[1] JIANG A, WANG S, DONG Z et al. Wide-band white light sparse-aperture Fizeau imaging interferometer testbed for a distributed small-satellites constellation[J]. Applied Optics, 57, 2736-2746(2018).

[2] XIE Z, MA H, QI B et al. Active sparse aperture imaging using independent transmitter modulation with improved incoherent Fourier ptychographic algorithm[J]. Optics Express, 25, 20541-20555(2017).

[3] ZHOU C, WANG Z. Mid-frequency MTF compensation of optical sparse aperture system[J]. Optics Express, 26, 6973-6992(2018).

[4] STOKES A J, DUNCAN B D, DIERKING M P. Improving mid-frequency contrast in sparse aperture optical imaging systems based upon the Golay-9 array[J]. Optics Express, 18, 4417-4427(2010).

[5] MA X, XIE Z, MA H et al. Piston sensing of sparse aperture systems with a single broadband image via deep learning[J]. Optics Express, 27, 16058-16070(2019).

[6] CARPENTER K G, GENDREAU K, LEITNER J et al. Technology development for future sparse aperture telescopes and interferometers in space[J]. The Astronomy and Astrophysics Decadal Survey, 2010, 47(2009).

[7] WANG D, HAN J, LIU H et al. Experimental study on imaging and image restoration of optical sparse aperture systems[J]. Optical Engineering, 46, 103201(2007).

[8] CHEN J, BENESTY J, HUANG Y et al. New insights into the noise reduction Wiener filter[J]. IEEE Transactions on Audio, Speech, and Language Processing, 14, 1218-1234(2006).

[9] WEI Xiaofeng, GENG Zexun, SONG Xiang. Detection and removal of ringing artifact for optical synthetic aperture restoration image[J]. Optics and Precision Engineering, 22, 3091-3099(2014).

[10] TANG J, WANG K, REN Z et al. RestoreNet: a deep learning framework for image restoration in optical synthetic aperture imaging system[J]. Optics and Lasers in Engineering, 139, 106463(2021).

[11] TANG J, WU J, WANG K et al. RestoreNet-Plus: image restoration via deep learning in optical synthetic aperture imaging system[J]. Optics and Lasers in Engineering, 146, 106707(2021).

[12] HE K, SUN J, TANG X. Single image haze removal using dark channel prior[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 33, 2341-2353(2010).

[13] PAN J, SUN D, PFISTER H et al. Blind image deblurring using dark channel prior[C], 1628-1636(2016).

[14] YAN Y, REN W, GUO Y et al. Image deblurring via extreme channels prior[C], 4003-4011(2017).

[15] HUI M, LI X, ZHANG H et al. Image restoration of optical sparse aperture systems based on a dual target network[J]. Results in Physics, 19, 103429(2020).

[16] BOLCAR M R, FIENUP J R. Sub-aperture piston phase diversity for segmented and multi-aperture systems[J]. Applied Optics, 48, A5-A12(2009).

[17] MA X, XIE Z, MA H et al. Piston sensing for sparse aperture systems with broadband extended objects via a single convolutional neural network[J]. Optics and Lasers in Engineering, 128, 106005(2020).

[18] LIU Z, WANG S Q, RAO C H. The co-phasing detection method for sparse optical synthetic aperture systems[J]. Chinese Physics B, 21, 069501(2012).

[19] HE R, ZHENG W S, TAN T et al. Half-quadratic-based iterative minimization for robust sparse representation[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 36, 261-275(2013).

[20] XU L, LU C, XU Y et al. Image smoothing via L 0 gradient minimization[C], 1-12(2011).

[21] HORE A, ZIOU D. Image quality metrics: PSNR vs. SSIM[C], 2366-2369(2010).