Photorealistic Ray-traced Visualization Approach for the Interactive Biomimetic Design of Insect Compound Eyes |
Nguyen, Tung Lam
(Department of Mechanical Engineering, Hanbat National University)
Trung, Hieu Tran Doan (Department of Mechanical Engineering, Hanbat National University) Lee, Wooseok (Department of Mechanical Engineering, Hanbat National University) Lee, Hocheol (Department of Mechanical Engineering, Hanbat National University) |
1 | S. Eddins, "Multiresolution Pyramid part 3: Laplacian pyramids," (MathWorks, Published date: 2019 April 16) https://blogs.mathworks.com/steve/2019/04/16/multiresolution-pyramids-part-3-laplacian-pyramids/?s_tid=blogs_rc_1 (Accessed date: 2020 July). |
2 | M. F. Land and D.-E. Nilsson, Animal Eyes, 2nd ed. (Oxford University Express, NY, USA. 2012). |
3 | K.-H. Jeong, J. Kim, and L. P. Lee, "Biologically inspired artificial compound eyes," Science 312, 557-561 (2006). DOI |
4 | A. Bruckner, J. Duparre, R. Leitel, P. Dannberg, A. Brauer, and A. Tunnermann, "Thin wafer-level camera lenses inspired by insect compound eyes," Opt. Express 18, 24379-24394 (2010). DOI |
5 | Y. Xiong and K. Pulli, "Fast panorama stitching for highquality panoramic images on mobile phones," IEEE Trans. Consum. Electron. 56, 298-306 (2010). DOI |
6 | C. S. Min, Y. W. Kim, and J. S. Lee, "Analysis of interrelation between FFR and OCTCT diagnostic for bending stenosed blood vessel using CFD," in Proc. Korean Society of Manufacturing Technology Engineers Autumn Annual Conference (Seoul, Korea, Oct. 2018), p. 9. |
7 | Z. Wang and Z. Yang, "Review on image stitching techniques," Multimed. Syst. 26, 413-430 (2020). DOI |
8 | C. Je and H.-M. Park, "Optimized hierarchical block matching for fast and accurate image registration," Signal Process. Image Commun. 28, 779-791 (2013). DOI |
9 | J. Kim and J. A. Fessler, "Intensity based image registration using robust correlation coefficients," IEEE Trans. Med. Imaging 23, 1430-1444 (2004). DOI |
10 | M. Brown and D. Lowe, "Automatic panoramic image stitching using invariant features," Int. J. Comput. Vis. 74, 59-73 (2007). DOI |
11 | D. G. Lowe, "Distinctive image features from scale-invariant key points," Int. J. Comput. Vis. 60, 91-110 (2004). DOI |
12 | H. Bay, T. Tuytelaars, and L. G. Van, "SURF: Speeded up robust features," in Computer Vision-ECCV 2006 (Lecture Notes in Computer Science Series, Vol. 3951), A. Leonardis, H. Bischof, A. Pinz, Eds. (Springer, Berlin, Germany, 2006). |
13 | P. J. Burt and E. H. Adelson, "A multiresolution spline with application to image mosaics," ACM. Trans. Graph. 2, 217-236 (1983). DOI |
14 | S. Wu, T. Zhang, G. Zhang, B. Schoenemann, F. Neri, M. Zhu, C. Bu, J. Han, and K.-D. Kuhnert, "Artificial compound eye: a survey of the state-of-the-art," Artif. Intell. Rev. 48, 573-603 (2017). DOI |
15 | H. Lee, M. Park, H. Lee, and H.-J. Choi, "An analysis on the range of singular fusion of augmented reality devices," Curr. Opt. Photon. 4, 540-544 (2020). DOI |
16 | Z. Wang, A. C. Bovik, H. R. Sheikh, and E. P. Simoncelli, "Image quality assessment: from error visibility to structural similarity," IEEE Trans. Image Process. 13, 600-612 (2004). DOI |
17 | L. Lei and A. Y. Yi, "Design and fabrication of a freeform microlens array for a compact large-field-of-view compound-eye camera," Appl. Opt. 51, 1843-1852 (2012). DOI |
18 | J. Duparre, P. Dannberg, P. Schreiber, A. Brauer, and A. Tunnermann, "Thin compound-eye camera," Appl. Opt. 44, 2949-2956 (2005). DOI |
19 | Y. Cheng, J. Cao, Q. Hao, F. Zhang, S. Wang, W. Xia, L. Meng, Y. Zhang, and H. Yu, "Compound eye and retinalike combination sensor with a large field of view based on a space-variant curved micro lens array," Appl. Opt. 56, 3502-3509 (2017). DOI |
20 | O. Cogal and Y. Leblevichi, "An insect eye inspired miniaturized multi camera system for endoscopic imaging," IEEE Trans. Biomed. Circuits Syst. 11, 212-224 (2017). DOI |
21 | G. Edward, "Optics and phylogeny: is there an insight? The evolution of superposition eyes in the Decapoda (Crustacea)," Contrib. Zool. 67, 223-236 (1998). DOI |
22 | M. F. Land, "Optics and vision in invertebrates," in Handbook of sensory physiology, H. Autrum, Ed. (Springer, 1981), Vol. VII/6B, pp. 471-592. |
23 | R. Szeliski, "Image alignment and stitching: A tutorial," Found. Trends Comput. Graph. Vis. (2006). |
24 | S. T. Y. Suen, E. Y. Lam, and K. K. Y. Wong, "Photographic stitching with optimized object and color matching based on image derivatives," Opt. Express 15, 7689-7696 (2007). DOI |
25 | H. Lee, U. Yang, and H.-J. Choi, "Analysis of the design parameters for a lightfield near-eye display based on a pinhole array," Curr. Opt. Photon. 4, 121-126 (2020). DOI |
26 | Y. Li and V. Monga, "SIASM: Sparsity based image alignment and stitching method for robust image mosaicking," in Proc. IEEE International Conference on Image Processing -ICIP (Phoenix, AZ, USA, Sept. 2016), pp. 1828-1832. |
27 | Y. Li, M. Tofighi, and V. Monga, "Robust alignment for panoramic stitching via an exact rank constraint," IEEE Trans. Image Process. 28, 4730-4745 (2019). DOI |
28 | P. F. Alcantarilla, A. Bartoli, and A. J. Davison, "KAZE Features," in Computer Vision-ECCV 2012 (Lecture Notes in Computer Science Sereis, Vol. 7577), A. Fitzgibbon, S. Lazebnik, P. Perona, Y. Sato, C. Schmid, Eds. (Springer, Berlin,Germany, 2012). |
29 | Q. Wu, H. Li, F. Meng, and K. N. Ngan, "A perceptually weighted rank correlation indicator for objective image quality assessment," IEEE Trans. Image Process. 27, 2499-2513 (2018). DOI |