sin θ 0 ~ = B A ′ C ′ B = B A ′ C P = B A ′ 2 d tan θ {\displaystyle \sin {\widetilde {\theta _{0}}}={\frac {BA'}{C'B}}={\frac {BA'}{CP}}={\frac {BA'}{2d\tan \theta }}}
B A ′ = 2 d tan θ sin θ 0 ~ {\displaystyle BA'=2d\tan \theta \sin {\widetilde {\theta _{0}}}}
Δ Λ = 2 d cos θ n t − 2 d tan θ sin θ 0 n i {\displaystyle \Delta \Lambda ={\frac {2d}{\cos \theta }}nt-2d\tan \theta \sin \theta _{0}ni}
= 2 d cos θ n t [ 1 − sin θ sin θ 0 n i n t ] {\displaystyle ={\frac {2d}{\cos \theta }}nt\left[1-\sin \theta \sin \theta _{0}{\frac {ni}{nt}}\right]}
= 2 d cos θ n t [ 1 − sin 2 θ ] {\displaystyle ={\frac {2d}{\cos \theta }}nt\left[1-\sin ^{2}\theta \right]}
Δ Λ = 2 d n t cos θ {\displaystyle \Delta \Lambda =2dnt\cos \theta }
δ = 2 π λ 0 Δ Λ = 4 π λ 0 n t d cos θ {\displaystyle \delta ={\frac {2\pi }{\lambda _{0}}}\Delta \Lambda ={\frac {4\pi }{\lambda _{0}}}ntd\cos \theta }
E 1 r = E 0 r e i ω t {\displaystyle E_{1r}=E_{0}re^{i\omega t}}
E 2 r = E 0 t t ′ r ′ e i ( ω t − δ ) {\displaystyle E_{2r}=E_{0}tt'r'e^{i\left(\omega t-\delta \right)}}
E 3 r = E 0 t t ′ r ′ 3 e i ( ω t − 2 δ ) {\displaystyle E_{3r}=E_{0}tt'r'^{3}e^{i\left(\omega t-2\delta \right)}}
E N r = E 0 t t ′ r ′ ( 2 N − 3 ) e i ( ω t − ( N − 1 ) δ ) {\displaystyle E_{Nr}=E_{0}tt'r'^{(2N-3)}e^{i\left(\omega t-\left(N-1\right)\delta \right)}}
E r T = ∑ E i r = E 0 r e i ω t + ∑ j = 2 N E 0 t r ′ ( 2 j − 3 ) t ′ e i ( ω t − ( j − 1 ) δ ) {\displaystyle E_{rT}=\sum E_{ir}=E_{0}re^{i\omega t}+\sum _{j=2}^{N}E_{0}tr'^{(2j-3)}t'e^{i\left(\omega t-\left(j-1\right)\delta \right)}}
= E 0 e i ω t [ r + { ∑ j = 2 N ( r ′ 2 e i δ ) j − 2 } r ′ t t ′ e − i δ ] {\displaystyle =E_{0}e^{i\omega t}\left[r+\left\{\sum _{j=2}^{N}\left(r'^{2}e^{i\delta }\right)^{j-2}\right\}r'tt'e^{-i\delta }\right]}
E r = E 0 e i ω t [ r + r ′ t t ′ e − i δ 1 − r ′ 2 e − i δ ] {\displaystyle E_{r}=E_{0}e^{i\omega t}\left[r+{\frac {r'tt'e^{-i\delta }}{1-r'^{2}e^{-i\delta }}}\right]}
E r = E 0 e i ω t [ r ( 1 − e − i δ ) 1 − r 2 e − i δ ] {\displaystyle E_{r}=E_{0}e^{i\omega t}\left[{\frac {r\left(1-e^{-i\delta }\right)}{1-r^{2}e^{-i\delta }}}\right]}
t t ′ + r 2 = 1 {\displaystyle tt'+r^{2}=1}
I R = E r E r ∗ = E 0 2 [ r ( 1 − e i δ ) 1 − r 2 e i δ ] [ r ( 1 − e i δ ) 1 − r 2 e i δ ] {\displaystyle I_{R}=E_{r}E_{r}^{*}=E_{0}^{2}\left[{\frac {r\left(1-e^{i\delta }\right)}{1-r^{2}e^{i\delta }}}\right]\left[{\frac {r\left(1-e^{i\delta }\right)}{1-r^{2}e^{i\delta }}}\right]}
I r = E 0 2 2 r 2 ( 1 − cos θ ) ( 1 + r 4 ) − 2 r 2 cos δ {\displaystyle I_{r}=E_{0}^{2}{\frac {2r^{2}\left(1-\cos \theta \right)}{\left(1+r^{4}\right)-2r^{2}\cos \delta }}}
E t = E 0 e i ω t t t ′ 1 − r 2 e − i δ {\displaystyle E_{t}=E_{0}e^{i\omega t}{\frac {tt'}{1-r^{2}e^{-i\delta }}}}
I t = I i ( t t ′ ) 2 1 1 − r 2 e − i δ 1 1 − r 2 e i δ {\displaystyle I_{t}=I_{i}\left(tt'\right)^{2}{\frac {1}{1-r^{2}e^{-i\delta }}}{\frac {1}{1-r^{2}e^{i\delta }}}}
I t = I i ( t t ′ ) 2 1 ( 1 + r 4 ) − 2 r 2 cos δ {\displaystyle I_{t}=I_{i}\left(tt'\right)^{2}{\frac {1}{\left(1+r^{4}\right)-2r^{2}\cos \delta }}}
I t = I i ( 1 − r 2 ) 2 ( 1 + r 4 ) − 2 r 2 cos δ {\displaystyle I_{t}=I_{i}{\frac {\left(1-r^{2}\right)^{2}}{\left(1+r^{4}\right)-2r^{2}\cos \delta }}}
I r + I t = ( 1 − r 2 ) 2 + 2 r 2 ( 1 − cos δ ) ( 1 + r 4 ) − 2 r 2 cos δ I i {\displaystyle I_{r}+I_{t}={\frac {\left(1-r^{2}\right)^{2}+2r^{2}\left(1-\cos \delta \right)}{\left(1+r^{4}\right)-2r^{2}\cos \delta }}I_{i}}
= 1 + r 4 − 2 r 2 − 2 r 2 cos δ + 2 r 2 ( 1 + r 4 ) − 2 r 2 cos δ I i = I i {\displaystyle ={\frac {1+r^{4}-2r^{2}-2r^{2}\cos \delta +2r^{2}}{\left(1+r^{4}\right)-2r^{2}\cos \delta }}I_{i}=I_{i}}
I i = I i = I r + I t {\displaystyle I_{i}=I_{i}=I_{r}+I_{t}}
δ = 2 π m {\displaystyle \delta =2\pi m}