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|Jahr=1893
 
|Jahr=1893
 
|Titel=Electromagnetic theory
 
|Titel=Electromagnetic theory
|Stichworte=electromagnetic theory; magnetism; electricity; theory; vector analysis; electric waves;
+
|Stichworte=electromagnetic theory; magnetism; electricity; theory; vector analysis; electric waves; english;
 
|Band=1
 
|Band=1
 
|Verlag=“The Electrician” printing and publishing company, limited
 
|Verlag=“The Electrician” printing and publishing company, limited
 
|Ort=London
 
|Ort=London
 
|Seiten=1-466
 
|Seiten=1-466
 +
|Deutsche Übersetzung=Elektromagnetische Theorie
 
|Originalsprache=en
 
|Originalsprache=en
 
|Zusammenfassung=Chapter I. Introduction.<br/>Chapter II. Outline of the electromagnetic connections.<br/>Appendix A: The rotational ether in its application to electromagnetism.<br/>Chapter III. The elements of vectorial algebra and analysis.<br/>Chapter IV. Theory of plane electromagnetic waves.<br/>Appendix B: A gravitational and electromagnetic analogy.
 
|Zusammenfassung=Chapter I. Introduction.<br/>Chapter II. Outline of the electromagnetic connections.<br/>Appendix A: The rotational ether in its application to electromagnetism.<br/>Chapter III. The elements of vectorial algebra and analysis.<br/>Chapter IV. Theory of plane electromagnetic waves.<br/>Appendix B: A gravitational and electromagnetic analogy.
Zeile 19: Zeile 20:
 
Owing, however, to the necessity of much introductory  
 
Owing, however, to the necessity of much introductory  
 
repetition, this plan was at once found to be impracticable,  
 
repetition, this plan was at once found to be impracticable,  
and was, by request, greatly modified. The result is some-
+
and was, by request, greatly modified. The result is something approaching a connected treatise on electrical theory,  
thing approaching a connected treatise on electrical theory,  
 
 
though without the strict formality usually associated with  
 
though without the strict formality usually associated with  
 
a treatise. As critics cannot always find time to read more  
 
a treatise. As critics cannot always find time to read more  
Zeile 34: Zeile 34:
 
The second chapter, pp. 20 to 131, consists of an outline  
 
The second chapter, pp. 20 to 131, consists of an outline  
 
scheme of the fundamentals of electromagnetic theory from  
 
scheme of the fundamentals of electromagnetic theory from  
the Faraday-Maxwell point of view, with some small modifi-
+
the Faraday-Maxwell point of view, with some small modifications and extensions upon Maxwell's equations. It is done  
cations and extensions upon Maxwell's equations. It is done  
 
 
in terms of my rational units, which furnish the only way ot  
 
in terms of my rational units, which furnish the only way ot  
carrying out the idea of lines and tubes of force in a con-
+
carrying out the idea of lines and tubes of force in a consistent and intelligible manner. It is also done mainly in  
sistent and intelligible manner. It is also done mainly in  
 
 
terms of vectors, for the sufficient reason that vectors are  
 
terms of vectors, for the sufficient reason that vectors are  
 
the main subject of investigation. It is also done in the  
 
the main subject of investigation. It is also done in the  
 
duplex form I introduced in 1885, whereby the electric and  
 
duplex form I introduced in 1885, whereby the electric and  
magnetic sides of electromagnetism are symmetrically ex-
+
magnetic sides of electromagnetism are symmetrically exhibited and connected, whilst the "forces" and "fluxes"  
hibited and connected, whilst the "forces" and "fluxes"  
 
 
are the objects of immediate attention, instead of the  
 
are the objects of immediate attention, instead of the  
 
potential functions which are such powerful aids to obscuring  
 
potential functions which are such powerful aids to obscuring  
Zeile 57: Zeile 54:
 
vectorial ideas instead of quaternionic, it is needless to say  
 
vectorial ideas instead of quaternionic, it is needless to say  
 
more on the point here. But I must add that it has been  
 
more on the point here. But I must add that it has been  
gratifying to discover among mathematical physicists a con-
+
gratifying to discover among mathematical physicists a considerable and rapidly growing appreciation of vector algebra  
siderable and rapidly growing appreciation of vector algebra  
 
