Transmission and Reflection Coefficients of Light

This Calculator Will Help You To calculate The Transmission and Reflection of Coefficient of Light At Non-normal Incidence of Uniaxial Crystal (Single Surface)

$n_1 \sin heta_1 = n_0 \sin heta_0$

$T_s = rac{ \sin 2 heta_0 \sin 2 heta_1 }{ \sin^2( heta_0 + heta_1) }$

$T_p = rac{ \sin 2 heta_0 \sin 2 heta_1 }{ \sin^2( heta_0 + heta_1) \cos^2( heta_0 - heta_1) }$

$R_p = rac{ an^2( heta_0 - heta_1) }{ an^2( heta_0 + heta_1) }$

$R_s = rac{ \sin^2( heta_0 - heta_1) }{ \sin^2( heta_0 + heta_1) }$

Incident angle of the light $ heta_0$; Refraction angle of the light $ heta_1$;
Transmission Coefficient with polarization is out of the plane $T_s$;
Transmission Coefficient with polarization is in the plane $T_p$;
Reflection Coefficient with polarization is out of the plane $R_s$;
Reflection Coefficient with polarization is in the plane $R_p$.

Transmission and Reflection Coefficients of Light

$n_1 \sin heta_1 = n_0 \sin heta_0$

$T_s = rac{ \sin 2 heta_0 \sin 2 heta_1 }{ \sin^2( heta_0 + heta_1) }$

$T_p = rac{ \sin 2 heta_0 \sin 2 heta_1 }{ \sin^2( heta_0 + heta_1) \cos^2( heta_0 - heta_1) }$

$R_p = rac{ an^2( heta_0 - heta_1) }{ an^2( heta_0 + heta_1) }$

$R_s = rac{ \sin^2( heta_0 - heta_1) }{ \sin^2( heta_0 + heta_1) }$

Incident Angle, $ heta_0$:

$n_0$:

$n_1$:

$T_s$:

$T_p$:

$R_s$:

$R_p$: