Optimization of Demosaicing Algorithm for Autofluorescence Imaging System

doi:10.1007/s12204-019-2093-3

Journal of Shanghai Jiao Tong University (Science) ›› 2019, Vol. 24 ›› Issue (4): 439-444.doi: 10.1007/s12204-019-2093-3

Optimization of Demosaicing Algorithm for Autofluorescence Imaging System

QIN Shijia (秦诗佳), WANG Zhiwu (王志武), YAN Guozheng* (颜国正), KUANG Shuai (邝帅), CHENG Hao (程浩), XIAO Jie (肖杰)

(School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai 200240, China)

出版日期:2019-08-01 发布日期:2019-07-29
通讯作者: YAN Guozheng* (颜国正) E-mail: gzhyan@sjtu.edu.cn

Optimization of Demosaicing Algorithm for Autofluorescence Imaging System

QIN Shijia (秦诗佳), WANG Zhiwu (王志武), YAN Guozheng* (颜国正), KUANG Shuai (邝帅), CHENG Hao (程浩), XIAO Jie (肖杰)

(School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai 200240, China)

Online:2019-08-01 Published:2019-07-29
Contact: YAN Guozheng* (颜国正) E-mail: gzhyan@sjtu.edu.cn

摘要/Abstract

摘要： Autofluorescence imaging (AFI) systems are widely used in the detection of precancerous lesions. Fluorescence images of precancerous tissue are usually red (R) or blue (B), so this kind of system has high requirement for colour recovery, especially in R and B channels. Besides, AFI system requires bulk data transmission with no time delay. Existing colour recovery algorithms focus more on green (G) channel, overlooking R and B channels. Although the state-of-art demosaicing algorithms can perform well in colour recovery, they often have high computational cost and high hardware requirements. We propose an efficient interpolation algorithm with low complexity to solve the problem. When calculating R and B channel values, we innovatively propose the diagonal direction to select the interpolation direction, and apply colour difference law to make full use of the correlation between colour channels. The experimental results show that the peak signal-to-noise ratios (PSNRs) of G, R and B channels reach 37.54, 37.40 and 38.22 dB, respectively, which shows good performance in recovery of R and B channels. In conclusion, the algorithm proposed in this paper can be used as an alternative to the existing demosaicing algorithms for AFI system.

关键词: autofluorescence imaging (AFI), demosaicing, image recovery, interpolation, peak signal-to-noise ratio (PSNR)

Abstract: Autofluorescence imaging (AFI) systems are widely used in the detection of precancerous lesions. Fluorescence images of precancerous tissue are usually red (R) or blue (B), so this kind of system has high requirement for colour recovery, especially in R and B channels. Besides, AFI system requires bulk data transmission with no time delay. Existing colour recovery algorithms focus more on green (G) channel, overlooking R and B channels. Although the state-of-art demosaicing algorithms can perform well in colour recovery, they often have high computational cost and high hardware requirements. We propose an efficient interpolation algorithm with low complexity to solve the problem. When calculating R and B channel values, we innovatively propose the diagonal direction to select the interpolation direction, and apply colour difference law to make full use of the correlation between colour channels. The experimental results show that the peak signal-to-noise ratios (PSNRs) of G, R and B channels reach 37.54, 37.40 and 38.22 dB, respectively, which shows good performance in recovery of R and B channels. In conclusion, the algorithm proposed in this paper can be used as an alternative to the existing demosaicing algorithms for AFI system.

Key words: autofluorescence imaging (AFI), demosaicing, image recovery, interpolation, peak signal-to-noise ratio (PSNR)

中图分类号:

TP 391

QIN Shijia (秦诗佳), WANG Zhiwu (王志武), YAN Guozheng* (颜国正), KUANG Shuai (邝帅), CHENG. Optimization of Demosaicing Algorithm for Autofluorescence Imaging System[J]. Journal of Shanghai Jiao Tong University (Science), 2019, 24(4): 439-444.

QIN Shijia (秦诗佳), WANG Zhiwu (王志武), YAN Guozheng* (颜国正), KUANG Shuai (邝帅), CHENG Hao (程浩), XIAO Jie (肖杰). Optimization of Demosaicing Algorithm for Autofluorescence Imaging System[J]. Journal of Shanghai Jiao Tong University (Science), 2019, 24(4): 439-444.