 
on these lines; and moreover, that students who had found  
 
on these lines; and moreover, that students who had found  
 
quaternions quite hopeless could understand my vectors very  
 
quaternions quite hopeless could understand my vectors very  
well. Regarded as a treatise on vectorial algebra, this chap-
+
well. Regarded as a treatise on vectorial algebra, this chapter has manifest shortcomings. It is only the first rudiments  
ter has manifest shortcomings. It is only the first rudiments  
 
 
of the subject. Nevertheless, as the reader may see from the  
 
of the subject. Nevertheless, as the reader may see from the  
 
applications made, it is fully sufficient for ordinary use in  
 
applications made, it is fully sufficient for ordinary use in  
Zeile 77: Zeile 72:
 
theory of plane electromagnetic waves, and, being mainly  
 
theory of plane electromagnetic waves, and, being mainly  
 
descriptive, may perhaps be read with profit by many who  
 
descriptive, may perhaps be read with profit by many who  
are unable to tackle the mathematical theory comprehen-
+
are unable to tackle the mathematical theory comprehensively. It may be also useful to have results of mathematical  
sively. It may be also useful to have results of mathematical  
 
 
reasoning expanded into ordinary language for the benefit of  
 
reasoning expanded into ordinary language for the benefit of  
 
mathematicians themselves, who are sometimes too apt to  
 
mathematicians themselves, who are sometimes too apt to  
Zeile 85: Zeile 79:
 
waves. Some examples in illustration thereof have been  
 
waves. Some examples in illustration thereof have been  
 
crowded out, and will probably be given in the next volume.  
 
crowded out, and will probably be given in the next volume.  
I have, however, included in the present volume the applica-
+
I have, however, included in the present volume the application of the theory (in duplex form) to straight wires, and  
tion of the theory (in duplex form) to straight wires, and  
 
 
also an account of the effects of self-induction and leakage,  
 
also an account of the effects of self-induction and leakage,  
 
which are of some significance in present practice as well  
 
which are of some significance in present practice as well  
 
as in possible future developments. There have been some  
 
as in possible future developments. There have been some  
very queer views promulgated officially in this country con-
+
very queer views promulgated officially in this country concerning the speed of the current, the impotence of selfinduction, and other material points concerned. No matter  
cerning the speed of the current, the impotence of self-
 
induction, and other material points concerned. No matter  
 
 
how eminent they may be in their departments, officials need  
 
how eminent they may be in their departments, officials need  
 
not be scientific men. It is not expected of them. But  
 
not be scientific men. It is not expected of them. But  
 
should they profess to be, and lay down the law outside their  
 
should they profess to be, and lay down the law outside their  
 
knowledge, and obstruct the spreading of views they cannot  
 
knowledge, and obstruct the spreading of views they cannot  
understand, their official weight imparts a fictitious impor-
+
understand, their official weight imparts a fictitious importance to their views, and acts most deleteriously in propagating  
tance to their views, and acts most deleteriously in propagating  
 
 
error, especially when their official position is held up as a  
 
error, especially when their official position is held up as a  
 
screen to protect them from criticism. But in other countries  
 
screen to protect them from criticism. But in other countries  
Zeile 104: Zeile 94:
  
 
Having thus gone briefly through the book, it is desirable  
 
Having thus gone briefly through the book, it is desirable  
to say a few words regarding the outline sketch of electro-
+
to say a few words regarding the outline sketch of electromagnetics in the second chapter. Two diverse opinions have  
magnetics in the second chapter. Two diverse opinions have  
 
 
been expressed about it. On the one hand, it has been said  
 
been expressed about it. On the one hand, it has been said  
to be too complicated. This probably came from a simple-
+
to be too complicated. This probably came from a simpleminded man. On the other hand, it has been said to be too  
minded man. On the other hand, it has been said to be too  
 
 
simple. This objection, coming from a wise man, is of  
 
simple. This objection, coming from a wise man, is of  
 
weight, and demands some notice.  
 
weight, and demands some notice.  
  
