Piston Error Measurement for Segmented Telescopes with an Artificial Neural Network

Yue, Dan; He, Yansong; Li, Yushuang

doi:10.3390/s21103364

Cited by 4 publications

(4 citation statements)

References 30 publications

(47 reference statements)

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“…e level of personal and social returns brought by education has become a realistic measure for the cost sharing of national and social investment in education [8]. Beyond a certain scale, private higher education will show limited competitiveness and limited exclusivity in consumption, but private higher education can bring huge positive external effects.…”

Section: Literature Reviewmentioning

confidence: 99%

Prediction of Higher Education Cost and Analysis of Sharing Ability Based on Artificial Neural Network

Xia

Yue

Niu

et al. 2022

Security and Communication Networks

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In order to explore how to realize the cost prediction and sharing ability of higher education, this paper proposes an analysis of the cost prediction and sharing ability of higher education based on artificial neural network. This method explores how to realize the cost prediction of higher education through the key technical problems and solutions of information recommendation based on artificial neural network. The research shows that the ability of college education cost prediction and sharing based on artificial neural network is 61% higher than that of traditional cost prediction and sharing. With the help of BP neural network algorithm, the accuracy of cost prediction can be maintained above 90%. It is proved that the artificial neural network algorithm can effectively improve the cost forecasting, financial system, and cost management system of colleges and universities.

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Section: Literature Reviewmentioning

confidence: 99%

Prediction of Higher Education Cost and Analysis of Sharing Ability Based on Artificial Neural Network

Xia

Yue

Niu

et al. 2022

Security and Communication Networks

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“…Segmented mirror telescope surface calibration mainly comprises piston error and tip/tilt error; among these, tip/tilt error detection methods are relatively mature, while piston error detection is still challenging and 2π errors are prone to occurring. An ANN can be used to build the relationship between piston error and the amplitude of a modulation transfer function's sidelobes to detect piston error [66]. A CNN can be used to distinguish the range of the piston error and improve the sensitivity of the Shack-Hartmann wavefront sensor to the 2π error [67].…”

Section: Mirror Surface Calibrationmentioning

confidence: 99%

Artificial Intelligence in Astronomical Optical Telescopes: Present Status and Future Perspectives

Huang,

Hu,

Cai

et al. 2024

Universe

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With new artificial intelligence (AI) technologies and application scenarios constantly emerging, AI technology has become widely used in astronomy and has promoted notable progress in related fields. A large number of papers have reviewed the application of AI technology in astronomy. However, relevant articles seldom mention telescope intelligence separately, and it is difficult to understand the current development status of and research hotspots in telescope intelligence from these papers. This paper combines the development history of AI technology and difficulties with critical telescope technologies, comprehensively introduces the development of and research hotspots in telescope intelligence, conducts a statistical analysis of various research directions in telescope intelligence, and defines the merits of these research directions. A variety of research directions are evaluated, and research trends in each type of telescope intelligence are indicated. Finally, according to the advantages of AI technology and trends in telescope development, potential future research hotspots in the field of telescope intelligence are given.

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“…For example, understanding the amplitude transmittance function in biomedical optics is essential for accurately interpreting optical images of biological tissues [3]. Furthermore, in the design of segmented telescopes, the precise measurement of the piston error, which uses the amplitude transmittance function, is crucial for optimizing the telescope's performance [4]. Fourier Optics has also been used to simulate physical optics, allowing practical performance predictions, including diffraction effects that emerge with fully coherent sources [5].…”

Section: Introductionmentioning

confidence: 99%

Artificial intelligence and Fourier optics: Application of DeepLabV3+ in the recovery of a diffracting aperture in light propagation

Camacho-Bello,

Gutierrez-Lazcano,

Ortega-Mendoza

2024

Rev. Mex. Fís.

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The combination of Fourier Optics and Artificial Intelligence has driven significant advances in image processing and modeling of optical systems, with the UNet architecture being the main protagonist. However, the DeepLabV3+ network has recently shown promising performance in detecting transfer opens. In this study, we investigate the effectiveness of DeepLabV3+ in identifying transfer apertures in light propagation models and compare its performance with that of UNet. The results reveal that DeepLabV3+ outperforms UNet in terms of accuracy and robustness in identifying transfer apertures, even in the presence of noise and aperture shape variations.

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Piston Error Measurement for Segmented Telescopes with an Artificial Neural Network

Cited by 4 publications

References 30 publications

Prediction of Higher Education Cost and Analysis of Sharing Ability Based on Artificial Neural Network

Prediction of Higher Education Cost and Analysis of Sharing Ability Based on Artificial Neural Network

Artificial Intelligence in Astronomical Optical Telescopes: Present Status and Future Perspectives

Artificial intelligence and Fourier optics: Application of DeepLabV3+ in the recovery of a diffracting aperture in light propagation

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