)
4. ↵
1. Kinniment DJ
. 2008 Synchronization
and arbitration in digital systems. Chichester, UK: Wiley
Publishing. ; http://www.ivorcatt.co.uk/x1bn.pdf
5. ↵
1. Kinniment DJ
. 2011 He
who hesitates is lost. Newcastle upon Tyne, UK: Newcastle University,
School of Engineering. http://www.ivorcatt.co.uk/x84gglitch.pdf
6. ↵
1. Catt I
. 1966 Time
loss through gating of asynchronous logic signal pulses. IEEE Trans. Electron.
Comput. EC-15,108–111. (doi:10.1109/PGEC.1966.264407)
7. ↵
1. Catt I
. 1995 Electromagnetics
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8. ↵
1. Catt I,
2. Davidson MF,
3. Walton DS
. 1978 Displacement
current – and how to get rid of it. In Wireless World, pp. 51–52. http://www.ivorcatt.co.uk/x3b2.pdf
9. ↵
1. Catt I
. 2013 Advances
in electromagnetic theory. In Video recording of the Electromagnetism Seminar
at Newcastle University, 9 October 2013. See http://async.org.uk/IvorCatt+DavidWalton.html.
10. ↵
1. Walton D
. 2013 Maxwell's
electromagnetic theory. In Video recording of the Electromagnetism Seminar
at Newcastle University, 9 October 2013. See .
11. ↵
1. Catt I
. 2013 The
end of the road. Electronics World, The Centenary Issue 119, 72–74. Seehttps://www.electronicsworld.co.uk/magazine/centenary-issue.
12. ↵
1. Heaviside O
. 1892 Electrical
papers, vol. I. London: Macmillan and Co., p. 438.
13. ↵
1. Shafik R,
2. Yakovlev A,
3. Das S
. 2018 Real-power
computing. IEEE Trans. Comput. 67, 1445–1461. Early
Access. (doi:10.1109/TC.2018.2822697)
14. ↵
1. Yakovlev A,
2. Vivet P,
3. Renaudin M
. 2013 Advances
in asynchronous logic: from principles to GALS & NoC, recent industry
applications, and commercial CAD tools. In Proc. Design Automation & Test
in Europe (DATE), Grenoble, France, pp. 1715–1724. (doi:10.7873/DATE.2013.346)
15. ↵
1. Heaviside O
. 1892. Electrical
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. 1979 Digital
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. 2014 On
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13
December 2018
Volume 376, issue 2134
·
Article
·
Abstract
·
2.
Energy-modulated computing
·
3.
Computing by accumulating and dividing energy
·
4.
Mathematical models for energy-modulated computing
·
Funding
·
eLetters
·
PDF
·
Scopus
·
PubMed
Celebrating
350 years of Philosophical Transactions
Anniversary issue with free commentaries, archive
material, videos and blogs.
1. On
Heaviside's contributions to transmission line theory: waves, diffusion and
energy flux
Christopher
Donaghy-Spargo, Philosophical Transactions A
2. Oliver
Heaviside's electromagnetic theory
Christopher
Donaghy-Spargo et al., Philosophical Transactions A
3. Oliver
Heaviside: an accidental time traveller
Paul
J. Nahin, Philosophical Transactions A
4. Stochastic
electromagnetic field propagation— measurement and modelling
Gabriele
Gradoni et al., Philosophical Transactions A
Mark
W. Verbrugge et al., Journal of The Electrochemical Society
Darryl
Dunn et al., Journal of The Electrochemical Society
3. A
Current Supply with Single Organic Thin-Film Transistor for Charging
Supercapacitors
Vahid
Keshmiri et al., ECS Meeting Abstracts
4. Model-Based
Investigation of Dual Energy Storage Selection for Advanced Start-Stop Vehicles
Zhenli
Zhang et al., ECS Meeting Abstracts
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I
believe the issue may be found at http://rsta.royalsocietypublishing.org/content/376/2134.
The
specific papers you referred to may be found at the following:
Christopher
Donaghy-Spargo -- http://rsta.royalsocietypublishing.org/content/376/2134/20170457
Alex
Yakovlev -- http://rsta.royalsocietypublishing.org/content/376/2134/20170449
Thanks
again for your interest in Royal Society Publishing.
Sign
up to table of contents alerts at http://royalsocietypublishing.org/alerts
Follow
us on Twitter @rsocpublishing
Professor
Massimiliano Pieraccini
http://www.ivorcatt.co.uk/x89uned.htm
I
have now firmed up the definitions.
By
analogy with the AIDS Scam.
1.
HIV does not exist. Neville Hodgkinson, Eleni Papadopulos-Eleopulos
2.
HIV is a passenger virus, not causing AIDS. Duesberg.
Theory
C. Electricity does not help a battery to light a lamp.