 
Whether a theory can be rightly described as too simple  
 
Whether a theory can be rightly described as too simple  
depends materially upon what it professes to be. The pheno-
+
depends materially upon what it professes to be. The phenomena involving electromagnetism may be roughly divided  
mena involving electromagnetism may be roughly divided  
 
 
into two classes, primary and secondary. Besides the main  
 
into two classes, primary and secondary. Besides the main  
 
primary phenomena, there is a large number of secondary  
 
primary phenomena, there is a large number of secondary  
Zeile 134: Zeile 121:
 
thereof for the secondary. The theory of electromagnetism  
 
thereof for the secondary. The theory of electromagnetism  
 
is then a primary theory, a skeleton framework corresponding  
 
is then a primary theory, a skeleton framework corresponding  
to a possible state of things simpler than the real in innu-
+
to a possible state of things simpler than the real in innumerable details, but suitable for the primary effects, and  
merable details, but suitable for the primary effects, and  
 
 
furnishing a guide to special extensions. From this point of  
 
furnishing a guide to special extensions. From this point of  
 
view, the theory cannot be expressed too simply, provided it  
 
view, the theory cannot be expressed too simply, provided it  
Zeile 144: Zeile 130:
 
clarifying in complicated cases as well as in simple ones. It  
 
clarifying in complicated cases as well as in simple ones. It  
 
is essentially Maxwell's theory, but there are some differences.  
 
is essentially Maxwell's theory, but there are some differences.  
Some are changes of form only ; for instance, the rationalisa-
+
Some are changes of form only ; for instance, the rationalisation effected by changing the units, and the substitution ol  
tion effected by changing the units, and the substitution ol  
+
the second circuital law for Maxwell's equation of electromotive force involving the potentials, etc. But there is one  
the second circuital law for Maxwell's equation of electro-
 
motive force involving the potentials, etc. But there is one  
 
 
change in particular which raises a fresh question. What is  
 
change in particular which raises a fresh question. What is  
 
Maxwell's theory? or, What should we agree to understand  
 
Maxwell's theory? or, What should we agree to understand  
 
by Maxwell's theory ?  
 
by Maxwell's theory ?  
 
 
 
PREFACE. vii.
 
  
 
The first approximation to the answer is to say, There is  
 
The first approximation to the answer is to say, There is  
Zeile 165: Zeile 145:
 
that there may be much difference of opinion as to what his  
 
that there may be much difference of opinion as to what his  
 
theory is. It may be, and has been, differently interpreted by  
 
theory is. It may be, and has been, differently interpreted by  
different men, which is a sign that it is not set forth in a per-
+
different men, which is a sign that it is not set forth in a perfectly clear and unmistakeable form. There are many obscurities and some inconsistencies. Speaking for myself, it was  
fectly clear and unmistakeable form. There are many obscuri-
 
ties and some inconsistencies. Speaking for myself, it was  
 
 
only by changing its form of presentation that I was able to  
 
only by changing its form of presentation that I was able to  
 
see it clearly, and so as to avoid the inconsistencies. Now  
 
see it clearly, and so as to avoid the inconsistencies. Now  
Zeile 192: Zeile 170:
 
similar change in the first, or Maxwell's circuital law. An  
 
similar change in the first, or Maxwell's circuital law. An  
 
independent formal proof is unnecessary ; the similarity of  
 
independent formal proof is unnecessary ; the similarity of  
 
 
 
Vlll. PREFACE.
 
 
 
form and of the conditions of motion show that Maxwell's  
 
form and of the conditions of motion show that Maxwell's  
 
auxiliary term in the electromotive force, viz., VqB (the  
 
auxiliary term in the electromotive force, viz., VqB (the  
Zeile 230: Zeile 203:
 
light referred to the external ether be V//* + v(l -ft~ 2 ), if v  
 
light referred to the external ether be V//* + v(l -ft~ 2 ), if v  
 
is the speed of the water. The experiments of Fizeau and  
 
is the speed of the water. The experiments of Fizeau and  
Michelson have shown that this result is at least approxi-
+
Michelson have shown that this result is at least approximately true, and there is other evidence to support FresnePs  
mately true, and there is other evidence to support FresnePs  
 
 
hypothesis, at least in a generalised form. But, in the case  
 
hypothesis, at least in a generalised form. But, in the case  
 
 
 
PREFACE. is.
 
