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[Amps] Capacitance Amount Formula

To: <amps@contesting.com>
Subject: [Amps] Capacitance Amount Formula
From: davek at medphys.ucl.ac.uk (Dr. David Kirkby)
Date: Mon Feb 10 12:31:27 2003
MorgusMagnificen@aol.com wrote:
> 
> Yes, I do think you are wrong. The concept of 'exact' is context sensitive,
> but not altogether meaningless. This is an issue which causes scientists to
> have a great problem communicating with the scientifically illiterate world.
> 
> For practical purposes, I would call an exact analysis/calculation  one whose
> errors can be specified. "Exact" means that the results which we state are
> less than the precribed error. If you insist that the error go right down to
> zero, then there is nothing in the world that can be specified that precisely
> (this is the uncertainty principle in action). Does that mean that we totally
> abandon the concept of exact? Let me give some familiar examples.
> 
> Suppose I go into a high-precision laboratory and measure the voltage across
> the terminals of a standard cell and report it as 1.376899 volts +/-.000001
> volt (this is doable.) Are you rejecting this as non-exact because I cannot
> get closer than 1uVolt?
> 
> The degree of error is the whole gist of exactness, and in practice, we refer
> to measurments, calculations, etc. as 'exact' if their error is very low. How
> low? That requires judgement and adherence to convention.
> 
> In the case which I stated (a power supply calculation) I was making a fairly
> specific statement which would be understood by most experienced design
> engineers. Namely, before the computer became a desktop tool for every single
> person on the planet, many conceptually simple problems were never solved
> exactly. The most important category of same is problems involving non-linear
> elements, which are not well described by standard physical laws and
> formulas. Pre-computer power supply design was based upon picewise-linear
> approximations to linear circuits, which means that even if the mathematics
> were done exactly, the results would still be approximate. But with a
> computer, you can easily solve the necessary circuit equations to any degree
> of precision, limited only by how many significant figures of precision you
> seek. In practice, we don't need 10 or 100 sig. figures to feel that the
> result is exact.
> 
> So in that respect, when I tell you that I have done an exact solution, what
> I am really saying (this is understood to those who do this kind of
> calculation) is I will calculate the results for you to any specified degree
> of precision. You CANNOT make that statement based on an old-style
> (non-numeric) calculation which invokes approximations in the basic circuit
> equations themselves (e.g. piecewise-linear models). That is the difference.
> 
> Eric vonValtier K8LV

First I would say Eric sent some comments on this subject to me
personally. As far as I could tell, they were NOT copied to the 'amps'
mailing list, hence I only replied to Eric. Therefore others may have
some difficulty in knowing what this is all about.

In essence, Eric said that he had written a program to give an EXACT
solution of this problem. The last paragraph I sent to Eric was: 

* I would add that any EXACT analysis is likely to be an approximation. 
* Do you consider the change of forward voltage drop with junction
* temperature for example ??? Of course it's insignificant, but it does
* mean your analysis is likely not to be exact. Correct me if I'm wrong. 

Clearly Eric feels I am wrong and wants to correct me.

I've not seen Eric's program, but if, like I expect, it is a spice-type
model, where components, such as diodes are modelled as non-linear
equations, then I would maintain the solution it NOT exact. To me at
least, any computer program that models the non-ideal behaviour of
electronic components is not EXACT.

Personally, I don't think one could ever obtain an answer to 100
significant places (as claimed) since there is no way anyone could
possibly know the characteristics of a components that closely. To me at
least, such methods are numerical approximations. I use numerical
approximations in a program of mine
http://atlc.sourceforge.net/
and I would never say the solutions are exact. I can't even say for sure
what the bounds of the errors are (I would like to), I can only say I
have run tests and state the errors found in those tests.
http://atlc.sourceforge.net/accuracy.html
For some problems, one can admittedly state bounds on the errors - I
can't on my program.

If I write a cheque for $101.34, then it is exactly $101.34, but a
numerical approximation of a power supply can never be exact - in my
opinion anyway. Eric feels differently. 

Not only do I think an exact solution is impossible, but neither do I
think it's possible to get a solution to an arbitrary degree of
precision in this case. I would not like to put a figure on how accurate
such an approximation could be, but I doubt a solution could be found to
say better than 4 significant digits, simply because there is no model
that is better than that. Variability between components is likely to be
more than that. 

I would add:

I don't have the interest in pursing the capacitance problem myself. As
far as I'm aware, this has been done many years ago and I don't
personally at this moment in time wish to spend time on the issue.
Anyone seeking an analytical solution should first check the past issues
of journals, as I know this has been done before. I believe the author's
name was something like Schade, but I doubt I have the spelling EXACTLY
right. 

I just made a passing comment that I thought Jeff's analysis was too
simple. If I recall correctly, using a 3-phase supply, the ripple is
about 4% or so with no capacitance at all. Hence I maintain you must
consider the circuit. At least Eric and I agree on that, even if we
don't agree on the definition of EXACT. 


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Dr. David Kirkby PhD,
Senior Research Fellow,
Department of Medical Physics,
University College London,
11-20 Capper St, London, WC1E 6JA.
Tel: 020 7679 6408 Fax: 020 7679 6269
Internal telephone: ext 46408
e-mail davek@medphys.ucl.ac.uk  
Web page: http://www.medphys.ucl.ac.uk/~davek
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