the limiting phases being those which belong to the same systems at the times and respectively. But we have identically
|
|
for such limits. The principle of conservation of extension-in-phase may therefore be expressed in the form
|
(33)
|
This equation is easily proved directly. For we have identically
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where the double accents distinguish the values of the momenta and coördinates for a time
. If we vary
, while
and
remain constant, we have
|
(34)
|
Now since the time
is entirely arbitrary, nothing prevents us from making if
identical with
at the moment considered. Then the determinant
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|
will have unity for each of the elements on the principal diagonal, and zero for all the other elements. Since every term of the determinant except the product of the elements on the principal diagonal will have two zero factors, the differential of the determinant will reduce to that of the product of these elements,
i. e., to the sum of the differentials of these elements. This gives the equation
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|
Now since
, the double accents in the second member of this equation may evidently be neglected. This will give, in virtue of such relations as (16),