 
 
of water, the additional speed of light due to the motion of  
 
of water, the additional speed of light due to the motion of  
 
the water might be ^v instead of (1 - fir 2 ) v, without much  
 
the water might be ^v instead of (1 - fir 2 ) v, without much  
disagreement. Now suppose we examine the matter electro-
+
disagreement. Now suppose we examine the matter electromagnetically, and enquire what the increased speed through  
magnetically, and enquire what the increased speed through  
 
 
a moving dielectric should be. If we follow Maxwell's  
 
a moving dielectric should be. If we follow Maxwell's  
equations literally, we shall find that the extra speed is |r,  
+
equations literally, we shall find that the extra speed is 1/2ν,  
 
provided i?/V is small. This actually seems to corroborate  
 
provided i?/V is small. This actually seems to corroborate  
 
the experimental results. But the argument is entirely a  
 
the experimental results. But the argument is entirely a  
Zeile 274: Zeile 240:
 
and Michelson's results is that a transparent medium like  
 
and Michelson's results is that a transparent medium like  
 
water cannot be regarded as (in the electromagnetic theory)  
 
water cannot be regarded as (in the electromagnetic theory)  
 
 
 
X. PREFACE.
 
 
 
a simple medium like the ether, at least for waves of light,  
 
a simple medium like the ether, at least for waves of light,  
 
and that a secondary theory is necessary. Fresnel's sagacious  
 
and that a secondary theory is necessary. Fresnel's sagacious  
Zeile 288: Zeile 249:
 
with whirling discs, though on the other hand must not be  
 
with whirling discs, though on the other hand must not be  
 
forgotten the contrary conclusion arrived at by Michelson as  
 
forgotten the contrary conclusion arrived at by Michelson as  
to the absence of relative motion between the earth and sur-
+
to the absence of relative motion between the earth and surrounding ether. But if the ether be stationary, Fresnel's  
rounding ether. But if the ether be stationary, Fresnel's  
+
speculation is roughly equivalent to supposing that the molecules of transparent matter act like little condensers in increas-  
speculation is roughly equivalent to supposing that the mole-'
 
cules of transparent matter act like little condensers in increas-  
 
 
ing the permittivity, and that the matter, when in motion,  
 
ing the permittivity, and that the matter, when in motion,  
 
only carries forward the increased permittivity. But however  
 
only carries forward the increased permittivity. But however  
Zeile 297: Zeile 256:
 
primary theory that can be trusted within its limits. Whether  
 
primary theory that can be trusted within its limits. Whether  
 
Maxwell's theory will last, as a sufficient and satisfactory  
 
Maxwell's theory will last, as a sufficient and satisfactory  
primary theory upon which the numerous secondary deve-
+
primary theory upon which the numerous secondary developments required may be grafted, is a matter for the future  
lopments required may be grafted, is a matter for the future  
 
 
to determine. Let it not be forgotten that Maxwell's theory  
 
to determine. Let it not be forgotten that Maxwell's theory  
 
is only the first step towards a full theory of the .ether ; and,  
 
is only the first step towards a full theory of the .ether ; and,  
Zeile 305: Zeile 263:
 
tation.  
 
tation.  
  
There is one other matter that demands notice in conclu-
+
There is one other matter that demands notice in conclusion. It is not long since it was taken for granted that the  
sion. It is not long since it was taken for granted that the  
 
 
common electrical units were correct. That curious and  
 
common electrical units were correct. That curious and  
 
obtrusive constant 4?r was considered by some to be a sort of  
 
obtrusive constant 4?r was considered by some to be a sort of  
Zeile 315: Zeile 272:
 
English, the common system of electrical units involves an  
 
English, the common system of electrical units involves an  
 
irrationality of the same kind as would be brought into the  
 
irrationality of the same kind as would be brought into the  
 
 
 
PREFACE. X i.
 
