Methodology for the analysis of a thermo-mechanically deformed optical system

Nordera, Simone; Chioetto, Paolo; Zuppella, Paola; Pace, E.; Morgante, G.; Tozzi, A.; Vecchio, Ciro Del; Scippa, Antonio; Micela, G.; Deppo, V. Da

doi:10.1117/12.2599824

Cited by 1 publication

(1 citation statement)

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“…For example, thermal phenomena and thermally-induced aberrations can limit the achievable resolution and performance of optical lithography systems, [1][2][3][4][5][6][7][8][9][10] space and ground telescopes, [11][12][13][14][15][16][17][18][19][20][21][22][23] gravitational wave detectors, [24][25][26] high power lasers, [27][28][29] and other optical systems. [30][31][32][33] In the case of refractive optical systems consisting of lenses, absorbed thermal energy and non-uniform temperature distributions across optical elements, induce mechanical deformations and variations of refractive indices. These effects can in turn induce large focal shifts and wavefront aberrations.…”

Section: Introductionmentioning

confidence: 99%

Subspace identification of low-dimensional Structural-Thermal-Optical-Performance (STOP) models of reflective optics

Haber¹,

Draganov²,

Krainak³

2022

Preprint

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In this paper, we investigate the feasibility of using subspace system identification techniques for estimating transient Structural-Thermal-Optical Performance (STOP) models of reflective optics. As a test case, we use a Newtonian telescope structure. This work is motivated by the need for the development of model-based datadriven techniques for prediction, estimation, and control of thermal effects and thermally-induced wavefront aberrations in optical systems, such as ground and space telescopes, optical instruments operating in harsh environments, optical lithography machines, and optical components of high-power laser systems. We estimate and validate a state-space model of a transient STOP dynamics. First, we model the system in COMSOL Multiphysics. Then, we use LiveLink for MATLAB software module to export the wavefront aberrations data from COMSOL to MATLAB. This data is used to test the subspace identification method that is implemented in Python. One of the main challenges in modeling and estimation of STOP models is that they are inherently large-dimensional. The large-scale nature of STOP models originates from the coupling of optical, thermal, and structural phenomena and physical processes. Our results show that large-dimensional STOP dynamics of the considered optical system can be accurately estimated by low-dimensional state-space models. Due to their lowdimensional nature and state-space forms, these models can effectively be used for the prediction, estimation, and control of thermally-induced wavefront aberrations. The developed MATLAB, COMSOL, and Python codes are available online.

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