Ultra-compact dual band imaging spectrometer with freeform prisms

Yiqun Ji; Yiqun Ji; Yiqun Ji; Jizhou Han; Jizhou Han; Jizhou Han; Shijia Zhao; Shijia Zhao; Shijia Zhao; Chinhua Wang; Chinhua Wang; Chinhua Wang

doi:10.1364/AO.498327

Applied Optics
Vol. 62,
Issue 22,
pp. 5991-5998
(2023)
•https://doi.org/10.1364/AO.498327

Ultra-compact dual band imaging spectrometer with freeform prisms

Yiqun Ji, Jizhou Han, Shijia Zhao, and Chinhua Wang

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Yiqun Ji, Jizhou Han, Shijia Zhao, and Chinhua Wang, "Ultra-compact dual band imaging spectrometer with freeform prisms," Appl. Opt. 62, 5991-5998 (2023)

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Abstract

Wide spectrum and miniaturization are the main challenges in the imaging spectrometer design. In this paper, we propose an ultra-compact dual band imaging spectrometer (CDBIS) with cemented freeform prisms, which works at both the visible-near-infrared (VNIR) from 400 nm to 1000 nm and the shortwave-infrared (SWIR) from 1000 nm to 1700 nm. The imaging spectrometer is only composed of three cemented prisms, a primary prism and two triangular prisms. And a freeform surface characterized by the Zernike polynomial is introduced in each prism. The CDBIS is dispersed by a diffraction grating, which is designed on the second surface of the primary prism. Based on vector aberration theory (VAT), the relationship among the astigmatism generated by the introduced freeform surfaces, the wavelength, and the field of view is studied. Accordingly, a wideband is realized by introducing the freeform surfaces after the diffraction grating. Furthermore, through optimizing the coefficients of Zernike polynomial terms, residual astigmatism at different wavelengths is well balanced. An imaging spectrometer with a volume of only ${100}\;{{\rm cm}^3}$ is obtained, with a spectral resolution of 1.45 nm at VNIR and 2.40 nm at SWIR, respectively. It has a huge potential for broadband space exploration.

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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 (21)

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Term	Zernike Polynomial	Term	Zernike Polynomial	Term	Zernike Polynomial
Z1	1	Z7	$(3 ρ^{3} - 2 ρ) \cos ϕ$	Z13	$(4 ρ^{4} - 3 ρ^{2}) \sin (2 ϕ)$
Z2	$ρ \cos ϕ$	Z8	$(3 ρ^{3} - 2 ρ) \sin ϕ$	Z14	$(10 ρ^{5} - 12 ρ^{3} + 3 ρ) \cos (ϕ)$
Z3	$ρ \sin ϕ$	Z9	$6 ρ^{4} - 6 ρ^{2} + 1$	Z15	$(10 ρ^{5} - 12 ρ^{3} + 3 ρ) \sin (ϕ)$
Z4	$2 ρ^{2} - 1$	Z10	$ρ^{3} \cos (3 ϕ)$	Z16	$20 ρ^{6} - 30 ρ^{4} + 12 ρ^{2} - 1$
Z5	$ρ^{2} \cos (2 ϕ)$	Z11	$ρ^{3} \sin (3 ϕ)$	Z17	$ρ^{4} \cos (4 ϕ)$
Z6	$ρ^{2} \sin (2 ϕ)$	Z12	$(4 ρ^{4} - 3 ρ^{2}) \cos (2 ϕ)$	Z18	$ρ^{4} \sin (4 ϕ)$

Parameter	Value	Units
Wavelength for VNIR	400–1000	nm
Wavelength for SWIR	1000–1700	nm
Length of slits	4	mm
The distance between slits	4	mm
NA	0.143	—
Detector pixel size	7.5; 12.5	µm
Spectral resolution	1.45; 2.40	nm
Volume ( $X \times Y \times Z$ )	$23 \times 64 \times 68$	${m m}^{3}$
Magnification	− 1	—

Surface	Radius (mm)	Thickness (mm)	Tilt Angle (degree)
Slit	—	30.82	—
Incident surface	−31.41	29.07	0
Grating	−87.28	1.37	−17.58
Reflective Surface	349.30	41.79	−49.16
Dichroic filter	—	15.98; −11.89	45
Emitting surface in VNIR	31.47	9.29	3.84
Emitting surface in SWIR	−524.15	−11.51	−12.34

Term	Reflective Surface	Emitting Surface in VNIR	Emitting Surface in SWIR
$Z_{8}$	−0.328	0.420	0.395
$Z_{9}$	0.043	0.063	−0.079
$Z_{11}$	1.501	−1.651	−0.211
$Z_{12}$	−0.794	−0.336	0.707
$Z_{15}$	−0.085	$9.554 \times 10^{- 3}$	0.139
$Z_{16}$	−0.019	−0.016	0.023
$Z_{17}$	0.029	0.334	0.162
$Z_{20}$	0.211	−0.256	−0.083
$Z_{21}$	−0.069	−0.057	0.120
$Z_{27}$	0.078	−0.101	−0.038
$Z_{28}$	$- 9.189 \times 10^{- 3}$	0.052	0.079

Term	Zernike Polynomial	Term	Zernike Polynomial	Term	Zernike Polynomial
Z1	1	Z7	$(3 ρ^{3} - 2 ρ) \cos ϕ$	Z13	$(4 ρ^{4} - 3 ρ^{2}) \sin (2 ϕ)$
Z2	$ρ \cos ϕ$	Z8	$(3 ρ^{3} - 2 ρ) \sin ϕ$	Z14	$(10 ρ^{5} - 12 ρ^{3} + 3 ρ) \cos (ϕ)$
Z3	$ρ \sin ϕ$	Z9	$6 ρ^{4} - 6 ρ^{2} + 1$	Z15	$(10 ρ^{5} - 12 ρ^{3} + 3 ρ) \sin (ϕ)$
Z4	$2 ρ^{2} - 1$	Z10	$ρ^{3} \cos (3 ϕ)$	Z16	$20 ρ^{6} - 30 ρ^{4} + 12 ρ^{2} - 1$
Z5	$ρ^{2} \cos (2 ϕ)$	Z11	$ρ^{3} \sin (3 ϕ)$	Z17	$ρ^{4} \cos (4 ϕ)$
Z6	$ρ^{2} \sin (2 ϕ)$	Z12	$(4 ρ^{4} - 3 ρ^{2}) \cos (2 ϕ)$	Z18	$ρ^{4} \sin (4 ϕ)$

Abstract

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Equations (21)

Applied Optics