 
 
metric system of weights and measures, were we to define  
 
metric system of weights and measures, were we to define  
 
the unit area to be the area, not of a square with unit side,  
 
the unit area to be the area, not of a square with unit side,  
Zeile 349: Zeile 301:
 
by rationalising the units requires some consideration to fully  
 
by rationalising the units requires some consideration to fully  
 
appreciate, it is, on the other hand, very easy to overestimate  
 
appreciate, it is, on the other hand, very easy to overestimate  
the difficulty of making the change. Some temporary incon-
+
the difficulty of making the change. Some temporary inconvenience is necessary, of course. For a time there would be  
venience is necessary, of course. For a time there would be  
 
 
two sorts of ohms, &c., the old style and the new (or rational).  
 
two sorts of ohms, &c., the old style and the new (or rational).  
 
But it is not a novelty to have two sorts of ohms. There  
 
But it is not a novelty to have two sorts of ohms. There  
Zeile 357: Zeile 308:
 
going to be made, and with ever increasing rapidity, by reason  
 
going to be made, and with ever increasing rapidity, by reason  
 
of the enormously rapid extension of electrical industries.  
 
of the enormously rapid extension of electrical industries.  
 
 
 
XII. PREFACE.
 
  
 
Old style instruments would very soon be in a minority, and  
 
Old style instruments would very soon be in a minority, and  
 
then disappear, like the pins. I do not know that there is a  
 
then disappear, like the pins. I do not know that there is a  
more important practical question than this one of rational-
+
more important practical question than this one of rationalising the units, on account of its far-reaching effect, and  
ising the units, on account of its far-reaching effect, and  
 
 
think that whilst the change could be made now with ease  
 
think that whilst the change could be made now with ease  
 
(with a will, of course), it will be far more troublesome if  
 
(with a will, of course), it will be far more troublesome if  

Aktuelle Version vom 13. Mai 2020, 16:17 Uhr

Heaviside, O. 1893: Electromagnetic theory. Bd. 1, “The Electrician” printing and publishing company, limited, London, S. 1-466 ( https:/​/​archive.​org/​stream/​electromagnetict01heavrich#page/​n5/​mode/​2up, abgerufen am 6. Juli 2018). (Übersetzung: Elektromagnetische Theorie)


Zusammenfassung: Chapter I. Introduction.
Chapter II. Outline of the electromagnetic connections.
Appendix A: The rotational ether in its application to electromagnetism.
Chapter III. The elements of vectorial algebra and analysis.
Chapter IV. Theory of plane electromagnetic waves.
Appendix B: A gravitational and electromagnetic analogy.

(OCR text) PREFACE.

THIS work was originally meant to be a continuation of the series "Electromagnetic Induction and its Propagation," published in The Electrician in 1885-6-7, but left unfinished. Owing, however, to the necessity of much introductory repetition, this plan was at once found to be impracticable, and was, by request, greatly modified. The result is something approaching a connected treatise on electrical theory, though without the strict formality usually associated with a treatise. As critics cannot always find time to read more than the preface, the following remarks may serve to direct their attention to some of the leading points in this volume.

The first chapter will, I believe, be found easy to read, and may perhaps be useful to many men who are accustomed to show that they are practical by exhibiting their ignorance of the real meaning of scientific and mathematical methods of enquiry.

The second chapter, pp. 20 to 131, consists of an outline scheme of the fundamentals of electromagnetic theory from the Faraday-Maxwell point of view, with some small modifications and extensions upon Maxwell's equations. It is done in terms of my rational units, which furnish the only way ot carrying out the idea of lines and tubes of force in a consistent and intelligible manner. It is also done mainly in terms of vectors, for the sufficient reason that vectors are the main subject of investigation. It is also done in the duplex form I introduced in 1885, whereby the electric and magnetic sides of electromagnetism are symmetrically exhibited and connected, whilst the "forces" and "fluxes" are the objects of immediate attention, instead of the potential functions which are such powerful aids to obscuring and complicating the subject, and hiding from view useful and sometimes important relations.

