參考文獻 |
1. T. H. Jamieson, “Thermal effects in optical systems,” Opt. Eng. 20, 156-160 (1981).
2. https://www.nhtsa.gov/technology-innovation/automated-vehicles-safety
3. IHS, ADAS-Current and Future Perspectives. IHS Automotive Seminar , Frankurt, Germany. (2015,June).
4. SAE INTERNATIONAL, ADAS/CONNECTED CAR. Warrendale, PA, U.S.A. (2018,Dec).
5. Mobile vision technology Ltd, Forward-facing multi-image a vechicle . U.S.PATENT Pub. No. US2015/0103159 A1. (2015).
6. Google Inc, Cross-validating sensors of an autonomous vehcle, U.S. PATENT No. US9221396 B1. (2015).
7. Maria S. Greco, Automotive Radar. IEEE Radar Conference , Atlanta, U.S.A. (2012,May).
8. R. W. Wood, “Refraction of Light,” in Handbook of PhysicalOptics (Optical Society of America, Washington, DC, 1911).
9. R. Hill, “A Lens for Whole Sky Photography,” in Proceedings of the Optical Convention , (London, 1926) , pp.878-883.
10. J. Y. Zheng and S. G. Li, “Employing a fish-eye for scene tunnel Scanning,” in Asian Conference on Computer Vision,( Hyderabad, 2006), pp. 509.
11. W. S. Sun, C. L. Tien, Y. H. Chen, P. Y. Chu, “Ultra-wide angle lens design with relative illumination analysis,” J. Eur. Opt. Soc. –Rapid 11, 16001 (2016).
12. D. S. Grey, “Athermalization of Optical Systems,” J. Opt. Soc. Am, 38, 542-546 (1948).
13. M. J. Duggin, “Discrimination of targets from background of similar temperature, using two-channel data in the 3.5-4.1-m and 11–12-m regions,” Appl. Opt. 25(7), 1186–1195 (1986).
14. M. H. Horman, “Temperature analysis from multispectral infrared data,” Appl. Opt. 15(9), 2099–2104 (1976).
15. T. H. Jamieson, “Ultrawide waveband optics,” Opt. Eng. 23(2), 111–116 (1984).
16. M. Roberts and P. J. Rogers, “Wide waveband infrared optics,” Proc. SPIE 1013, 84–91 (1988).
17. Y. Tamagawa and T. Tajime, “Dual-band optical systems with a projective athermal chart: design,” Appl. Opt. 36(1), 297–301 (1997).
18. J. L. Rayces, L. Lebich, “Thermal compensation of infrared achromatic objectives with three optical materials,” Proc. SPIE 1354, 752-759 (1990).
19. I. Friedman, “Thermo-optical analysis of two long-focal length aerial reconnaissance lenses,” Opt. Eng. 20, 161-165 (1981).
20. W. Shi, M. E. Couture, “Long wave infrared zoom projector thermal analysis and compensation,” Opt. Eng. 39, 2705-2714 (2000).
21. M. Bayar, Ő. F. Farsakoğlu, “Mechanically active athermalization of a forward looking infrared system,” Infrared Physics & Technology 43, 91-99 (2002).
22. C. W. Kuo, C. L. Lin, and C. Y. Han, “Dual field-of-view midwave infrared optical design and athermalization analysis,” Appl. Opt. 49(19), 3691–3700 (2010).
23. Y. Tamagawa, S. Wakabayashi, T. Tajime, and T. Hashimoto, “Multilens system design with an athermal chart,” Appl. Opt. 33, 8009-8013 (1994).
24. Y. Tamagawa, T. Tajime, “Expansion of an athermal chart into a multilens system with thick lenses spaced apart,” Opt. Eng. 35, 3001-3006 (1996).
25. Y. J. Kim, Y. S. Kim, and S. C. Park, “Simple graphical selection of optical materials for an athermal and achromatic design using equivalent Abbe number and thermal glass constant,” Journal of the optical society of Korea 19, 182-187 (2015).
26. R. C. Simmons and P. A. Blaine, ‘‘Stability of aberrations with temperature in fast thermal imaging zoom telescopes,’’ Proc. SPIE 916, 19–26 (1988).
27. C. W. Kuo, J. M. Miao, and C. H. Tai, “Midwave infrared optical zooming design and kinoform degrading evaluation methods,” Appl. Opt. 50(18), 3043–3049 (2011).
28. G. P. Behrmann and John P. Bowen, “Influence of temperature on diffractive lens performance,” Appl. Opt. 32, 2483-2489 (1993).
29. C. Londoňo, W. T. Plummer, P. P. Clark, “Athermalization of a single-component lens with diffractive optics,” Appl. Opt. 32(13), 2295-2302 (1993).
30. R. M. Hudyma, “Athermal MWIR Objectives,” Proc. SPIE 2540, 229-235 (1995).
31. V. Povey, “Athermalisation technique in infrared systems,” Proc. SPIE, 655, 142–153 (1986).
32. R. Q. Wu, K. Huang, H. Yang, J. Wang, Y. Liu, “Analysis of athermalizing performance of thermal infrared optical system with Cassegrain antenna,” Optik 121, 1904-1907 (2010).
33. H. S. Yang et al., “Three-shell-based lens barrel for the effective athermalization of an IR optical system,” Appl. Opt. 50(33), 6206-6213 (2011).
34. A. H. Wang, Q. H. Wang, X. F. Li and D. H. Li, “Combined lenticular lens for autostereoscopic three dimensional display,” Optik 123, 827-830 (2012).
35. O. V. Ponin and A. A. Sharov, “Apochromatic thermally nonmisadjustable objectives for wide-range multispectral space imaging,” J. Opt. Technol. 80, 230-232 (2013).
36. B. N. Walker, R. H. James, D. Calogero, and I. K. Iiev, “Impact of environmental temperature on optical power properties of intraocular lenses,” Appl. Opt. 53, 453-457 (2014).
37. Schott, Optical Glass Catalogue Excel (Schott Inc., Germany, June, 2012).
38. P. J. Rogers, “Athermalized FLIR optics,” Proc. SPIE 1354, 742-751 (1990).
39. Schott, “TIE-29: Refractive index and dispersion,” in Proc. Schott Technical information (Schott Inc., Germany, 2015).
40. Schott, “TIE-19: Temperature coefficient of the refractive index,” in Proc. Schott Technical information (Schott Inc., Germany, July 2008).
41. J.M. Palmer, B.G. Grant.The Art of Radiometry (SPIE press Bellingham WA, USA, 2010).
42. Grant R. Fowles, Introduction to Modern optics. Second ed, New York.Holt Rinehart and Winston Inc.
43. Schott, “TIE-35: Transmittance of optical glass ,” in Proc. Schott Technical information (Schott Inc., Germany, Oct 2005).
44. Automotive Image Sensor
https://www.sony-semicon.co.jp/products_en/IS/sensor4/index.html
45. SUMITOMO E6007LHF
https://www.sumitomo-chem.co.jp/sep/english/products/lcp/
46. 高鳳遙,「超大廣角鏡頭在溫度-20C至60C對熱的分析與校正之鏡頭設計」,國立中央大學,碩士論文,民國105年。
47. 徐英舜,「汽車超大廣角於溫度-30C至70C消熱差與高相對照度之鏡頭設計」,國立中央大學,碩士論文,民國106年。
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