Derivatives of optical path length: from mathematical formulation to applications

Psang Dain Lin

doi:10.1364/JOSAA.32.000710

Journal of the Optical Society of America A
Vol. 32,
Issue 5,
pp. 710-717
(2015)
•https://doi.org/10.1364/JOSAA.32.000710

Derivatives of optical path length: from mathematical formulation to applications

Psang Dain Lin

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Psang Dain Lin, "Derivatives of optical path length: from mathematical formulation to applications," J. Opt. Soc. Am. A 32, 710-717 (2015)

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Abstract

The optical path length (OPL) of an optical system is a highly important parameter since it determines the phase of the light passing through the system and governs the interference and diffraction of the rays as they propagate. The Jacobian and Hessian matrices of the OPL are of fundamental importance in tuning the performance of a system. However, the OPL varies as a recursive function of the incoming ray and the boundary variable vector, and hence computing the Jacobian and Hessian matrices is extremely challenging. In an earlier study by the present group, this problem was addressed by deriving the Jacobian matrix of the OPL with respect to all of the independent system variables of a nonaxially symmetric system. In the present study, the proposed method is extended to the Hessian matrix of a nonaxially symmetric optical system. The proposed method facilitates the cross-sensitivity analysis of the OPL with respect to arbitrary system variables and provides an ideal basis for automatic optical system design applications in which the merit function is defined in terms of wavefront aberrations. An illustrative example is given. It is shown that the proposed method requires fewer iterations than that based on the Jacobian matrix and yields a more reliable and precise optimization performance.

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	$J$
	$V_{j}$	$ξ_{e j}$	$R_{2 j - 1}$	$R_{2 j}$	$q_{e j}$
1	0.0000	1.65000	38.2219	$- 56.0857$	15.8496
2	0.0000	1.71736	$- 56.0857$	$- 590.6820$	5.9690
3	3.0226	1.00000			0.0000
4	14.0208	1.52583	$- 41.7957$	29.3446	2.5146
5	7.9248	1.65000	63.5635	$- 56.8655$	6.0960
6	49.6316

	$Δ W$ from Ray Tracing	Eq. (26)		Eq. (27)
$Δ v_{4}$	$Δ W$ from Ray Tracing	$Δ W$	Error %	$Δ W$	Error %
0.1	0.00988	0.00974	$- 1.34$	0.00987	$- 0.03$
0.2	0.02003	0.01948	$- 2.72$	0.02000	$- 0.13$
0.4	0.04127	0.03897	$- 5.58$	0.04104	$- 0.56$
0.6	0.06394	0.05845	$- 8.57$	0.06312	$- 1.27$
0.8	0.07588	0.06820	$- 10.12$	0.07455	$- 1.74$
1.2	0.14313	0.11691	$- 18.32$	0.13558	$- 5.27$
1.6	0.20896	0.15587	$- 25.40$	0.18907	$- 9.52$

	Steepest Decent Method				Modified Newton Method
$k$	$v_{4}$	$v_{5}$	$v_{6}$	$\bar{Φ}$	$v_{4}$	$v_{5}$	$v_{6}$	$\bar{Φ}$
1	8.000	3.000	40.000	1.012646	8.000	3.000	40.000	1.012646
2	8.184	2.995	40.073	0.973706	15.544	7.338	54.082	0.113918
3	8.365	2.991	40.145	0.935976	14.629	8.191	49.618	0.002934
4	8.543	2.987	40.216	0.899436	14.542	8.331	48.870	0.000824
5	8.719	2.984	40.287	0.864063	14.527	8.343	48.803	0.000796
6	8.891	2.981	40.356	0.829837	14.520	8.343	48.805	0.000794
7	9.061	2.978	40.424	0.796733	14.514	8.341	48.818	0.000793
30	12.209	2.981	41.704	0.291153
70	15.044	3.008	42.885	0.041500
90	15.705	3.0106	43.164	0.015505
120	16.229	3.0113	43.389	0.004259
213	16.616	3.013	43.562	0.001439

	$J$
	$V_{j}$	$ξ_{e j}$	$R_{2 j - 1}$	$R_{2 j}$	$q_{e j}$
1	0.0000	1.65000	38.2219	$- 56.0857$	15.8496
2	0.0000	1.71736	$- 56.0857$	$- 590.6820$	5.9690
3	3.0226	1.00000			0.0000
4	14.0208	1.52583	$- 41.7957$	29.3446	2.5146
5	7.9248	1.65000	63.5635	$- 56.8655$	6.0960
6	49.6316

	$Δ W$ from Ray Tracing	Eq. (26)		Eq. (27)
$Δ v_{4}$	$Δ W$ from Ray Tracing	$Δ W$	Error %	$Δ W$	Error %
0.1	0.00988	0.00974	$- 1.34$	0.00987	$- 0.03$
0.2	0.02003	0.01948	$- 2.72$	0.02000	$- 0.13$
0.4	0.04127	0.03897	$- 5.58$	0.04104	$- 0.56$
0.6	0.06394	0.05845	$- 8.57$	0.06312	$- 1.27$
0.8	0.07588	0.06820	$- 10.12$	0.07455	$- 1.74$
1.2	0.14313	0.11691	$- 18.32$	0.13558	$- 5.27$
1.6	0.20896	0.15587	$- 25.40$	0.18907	$- 9.52$

Abstract

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Equations (35)

Journal of the Optical Society of America A