Alignment with a combination of deflectometry and the sine condition test

Hyemin Yoo; Matthew Dubin

doi:10.1364/AO.475915

Applied Optics
Vol. 62,
Issue 7,
pp. 1677-1688
(2023)
•https://doi.org/10.1364/AO.475915

Alignment with a combination of deflectometry and the sine condition test

Hyemin Yoo and Matthew Dubin

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Hyemin Yoo and Matthew Dubin, "Alignment with a combination of deflectometry and the sine condition test," Appl. Opt. 62, 1677-1688 (2023)

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Abstract

We propose a new alignment method that is based on relative measurements with an on-axis test setup composed of a pixelated camera and a monitor. By combining deflectometry and the sine condition test, the new method eliminates the necessity of moving a test instrument to multiple field points but still estimates the state of alignment by measuring both the off-axis and on-axis performances of the system. Additionally, it can be a very cost-effective option for certain projects as a monitor, and a camera may be substituted for the return optic and the interferometer required in a conventional interferometric method. We explain the concept of the new alignment method using a meter-class Ritchey–Chrétien telescope. Additionally, we present a new metric, the Metric for Misalignment Indicators (MMI), which represents the transmitted wavefront error caused by misalignment in the system. Then we demonstrate the validity of the concept using simulations where a poorly aligned telescope is the starting point to show that this method has a larger dynamic range compared to the interferometric method. Even considering realistic levels of noise, the new alignment method works successfully, as there is an improvement of two orders of magnitude in the final MMI after three iterations of alignment. The MMI of perturbed telescope models is about 10 µm but, after alignment, the MMI converges to one-tenth of a micrometer.

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Corrections

Hyemin Yoo and Matthew Dubin, "Alignment with a combination of deflectometry and the sine condition test: publisher’s note," Appl. Opt. 62, 6365-6365 (2023)
https://opg.optica.org/ao/abstract.cfm?uri=ao-62-24-6365

21 July 2023: A correction was made to Eq. (1).

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Equations (14)

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Error Type	Aberration	Related Terms & Ratios	Features
Pupil mapping error(Sine condition test)	Linear focus (vertical)	$S 3 : S 7 : T 8 = \sqrt 6 : 1 : - 1$	Fig. 3(c)
	Linear focus (horizontal)	$S 2 : S 8 : T 7 = \sqrt 6 : 1 : 1$	Fig. 3(c) rotated 90° clockwise
	Linear astigmatism (vertical)	$S 7 : T 8 = 1 : 1$	Fig. 3(d)
	Linear astigmatism (horizontal)	$S 8 : T 7 = 1 : - 1$	Fig. 3(d) rotated 90° clockwise
Slope mapping error(Deflectometry)	Power	$Δ S 4$	Fig. 3(a)
	Constant coma (vertical)	$Δ S 3 : Δ S 7 = \sqrt 3 : \sqrt 2$	Fig. 3(e)
	Constant coma (horizontal)	$Δ S 2 : Δ S 8 = \sqrt 3 : \sqrt 2$	Fig. 3(e) rotated 90° clockwise
	Spherical	$Δ S 4 : Δ S 11 = 2 \sqrt 2 : 1$	Fig. 3(b)

DOF Number	DOF Descriptions	Tolerance Range	Units
1	Pupil to secondary distance	$\pm 0.5$	mm
2	Pupil decenter in x	$\pm 0.5$	mm
3	Pupil decenter in y	$\pm 0.5$	mm
4	Secondary to primary distance	$\pm 0.5$	mm
5	Secondary decenter in x	$\pm 0.5$	mm
6	Secondary decenter in y	$\pm 0.5$	mm
7	Pupil tilt about x	$\pm 5.0$	mrad
8	Pupil tilt about y	$\pm 5.0$	mrad
9	Secondary tilt about x	$\pm 5.0$	mrad
10	Secondary tilt about y	$\pm 5.0$	mrad

Type	Descriptions	Tolerance Range
Pixel noise	1/10 of a monitor pixel size	0.00–0.05 mm (magnitude), $\pm π$ (direction)
Distortion error	Maximum distortion	$\pm 0.1 %$
Fabrication error	RMS Zernike surface sag (the Noll indices)	$\pm 50 n m$ (Z4-Z11), $\pm 5 n m$ (Z12-Z37)
LCD sag error	FEA modeling of LCD monitor sag
LCD positioning	Decenters, spacing, and tilts of the monitor planes	$\pm 0.5 m m$ or $\pm 5.0 m r a d$

	MMI (µm)
Iteration Number	Average	Standard Deviation
0	11.08	5.49
1	0.18	0.08
2	0.12	0.04
3	0.11	0.04

Surface Number	Comment	Radius (mm)	Thickness (mm)	Glass	Conic
0	Detector plane	Infinity	21.1039
1	Cooke triplet lens1	9.1977	1.4760	SK16
2		−39.8418	2.3752
3	Cooke triplet lens2	−0.1460	0.5000	F2
4		11.1066	3.0038
5	Cooke triplet lens3	217.8802	1.6295	SK16
6		−11.0068	0.5000
7	Stop (pupil)	Infinity	1412.5146
8	Secondary mirror	301.0000	−763.9914	MIRROR	−1.5012
9	Primary mirror	1800.000	47448.3240	MIRROR	−1.0033
10	Monitor 1 (Rear principal plane)	Infinity	5000.0000
11	Monitor 2 (Rear principal plane $+$ 5 m)	Infinity	-

Specifications	Value
Focal length (mm)	9346.93
F/#	9.346
Full field of view (deg)	0.98
Test wavelength (µm)	0.656

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Applied Optics