参考文献 18

[1]	GUNTURK B K, GLOTZBACH J, ALTUNBASAKY, et al. Demosaicking: Color filter array interpolation[J]. IEEE Signal Processing Magazine, 2005, 22(1):44-54.
[2]	LI X, GUNTURK B, ZHANG L. Image demosaicing:A systematic survey [J]. Proceedings of SPIE, VisualCommunications and Image Processing, 2008, 6822:68221J.
[3]	MENON D, CALVAGNO G. Color image demosaicking:An overview [J]. Signal Processing: Image Communication,2011, 26(8/9): 518-533.
[4]	GRIBBON K T, BAILEY D G. A novel approach toreal-time bilinear interpolation [C]//Proceedings of theSecond IEEE International Workshop on ElectronicDesign, Test and Applications. Perth, WA, Australia:IEEE, 2004: 126-131.
[5]	DUBOIS E. Frequency-domain methods for demosaickingof Bayer-sampled color images [J]. IEEE SignalProcessing Letters, 2005, 12(12): 847-850.
[6]	KEYS R G. Cubic convolution interpolation for digitalimage processing [J]. IEEE Transactions on Acoustics,Speech, and Signal Processing, 1981, 29(6): 1153-1160.
[7]	HIBBARD R H. Apparatus and method for adaptivelyinterpolating a full color image utilizing luminance gradients:US005382976A [P]. 1995-01-17 [2018-06-25].
[8]	LAROCHE C A, PRESCOTT M A. Apparatus andmethod for adaptively interpolating a full color imageutilizing chrominance gradients: US005373322A [P].1994-12-13 [2018-06-25].
[9]	HAMILTON J F, ADAMS J E. Adaptive color planinterpolation in single sensor color electronic camera:US005629734A [P]. 1997-05-13 [2018-06-25].
[10]	WU X R, ZHAO Q F, YASUHIRO Y. A wavelet interpolationapplied to the Bayer color filter array [J].Computer Engineering and Applications, 2005 (26):64-65 (in Chinese)
[11]	ALLEYSSON D, S¨USSTRUNK S, H′ERAULT J. Colordemosaicing by estimating luminance and opponentchromatic signals in the Fourier domain [C]//10thIS&T/SID Color Imaging Conference: Color Scienceand Engineering: Systems, Technologies, Applications.Scottsdale, Arizona, USA: The Society for Imaging Scienceand Technology, 2002: 331-336.
[12]	ZHANG L, WU X L. An edge-guided image interpolationalgorithm via directional filtering and data fusion[J]. IEEE Transactions on Image Processing, 2006,15(8): 2226-2238.
[13]	MENON D, ANDRIANI S, CALVAGNO G. Demosaicingwith directional filtering and a posteriori decision[J].IEEE Transactions on Image Processing, 2007,16(1): 132-141.
[14]	WANG L, JEON G. Bayer pattern CFA demosaickingbased on multi-directional weighted interpolation andguided filter [J]. IEEE Signal Processing Letters, 2015,22(11): 2083-2087.
[15]	MONNO Y, KIKU D, TANAKA M, et al. Adaptiveresidual interpolation for color image demosaicking[C]//2015 IEEE International Conference on ImageProcessing (ICIP). Quebec City, QC, Canada: IEEE,2015: 3861-3865.
[16]	LIU G, YAN G Z. Recent research progress and developmentdirection of autofluorescence diagnosis technology[J]. Journal of Biomedical Engineering, 2015,32(6): 1348-1353 (in Chinese).
[17]	ZHANG Y D, LIU W D, PENG J. Differences in laserinducedautofluorescence between normal and carcinomatouscolorectal tissures [J]. China Journal of ModernMedicine, 2000, 10(9): 1-4 (in Chinese).
[18]	ZHOU T. Adaptive demosaicing algorithms based onBayer color filter array [D]. Taiyuan, China: TaiyuanUniversity of Technology, 2011 (in Chinese).

Optimization of Demosaicing Algorithm for Autofluorescence Imaging System

Optimization of Demosaicing Algorithm for Autofluorescence Imaging System

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