Computational method for deriving the geometric point spread function of an optical system

Chien-Sheng Liu; Psang Dain Lin

doi:10.1364/AO.49.000126

Applied Optics
Vol. 49,
Issue 1,
pp. 126-136
(2010)
•https://doi.org/10.1364/AO.49.000126

Computational method for deriving the geometric point spread function of an optical system

Chien-Sheng Liu and Psang Dain Lin

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Chien-Sheng Liu and Psang Dain Lin, "Computational method for deriving the geometric point spread function of an optical system," Appl. Opt. 49, 126-136 (2010)

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Abstract

The distribution of the ray density of the spot diagram formed in the image plane is called the geometric point spread function (PSF). It plays an important role in the image formation theory, since it describes the impulse response of an optical system to a source point. However, the literature contains very few techniques for deriving the PSF of optical systems. Accordingly, this study presents a method based on an irradiance model for computing the geometric PSF of an optical system by considering the energy conservation along a single light ray. It is shown that the proposed method obtains a reliable and accurate estimate of the PSF and enables the computation of the centroid and root-mean-square radius of the focus spot on the image plane. In addition, compared to existing ray-counting methods presented in the literature, in which the quality of the PSF solution depends on the number of rays traced and the grid size used to mesh the image plane, the proposed irradiance-based method requires just one tracing operation. Overall, the results presented in this study confirm that the proposed method provides an ideal solution for calculating the merit function and modulation transfer function of an optical system.

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j	$t_{e j y}$	$ξ_{air}$	$ξ_{e j}$	$R_{2 j - 1}$	$R_{2 j}$	$q_{j}$
1	38.222	1	1.6500	38.222	56.086	15.850
2	$- 40.191$	1	1.7174	56.086	590.682	5.969
3	24.886	1	1.0000	—	—	7.620
4	$- 2.889$	1	1.5258	41.796	29.345	2.515
5	106.896	1	1.6500	63.564	56.866	6.096
6	105.074	1	—	—	—	—

PSF Values of Points in Region 0
$α_{0}$	$90^{\circ} \pm 1.96762408781$	$90^{\circ} \pm 1.9677240878$	$90^{\circ} \pm 1.96792408780$
$β_{0}$	0.	0.	0.
$x_{11}$	$- 3.9343624 \times 10^{- 5}$	$- 7.40454 \times 10^{- 7}$	$7.6483162 \times 10^{- 5}$
Jacobian	0.025342698582	0.000477001107	0.049280204562
PSF	6738.01	357985.04	3465.07
PSF Values of Points in Region 1
$α_{0}$	$90^{\circ} \pm 1.13897583371$	$90^{\circ} \pm 1.113847583372$	$90^{\circ} \pm 1.13857583372$
$β_{0}$	0.	0.	0.
$x_{11}$	0.146358838756	0.146358863068	0.146358865039
Jacobian	0.056549447153	0.015524786362	0.001107490161
PSF	3019.64	10999.15	154185.99

j	$t_{e j y}$	$ξ_{air}$	$ξ_{e j}$	$R_{2 j - 1}$	$R_{2 j}$	$q_{j}$
1	38.222	1	1.6500	38.222	56.086	15.850
2	$- 40.191$	1	1.7174	56.086	590.682	5.969
3	24.886	1	1.0000	—	—	7.620
4	$- 2.889$	1	1.5258	41.796	29.345	2.515
5	106.896	1	1.6500	63.564	56.866	6.096
6	105.074	1	—	—	—	—

PSF Values of Points in Region 0
$α_{0}$	$90^{\circ} \pm 1.96762408781$	$90^{\circ} \pm 1.9677240878$	$90^{\circ} \pm 1.96792408780$
$β_{0}$	0.	0.	0.
$x_{11}$	$- 3.9343624 \times 10^{- 5}$	$- 7.40454 \times 10^{- 7}$	$7.6483162 \times 10^{- 5}$
Jacobian	0.025342698582	0.000477001107	0.049280204562
PSF	6738.01	357985.04	3465.07
PSF Values of Points in Region 1
$α_{0}$	$90^{\circ} \pm 1.13897583371$	$90^{\circ} \pm 1.113847583372$	$90^{\circ} \pm 1.13857583372$
$β_{0}$	0.	0.	0.
$x_{11}$	0.146358838756	0.146358863068	0.146358865039
Jacobian	0.056549447153	0.015524786362	0.001107490161
PSF	3019.64	10999.15	154185.99

Abstract

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Applied Optics