Detection and Classification of Astronomical Targets with Deep Neural Networks in Wide-field Small Aperture Telescopes

Jia, Peng; Liu, Qiang; Sun, Yi

doi:10.3847/1538-3881/ab800a

Cited by 33 publications

(41 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Comparing with our faster-rcnn based framework in Jia et al (2020b), we have added the astrometry and photometry neural network branches at the end of the box regression. The box regression neural network would output types and rough positions of astronomical targets (bounding boxes with four boundary pixels to indicate their position and classification results to indicate types of different celestial objects).…”

Section: The Structure Of the Pnetmentioning

confidence: 99%

“…According to our experience, the bounding box regression in original faster-rcnn based astronomical target detection framework could return position accuracy better than 1 pixel (Jia et al 2020b), which is enough to cross-match stars in catalogue for WFSATs. The astrometry neural network in the PNET could obtain positions of stars with higher accuracy (better than 0.01 pixel for stars with moderate brightness), therefore we will leave along the performance of the astrometry neural network and test the performance of the photometry neural network, which is our main target for development of the PNET.…”

Section: Training the Pnetmentioning

confidence: 99%

“…Besides there are no structural noises in simulated images (cosmic rays, hot pixels or clouds), which will lead to unrealistic good results for the SExtractor: accuracy is almost 1 for bright targets. Detailed comparisons of detection abilities between the PNET and the SExtractor with real observed images can be found in Jia et al (2020b). Besides, for dim targets, the PNET is better than the SExtractor in target detection tasks.…”

Section: Testing the Pnet With Full Frame Of Simulated Imagesmentioning

confidence: 99%

“…For targets with small size, two step detection frameworks have better performance (Ren et al 2015). Therefore we have proposed to use feature pyramid nets and resnet (He et al 2016) to form backbone neural networks and use faster-rcnn structure to form a two step astronomical target detection framework to process images obtained by WFSATs (Jia et al 2020b). Tested with simulated and real observation data, our framework has shown robust performance in detection of astronomical targets of different types.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

The Deep Neural Network based Photometry and Astrometry Framework for Wide Field Small Aperture Telescopes

Jia¹,

Sun²,

Yang³

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Wide field small aperture telescopes (WFSATs) are mainly used to obtain scientific information of point-like and streak-like celestial objects. However, qualities of images obtained by WFSATs are seriously affected by the background noise and variable point spread functions. Developing high speed and high efficiency data processing method is of great importance for further scientific research. In recent years, deep neural networks have been proposed for detection and classification of celestial objects and have shown better performance than classical methods. In this paper, we further extend abilities of the deep neural network based astronomical target detection framework to make it suitable for photometry and astrometry. We add new branches into the deep neural network to obtain types, magnitudes and positions of different celestial objects at the same time. Tested with simulated data, we find that our neural network has better performance in photometry than classical methods. Because photometry and astrometry are regression algorithms, which would obtain high accuracy measurements instead of rough classification results, the accuracy of photometry and astrometry results would be affected by different observation conditions. To solve this problem, we further propose to use reference stars to train our deep neural network with transfer learning strategy when observation conditions change. The photometry framework proposed in this paper could be used as an end-to-end quick data processing framework for WFSATs, which can further increase response speed and scientific outputs of WFSATs.

show abstract

Section: The Structure Of the Pnetmentioning

confidence: 99%

Section: Training the Pnetmentioning

confidence: 99%

Section: Testing the Pnet With Full Frame Of Simulated Imagesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

The Deep Neural Network based Photometry and Astrometry Framework for Wide Field Small Aperture Telescopes

Jia¹,

Sun²,

Yang³

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Kong et al [25] proposed an effect analysis of the optical masking (EAOM) algorithm, which can detect GEO space debris with a low SNR based on a top-hat transformation, masking technique, and weighted algorithm. Jia et al [42] built an astronomical object detection and classification pipeline based on the Faster R-CNN, ResNet-50 [43] and Feature Pyramid Network [44]. These frameworks have a strong ability to detect dim small targets with high accuracy.…”

Section: Introductionmentioning

confidence: 99%

Space Debris Detection Using Feature Learning of Candidate Regions in Optical Image Sequences

Xiang

Ersoy

et al. 2020

IEEE Access

View full text Add to dashboard Cite

Space debris detection is important in space situation awareness and space asset protection. In this paper, we propose a method to detect space debris using feature learning of candidate regions. The acquired optical image sequences are first processed to remove hot pixels and flicker noise, and the nonuniform background information is removed by the proposed one dimensional mean iteration method. Then, the feature learning of candidate regions (FLCR) method is proposed to extract the candidate regions and to detect space debris. The candidate regions of space debris are precisely extracted, and then classified by a trained deep learning network. The feature learning model is trained using a large number of simulated space debris with different signal to noise ratios (SNRs) and motion parameters, instead of using real space debris, which make it difficult to extract a sufficient number of real space debris with diverse parameters in optical image sequences. Finally, the candidate regions are precisely placed in the optical image sequences. The experiment is performed using the simulated data and acquired image sequences. The results show that the proposed method has good performance when estimating and removing background, and it can detect low SNR space debris with high detection probability.INDEX TERMS Space debris detection, background estimation, candidate region extraction, deep learning.

show abstract

Semantic Segmentation of Radio-Astronomical Images

Pino

Renato

Sciacca

et al. 2021

Progress in Artificial Intelligence and Pattern Recognition

View full text Add to dashboard Cite

Detection and Classification of Astronomical Targets with Deep Neural Networks in Wide-field Small Aperture Telescopes

Cited by 33 publications

References 29 publications

The Deep Neural Network based Photometry and Astrometry Framework for Wide Field Small Aperture Telescopes

The Deep Neural Network based Photometry and Astrometry Framework for Wide Field Small Aperture Telescopes

Space Debris Detection Using Feature Learning of Candidate Regions in Optical Image Sequences

Semantic Segmentation of Radio-Astronomical Images

Contact Info

Product

Resources

About