The third chapter, pp. 132 to 305, is devoted to vector algebra and analysis, in the form used by me in my former papers. As I have at the beginning and end of this chapter stated my views concerning the unsuitability of quaternions for physical requirements, and my preference for a vector algebra which is based upon the vector and is dominated by vectorial ideas instead of quaternionic, it is needless to say more on the point here. But I must add that it has been gratifying to discover among mathematical physicists a considerable and rapidly growing appreciation of vector algebra on these lines; and moreover, that students who had found quaternions quite hopeless could understand my vectors very well. Regarded as a treatise on vectorial algebra, this chapter has manifest shortcomings. It is only the first rudiments of the subject. Nevertheless, as the reader may see from the applications made, it is fully sufficient for ordinary use in the mathematical sciences where the Cartesian mathematics is usually employed, and we need not trouble about more advanced developments before the elements are taken up. Now, there are no treatises on vector algebra in existence yet, suitable for mathematical physics, and in harmony with the Cartesian mathematics (a matter to which I attach the greatest importance). I believe, therefore, that this chapter may be useful as a stopgap.

The fourth chapter, pp. 306 to 466, is devoted to the theory of plane electromagnetic waves, and, being mainly descriptive, may perhaps be read with profit by many who are unable to tackle the mathematical theory comprehensively. It may be also useful to have results of mathematical reasoning expanded into ordinary language for the benefit of mathematicians themselves, who are sometimes too apt to work out results without a sufficient statement of their meaning and effect. But it is only introductory to plane waves. Some examples in illustration thereof have been crowded out, and will probably be given in the next volume. I have, however, included in the present volume the application of the theory (in duplex form) to straight wires, and also an account of the effects of self-induction and leakage, which are of some significance in present practice as well as in possible future developments. There have been some very queer views promulgated officially in this country concerning the speed of the current, the impotence of selfinduction, and other material points concerned. No matter how eminent they may be in their departments, officials need not be scientific men. It is not expected of them. But should they profess to be, and lay down the law outside their knowledge, and obstruct the spreading of views they cannot understand, their official weight imparts a fictitious importance to their views, and acts most deleteriously in propagating error, especially when their official position is held up as a screen to protect them from criticism. But in other countries there is, I find, considerable agreement with my views.

Having thus gone briefly through the book, it is desirable to say a few words regarding the outline sketch of electromagnetics in the second chapter. Two diverse opinions have been expressed about it. On the one hand, it has been said to be too complicated. This probably came from a simpleminded man. On the other hand, it has been said to be too simple. This objection, coming from a wise man, is of weight, and demands some notice.

Whether a theory can be rightly described as too simple depends materially upon what it professes to be. The phenomena involving electromagnetism may be roughly divided into two classes, primary and secondary. Besides the main primary phenomena, there is a large number of secondary ones, partly or even mainly electromagnetic, but also trenching upon other physical sciences. Now the question arises whether it is either practicable or useful to attempt to construct a theory of such comprehensiveness as to include the secondary phenomena, and to call it the theory of electromagnetism. I think not, at least at present. It might perhaps be done ii the secondary phenomena were thoroughly known ; but their theory is so much more debatable than that of the primary phenomena that it would be an injustice to the latter to too closely amalgamate them. Then again, the expression of the theory would be so unwieldy as to be practically useless ; the major phenomena would be apparently swamped by the minor. It would, therefore, seem best not to attempt too much, but to have a sort of abstract electromagnetic scheme for the primary phenomena only, and have subsidiary extensions thereof for the secondary. The theory of electromagnetism is then a primary theory, a skeleton framework corresponding to a possible state of things simpler than the real in innumerable details, but suitable for the primary effects, and furnishing a guide to special extensions. From this point of view, the theory cannot be expressed too simply, provided it be a consistent scheme, and be sufficiently comprehensive to serve for a framework. I believe the form of theory in the second chapter will answer the purpose. It is especially useful in the duplex way of exhibiting the relations, which is clarifying in complicated cases as well as in simple ones. It is essentially Maxwell's theory, but there are some differences. Some are changes of form only ; for instance, the rationalisation effected by changing the units, and the substitution ol the second circuital law for Maxwell's equation of electromotive force involving the potentials, etc. But there is one change in particular which raises a fresh question. What is Maxwell's theory? or, What should we agree to understand by Maxwell's theory ?

