Polarization ray tracing in anisotropic optically active media. I. Algorithms

Stephen C. McClain; Lloyd W. Hillman; Russell A. Chipman

doi:10.1364/JOSAA.10.002371

Journal of the Optical Society of America A
Vol. 10,
Issue 11,
pp. 2371-2382
(1993)
•https://doi.org/10.1364/JOSAA.10.002371

Polarization ray tracing in anisotropic optically active media. I. Algorithms

Stephen C. McClain, Lloyd W. Hillman, and Russell A. Chipman

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Stephen C. McClain, Lloyd W. Hillman, and Russell A. Chipman, "Polarization ray tracing in anisotropic optically active media. I. Algorithms," J. Opt. Soc. Am. A 10, 2371-2382 (1993)

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Abstract

Procedures for performing polarization ray tracing through birefringent media are presented in a form compatible with the standard methods of geometrical ray tracing. The birefringent materials treated include the following: anisotropic optically active materials such as quartz, non-optically active uniaxial materials such as calcite, and isotropic optically active materials such as mercury sulfide and organic liquids. Refraction and reflection algorithms are presented that compute both ray directions and wave directions. Methods for computing polarization modes, refractive indices, optical path lengths, and Fresnel transmission and reflection coefficients are also specified. A numerical example of these algorithms is given for analyzing the field of view of a quartz rotator.

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λ (nm)	n_o	n_e	ρ (deg/mm)
303.4	1.57695	1.58720	95.02
340.4	1.56747	1.57738	72.45
404.7	1.55716	1.56671	48.95
486.1	1.54968	1.55898	32.76
546.1	1.54617	1.55535	25.53
589.3	1.54425	1.55336	21.72
656.3	1.54190	1.55093	17.32
794.8	1.53848	1.54739	11.59

Ordinary	Extraordinary
n_to = 1.5391511	n_te = 1.5392173
k_to_x = 0	k_tex = 0
k_to_y = 0.0566259	k_tex = 0.0566234
k_to_z = 0.998395	k_tez = 0.998396
Ê_to_x = 0.845486	Ê_tex = −0.534020i
Ê_to_y = −0.533160i	Ê_tey = 0.844146
Ê_to_z = 0.0298882i	Ê_tez = −0.0473256
Ĥ_to_x = 0.821927i	Ĥ_tex = −1.301348
Ĥ_to_y = 1.299259	Ĥ_tey = −0.820629i
Ĥ_to_z = −0.0736873	Ĥ_tez = 0.0465457
${\hat{ρ}}_{to x}$ = 0	${\hat{ρ}}_{t e x}$ = 0
${\hat{ρ}}_{to y}$ = 0.0564376	${\hat{ρ}}_{t e y}$ = 0.0561616
${\hat{ρ}}_{to z}$ = 0.998406	${\hat{ρ}}_{t e z}$ = 0.998422
l_o (mm) = 6.360137	l_e (mm) = 6.360038
y_o (mm) = 0.358957	y_e (mm) = 0.357190
OPL_o (mm) = 9.789212	OPL_e (mm) = 9.789479
a_1to_s = 0.665053	a₁_tes = 0.420045i
a_2ts_o = 1.02591	a₂_tse = −0.647977i
a_2tp_o = −0.648272i	a₂_tpe = 1.02640

λ (nm)	n_o	n_e	ρ (deg/mm)
303.4	1.57695	1.58720	95.02
340.4	1.56747	1.57738	72.45
404.7	1.55716	1.56671	48.95
486.1	1.54968	1.55898	32.76
546.1	1.54617	1.55535	25.53
589.3	1.54425	1.55336	21.72
656.3	1.54190	1.55093	17.32
794.8	1.53848	1.54739	11.59

Ordinary	Extraordinary
n_to = 1.5391511	n_te = 1.5392173
k_to_x = 0	k_tex = 0
k_to_y = 0.0566259	k_tex = 0.0566234
k_to_z = 0.998395	k_tez = 0.998396
Ê_to_x = 0.845486	Ê_tex = −0.534020i
Ê_to_y = −0.533160i	Ê_tey = 0.844146
Ê_to_z = 0.0298882i	Ê_tez = −0.0473256
Ĥ_to_x = 0.821927i	Ĥ_tex = −1.301348
Ĥ_to_y = 1.299259	Ĥ_tey = −0.820629i
Ĥ_to_z = −0.0736873	Ĥ_tez = 0.0465457
${\hat{ρ}}_{to x}$ = 0	${\hat{ρ}}_{t e x}$ = 0
${\hat{ρ}}_{to y}$ = 0.0564376	${\hat{ρ}}_{t e y}$ = 0.0561616
${\hat{ρ}}_{to z}$ = 0.998406	${\hat{ρ}}_{t e z}$ = 0.998422
l_o (mm) = 6.360137	l_e (mm) = 6.360038
y_o (mm) = 0.358957	y_e (mm) = 0.357190
OPL_o (mm) = 9.789212	OPL_e (mm) = 9.789479
a_1to_s = 0.665053	a₁_tes = 0.420045i
a_2ts_o = 1.02591	a₂_tse = −0.647977i
a_2tp_o = −0.648272i	a₂_tpe = 1.02640

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