Method of combining thermal homology theory with a genetic algorithm for the design and optimization of precise submillimeter-wave antennas

Mingzhu Zhang; Mingzhu Zhang; Hairen Wang; Hairen Wang; Yingxi Zuo; Yingxi Zuo

doi:10.1364/AO.416316

Applied Optics
Vol. 60,
Issue 6,
pp. 1629-1636
(2021)
•https://doi.org/10.1364/AO.416316

Method of combining thermal homology theory with a genetic algorithm for the design and optimization of precise submillimeter-wave antennas

Mingzhu Zhang, Hairen Wang, and Yingxi Zuo

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Mingzhu Zhang, Hairen Wang, and Yingxi Zuo, "Method of combining thermal homology theory with a genetic algorithm for the design and optimization of precise submillimeter-wave antennas," Appl. Opt. 60, 1629-1636 (2021)

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Abstract

It is a common problem in precise submillimeter-wave telescopes that thermal deformation coupling between major subsystems results from materials with different coefficients of thermal expansion or at different temperatures. Here, the method of combining thermal homology theory with a genetic algorithm (CTHTGA) is proposed for the design and optimization of large precise submillimeter-wave antennas. The CTHTGA method has two key steps: (1) design of the structure of the antenna according to thermal homology theory; and (2) structural optimization based on the genetic algorithm. It has the ability to solve the problem of thermal deformation coupling well and to ensure sufficient rigidity. As an application, CTHTGA was used in the design and optimization of a 1.2 m submillimeter-wave telescope. The results showed that the CTHTGA method, compared to the previous design of a 1.2 m antenna, not only dramatically decreases the impact of thermal deformation coupling but gives the designed antenna sufficient stiffness and smaller gravity deformation. Moreover, other things being equal, a method of combining thermal homology theory with zero-order and a first-order compound optimization algorithm is used to quantitatively validate the CTHTGA method. As the results suggest, the overall performance of the CTHTGA is, to the best of our knowledge, better than that of the latter method.

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Type	Variable Name and Explanation
DV	${i n r}_{i}$ : inside radius of $P i$ , $i = 1, 2, 3, 4, 5$
DV	${t h i c k}_{i}$ : thickness of $P i$ , $i = 1, 2, 3, 4, 5$
DV	$m h$ : determines the position of point M
DV	$d r$ : outer radius of P3-radius of P1
SV	rmse: effective RMS of MS under thermal load
SV	firstfq: first-order mode frequency
OB	rmst: geometrical RMS of MS under thermal load

Variable Type	Variable Name	Optimal Result	Variable Name	Optimal Result
DV	${i n r}_{1}$	13.613 mm	${i n r}_{2}$	6.093 mm
DV	${t h i c k}_{1}$	4.613 mm	${t h i c k}_{2}$	3.702 mm
DV	${i n r}_{3}$	13.705 mm	${i n r}_{4}$	14.036 mm
DV	${t h i c k}_{3}$	4.261 mm	${t h i c k}_{4}$	4.326 mm
DV	${i n r}_{5}$	8.565 mm	$m h$	47.776 mm
DV	${t h i c k}_{5}$	4.769 mm	$d r$	131.883 mm
SV	rmse	0.810 µm	firstfq	14.507 Hz
OB	rmst	0.865 µm

Variable Type	Variable Name	Initial Value	Optimal Result
DV	${i n r}_{1}$	10 mm	14.882 mm
DV	${t h i c k}_{1}$	2 mm	1.933 mm
DV	${i n r}_{2}$	10 mm	3.482 mm
DV	${t h i c k}_{2}$	2 mm	4.832 mm
DV	${i n r}_{3}$	10 mm	12.126 mm
DV	${t h i c k}_{3}$	2 mm	4.181 mm
DV	${i n r}_{4}$	10 mm	8.754 mm
DV	${t h i c k}_{4}$	2 mm	4.855 mm
DV	${i n r}_{5}$	10 mm	12.979 mm
DV	${t h i c k}_{5}$	2 mm	1.833 mm
DV	$m h$	55 mm	60.870 mm
DV	$d r$	90 mm	63.854 mm
SV	rmse	1.331 µm	1.076 µm
SV	firstfq	14.935 Hz	14.754 Hz
OB	rmst	1.426 µm	1.148 µm

Previous	GA Optimum	HOM Optimum
1.775 µm	0.865 µm	1.148 µm
–	51.3%	35.3%

Previous	GA Optimum	HOM Optimum
15.252 Hz	14.507 Hz	14.760
–	4.9%	3.2%

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Applied Optics