The first approximation to the answer is to say, There is Maxwell's book as he wrote it ; there is his text, and there are his equations : together they make his theory. But when we come to examine it closely, we find that this answer is unsatisfactory. To begin with, it is sufficient to refer to papers by physicists, written say during the twelve years following the first publication of Maxwell's treatise, to see that there may be much difference of opinion as to what his theory is. It may be, and has been, differently interpreted by different men, which is a sign that it is not set forth in a perfectly clear and unmistakeable form. There are many obscurities and some inconsistencies. Speaking for myself, it was only by changing its form of presentation that I was able to see it clearly, and so as to avoid the inconsistencies. Now there is no finality in a growing science. It is, therefore, impossible to adhere strictly to Maxwell's theory as he gave it to the world, if only on account of its inconvenient form. But it is clearly not admissible to make arbitrary changes in it and still call it his. He might have repudiated them utterly. But if we have good reason to believe that the theory as stated in his treatise does require modification to make it self-consistent, and to believe that he would have admitted the necessity of the change when pointed out to him, then I think the resulting modified theory may well be called Maxwell's.

Now this state of things is exemplified by his celebrated circuital law defining the electric current in terms of magnetic force. For although he did not employ the other, or second circuital law, yet it may be readily derived from his equation of electromotive force ; and when this is done, and the law made a fundamental one, we readily see that the change it suffers in passing from the case of a stationary to that of a moving medium should be necessarily accompanied by a similar change in the first, or Maxwell's circuital law. An independent formal proof is unnecessary ; the similarity of form and of the conditions of motion show that Maxwell's auxiliary term in the electromotive force, viz., VqB (the motional electric force), where q is the velocity of the medium and B the induction, requires the use of a similar auxiliary term in the first circuital law, viz., VDq, the motional magnetic force, D being the displacement. And there is yet another change sometimes needed. For whilst B is circuital, so that a convective magnetic current does not appear in the second circuital equation, D is not always circuital, and convective electric current must therefore appear in the first circuital equation. For the reason just mentioned, it is the theory as thus modified that I consider to represent the true Maxwellian theory, with the other small changes required to make a fit. But further than this I should not like to go, because, having made a fit, it is not necessary, and because it would be taking too great a liberty to make additions without the strongest reason to consider them essential.

The following example, which has been suggested to me by remarks in Prof. Lodge's recent paper on " Aberration Problems," referring to a previous investigation of Prof. J. J. Thomson, will illustrate the matter in question. It is known that if V be the speed of light through ether, the speed through a stationary transparent body, say water, is V//A, if p is the refractive index. Now what is the speed when the water is itself moving in the same direction as the light waves ? This is a very old problem. Fresnel considered that the external ether was stationary, and that the ether was /a 2 times as dense in the water as outside, and that, when moving, the water only carried forward with it the extra ether it contained (or equivalently). This makes the speed of light referred to the external ether be V//* + v(l -ft~ 2 ), if v is the speed of the water. The experiments of Fizeau and Michelson have shown that this result is at least approximately true, and there is other evidence to support FresnePs hypothesis, at least in a generalised form. But, in the case of water, the additional speed of light due to the motion of the water might be ^v instead of (1 - fir 2 ) v, without much disagreement. Now suppose we examine the matter electromagnetically, and enquire what the increased speed through a moving dielectric should be. If we follow Maxwell's equations literally, we shall find that the extra speed is 1/2ν, provided i?/V is small. This actually seems to corroborate the experimental results. But the argument is entirely a deceptive one. Maxwell's theory is a theory of propagation through a simple medium. Fundamentally it is the ether, but when we pass to a solid or liquid dielectric it is still to be regarded as a simple medium in the same sense, because the only change occurring in the equations is in the value of one or both ethereal constants, the permittivity and inductivity practically only the first. Consequently, if we find, as above, that when the medium is itself moved, its velocity is not superimposed upon that of the velocity of waves through the medium at rest, the true inference is that there is something wrong with the theory. For all motion is relative, and it is an axiomatic truth that there should be superimposition of velocities, so that V//* + v should be the velocity in the above case according to any rational theory of propagation through a simple medium, the extra velocity being the full v t instead of Jv. And, as a matter of fact, if we employ the modified or corrected circuital law above referred to, we do obtain full superimposition of velocities.

