Page:MichelsonRefractometer1882.djvu/3

${\displaystyle \vartheta }$. Draw ${\displaystyle P'D}$ parallel to ${\displaystyle cf}$, and ${\displaystyle P'C}$, at right angles, and complete the rectangle ${\displaystyle BDP'C}$. Let ${\displaystyle P'PC=i}$ and ${\displaystyle DPP'=\theta }$. Let ${\displaystyle PP'=P}$, and the distance between the surfaces at ${\displaystyle P'=2t_{0}}$. We have then

${\displaystyle {\begin{aligned}t=t_{0}+CP'\cdot \tan \varphi =&t_{0}+P\tan \varphi \cdot \tan i,\ {\text{and}}\\\Delta =&2\left(t_{0}+P\tan \varphi \tan i\right)\cos \vartheta ,\ {\text{or}}\\\Delta =&{\frac {2\left(t_{0}+P\tan \varphi \tan i\right)}{\sqrt {1+\tan ^{2}i+\tan ^{2}\theta }}}\end{aligned}}}$

(1)

We see that in general ${\displaystyle \Delta }$ has all possible values, and therefore all phenomena of interference would be obliterated. If, however, we observe the point ${\displaystyle P}$ through a small aperture, ${\displaystyle ab}$, the pupil of the eye, for instance, the light which enters the eye from the surfaces will be limited to the small cone whose angle is ${\displaystyle bPa}$, and if the aperture be sufficiently small the differences in ${\displaystyle \Delta }$ may be reduced to any required degree.

It is proposed to find such a distance ${\displaystyle P}$, that with a given aperture these differences shall be as small as possible, which is equivalent to finding the distance from the mirrors at which the phenomena of interference are most distinct. The change of ${\displaystyle \Delta }$ for a change in ${\displaystyle \theta }$, is

${\displaystyle {\frac {\delta \Delta }{\delta \theta }}=-{\frac {2\left(t_{0}+P\tan \varphi \tan i\right){\frac {\tan \theta }{\cos ^{2}\theta }}}{\left(1+\tan ^{2}i+\tan ^{2}\theta \right)^{\frac {3}{2}}}}}$

(2)

The change of ${\displaystyle \Delta }$ for a change in ${\displaystyle i}$, is

${\displaystyle {\frac {\delta \Delta }{\delta i}}=2{\frac {\left(1+\tan ^{2}i+\tan ^{2}\theta \right){\frac {P\tan \varphi }{\cos ^{2}i}}-\left(t_{0}+P\tan \varphi \tan i\right){\frac {\tan i}{\cos ^{2}i}}}{\left(1+\tan ^{2}i+\tan ^{2}\theta \right)^{\frac {3}{2}}}}}$

(3)

For ${\displaystyle {\tfrac {\delta \Delta }{\delta \theta }}=0}$ we have ${\displaystyle \theta =0}$ (or ${\displaystyle \Delta =0}$).

For ${\displaystyle {\frac {\delta \Delta }{\delta i}}=0}$ we have ${\displaystyle \left(1+\tan ^{2}i+\tan ^{2}\theta \right)P\tan \varphi =\left(t_{0}+P\tan \varphi \tan i\right)\tan i}$, or

${\displaystyle \left(1+\tan ^{2}\theta \right)P\tan \varphi =t_{0}\tan i}$, whence ${\displaystyle P={\frac {t_{0}}{\tan \varphi }}\tan i\cos ^{2}\theta }$

Hence the fringes will be most distinct when ${\displaystyle \theta =0}$ and when

${\displaystyle P={\frac {t_{0}}{\tan \varphi }}\tan i}$

(4)

This condition coincides nearly with that found by Feussner.

If the thickness of the film is zero, or if the angle of incidence is zero, the fringes are formed at the surface of the mirrors. If the film is of uniform thickness, the fringes appear at infinity. If at the same time ${\displaystyle \varphi =0}$, and ${\displaystyle t_{0}=0}$, or ${\displaystyle i=0}$ and ${\displaystyle \varphi =0}$, the position of the fringes is indeterminate. If ${\displaystyle i}$ has the