This example shows the importance of having a simply expressed and sound primary theory. For if the auxiliary hypotheses required to explain outstanding or secondary phe- nomena be conjoined to an imperfect primary theory we shall surely be led to wrong results. Whereas if the primary theory be good, there is at least a chance of its extension by auxiliary hypotheses being also good. The true conclusion from Fizeau and Michelson's results is that a transparent medium like water cannot be regarded as (in the electromagnetic theory) a simple medium like the ether, at least for waves of light, and that a secondary theory is necessary. Fresnel's sagacious speculation is justified, except indeed as regards its form of expression. The ether, for example, may be identical inside and outside the body, and the matter slip through it without sensibly affecting it. At any rate the evidence that this is the case preponderates, the latest being Prof. Lodge's experiments with whirling discs, though on the other hand must not be forgotten the contrary conclusion arrived at by Michelson as to the absence of relative motion between the earth and surrounding ether. But if the ether be stationary, Fresnel's speculation is roughly equivalent to supposing that the molecules of transparent matter act like little condensers in increas- ing the permittivity, and that the matter, when in motion, only carries forward the increased permittivity. But however this matter may be finally interpreted, we must have a clear primary theory that can be trusted within its limits. Whether Maxwell's theory will last, as a sufficient and satisfactory primary theory upon which the numerous secondary developments required may be grafted, is a matter for the future to determine. Let it not be forgotten that Maxwell's theory is only the first step towards a full theory of the .ether ; and, moreover, that no theory of the ether can be complete that does not fully account for the omnipresent force of gravi- tation.

There is one other matter that demands notice in conclusion. It is not long since it was taken for granted that the common electrical units were correct. That curious and obtrusive constant 4?r was considered by some to be a sort of blessed dispensation, without which all electrical theory would fall to pieces. I believe that this view is now nearly extinct, and that it is well recognised that the 4?r was an unfortunate and mischievous mistake, the source of many evils. In plain English, the common system of electrical units involves an irrationality of the same kind as would be brought into the metric system of weights and measures, were we to define the unit area to be the area, not of a square with unit side, but of a circle of unit diameter. The constant TT would then obtrude itself into the area of a rectangle, and everywhere it should not be, and be a source of great confusion and inconvenience. So it is in the common electrical units, which are truly irrational. Now, to make a mistake is easy and natural to man. But that is not enough. The next thing is to correct it. When a mistake has once been started, it is not necessary to go on repeating it for ever and ever with cumulative inconvenience.

The B. A. Committee on Electrical Standards had to do two kinds of work. There was the practical work of making standards from the experimentally found properties of matter (and ether). This has been done at great length, and with much labour and success. But there was also the theoretical work of fixing the relations of the units in a convenient, rational, and harmonious manner. This work has not yet been done. To say that they ought to do it is almost a platitude. Who else should do it ? To say that there is not at present sufficient popular demand for the change does not seem very satisfactory. Is it not for leaders to lead ? And who should lead but the men of light and leading who have practical influence in the matter ?

Whilst, on the one hand, the immense benefit to be gained by rationalising the units requires some consideration to fully appreciate, it is, on the other hand, very easy to overestimate the difficulty of making the change. Some temporary inconvenience is necessary, of course. For a time there would be two sorts of ohms, &c., the old style and the new (or rational). But it is not a novelty to have two sorts of ohms. There have been several already. Eemember that the number of standards in present existence is as nothing to the number going to be made, and with ever increasing rapidity, by reason of the enormously rapid extension of electrical industries.

Old style instruments would very soon be in a minority, and then disappear, like the pins. I do not know that there is a more important practical question than this one of rationalising the units, on account of its far-reaching effect, and think that whilst the change could be made now with ease (with a will, of course), it will be far more troublesome if put off until the general British units are reformed; even though that period be not so distant as it is customary to believe. Electricians should set a good example.

The reform which I advocate is somewhat similar to the important improvement made by chemists in their units about a quarter of a century ago. One day our respected master informed us that it had been found out that water was not HO, as he had taught us before, but something else. It was henceforward to be H 2 0. This was strange at first, and inconvenient, for so many other formulae had to be altered, and new books written. But no one questions the wisdom of the change. Now observe, here, that the chemists, when they found that their atomic weights were wrong, and their formulae irrational, did not cry " Too late," ignore the matter, and ask Parliament to legalise the old erroneous weights ! They went and set the matter right. Verb. sap.

DECEMBER 16, 1893.




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