基本信息
刘诚  男  博导  中国科学院上海光学精密机械研究所
电子邮件: cheng.liu@hotmail.co.uk
通信地址: 中科院上海光机所联合室
邮政编码:

招生信息

   
招生专业
080300-光学工程
招生方向
光学测量,光学成像

教育背景

2000-03--2003-03   上海光机所   博士

工作经历

   
工作简历
2003-08~2011-04,新加坡国立大学、韩国延世大学、韩国光州科技研究院、英国谢菲尔德大学, 博士后

专利与奖励

   
奖励信息
(1) 中国仪器仪表学会科学技术奖一等奖, 一等奖, 其他, 2018
(2) 首届中国欧雷奥光电精英赛一等奖, 一等奖, 其他, 2017
(3) 首届中国军民两用技术创新应用大赛金奖, 一等奖, 部委级, 2016
专利成果
[1] 潘兴臣, 刘诚, 朱健强. 基于动态调制的单次曝光波前重建和相位成像装置和方法. CN: CN111474188B, 2021-07-27.

[2] 潘兴臣, 徐英明, 刘诚, 朱健强. 一种基于分束元件的单次曝光复振幅测量装置和方法. CN: CN112880844A, 2021-06-01.

[3] 潘兴臣, 刘诚, 朱健强. 基于波前调制的相位成像及元件检测的装置和方法. CN: CN112683794A, 2021-04-20.

[4] 潘兴臣, 徐英明, 刘诚, 朱健强. 一种超快时间复振幅测量装置和方法. CN: CN112539823A, 2021-03-23.

[5] 刘诚, 浦东, 潘兴臣, 陶华, 朱健强. 二维光学传递函数测量装置及方法. CN: CN112229603A, 2021-01-15.

[6] 朱健强, 葛银娟, 潘兴臣, 董学, 陶华, 刘诚. 多波长光场能量测量方法. CN: CN110736556B, 2021-01-01.

[7] 张雪洁, 程北, 沈卫星, 刘诚, 朱健强. 一种高分辨率的近场波前测量装置和测量方法. CN: CN110160663B, 2020-12-04.

[8] 潘兴臣, 刘诚, 朱健强. 基于波前测量的光学元件缺陷检测装置和检测方法. CN: CN109708854B, 2020-11-10.

[9] 张雪丹, 刘诚, 朱健强. 基于K空间变换的三维成像装置及其成像方法. CN: CN109085137B, 2020-08-28.

[10] 刘诚, 何思源, 潘兴臣, 朱健强. 长距离端面粗糙晶体体内缺陷测量装置和方法. CN: CN111208089A, 2020-05-29.

[11] 潘兴臣, 刘诚, 朱健强. 基于振幅调制的波前在线快速重建装置和重建方法. CN: CN108332866B, 2020-02-21.

[12] 朱健强, 潘良泽, 张雪洁, 刘诚, 欧阳小平. 一种高分辨大量程时域测量装置. CN: CN110686784A, 2020-01-14.

[13] 刘诚, 昌成成, 董学, 陶华, 潘兴臣, 朱健强. 相位恢复成像装置和成像方法. CN: CN110687078A, 2020-01-14.

[14] 陶华, 刘诚, 朱健强. 激光等离子体电子密度测量方法. CN: CN108174503B, 2019-09-20.

[15] 刘诚, 何西, 潘兴臣, 陶华, 朱健强. 编码分束相位测量装置和测量方法. CN: CN107300420B, 2019-08-13.

[16] 刘诚, 渠勍, 何小亮, 潘兴臣, 陶华, 朱健强. 基于大功率LED亮度自适应照明的显微成像装置及测量方法. CN: CN110082350A, 2019-08-02.

[17] 朱健强, 程北, 张雪洁, 刘诚. 基于衍射重叠迭代算法的应力测量装置和方法. 中国: CN108760112A, 2018.11.06.

[18] 刘诚, 董学, 潘兴臣, 陶华. 多波长复合光场在线测量装置和测量方法. 中国: CN107036711B, 2018.06.19.

[19] 刘诚, 陈文, 王海燕, 朱健强. 高分辨率三维相位显微成像装置和成像方法. 中国: CN105806250B, 2018-04-17.

[20] 蒋志龙, 程君, 陈文, 潘兴臣, 陶华, 刘诚, 朱健强. 高分辨率数字全息显微成像装置和成像方法. 中国: CN104808469A, 2015-07-29.

[21] 孙晓鹏, 刘诚, 朱健强. 基于形貌相关计算的三维位移测量方法. 中国: CN104634253A, 2015-05-20.

[22] 陶华, 潘兴臣, 王海燕, 刘诚, 朱健强. 大口径光学元件二次曝光相位测量装置及测量方法. 中国: CN104634542A, 2015-05-20.

[23] 陶华, 潘兴臣, 刘诚, 朱健强. 可移动式高功率激光光束波前测量装置及其测量方法. 中国: CN104198054A, 2014.12.10.

[24] 潘兴臣, 王海燕, 程君, 刘诚, 朱健强. 光束相位在线测量装置和测量方法. 中国: CN103884436A, 2014-06-25.

[25] 王海燕, 刘诚, 潘兴臣, 孙美智, 程君, 朱健强. 透射型光学元件分层相位成像的装置和方法. 中国: CN103837325A, 2014-06-04.

[26] 王海燕, 刘诚, 潘兴臣, 程君, 孙美智, 朱健强. 透射型大口径元件相位测量装置和测量方法. 中国: CN103499429A, 2014-01-08.

[27] 潘兴成, 刘诚, 朱健强. 利用光栅实现物体成像的装置. 中国: CN103246077A, 2013-08-14.

[28] 潘兴臣, 刘诚, 朱健强. 透射型样品振幅和相位成像装置和方法. 中国: CN102866133A, 2013-01-09.

[29] 潘兴臣, 刘诚, 朱健强. 透射型样品相位显微装置和相位显微方法. 中国: CN102645739A, 2012-08-22.

[30] 刘诚, 戴亚平, 李银柱, 李良玉, 朱健强. 无直透光和共轭像的电子全息测量方法. 中国: CN1147704, 2004-04-28.

[31] 刘诚, 李银柱, 戴亚平, 朱健强. 导数场的测量方法. 中国: CN1284648, 2001-02-21.

出版信息

   
发表论文
[1] Pan, Liangze, Liu, Cheng, Veetil, Suhas P, Zhu, Jianqiang. Temporal self-referencing technique for the diagnostics of nanosecond laser pulse. OPTICS AND LASERS IN ENGINEERING[J]. 2022, 148: http://dx.doi.org/10.1016/j.optlaseng.2021.106751.
[2] Lin, Rong, He, Xiaoliang, Jiang, Zhilong, Liu, Cheng, Wang, Shouyu, Kong, Yan. Dual-layer graphene based tunable broadband terahertz absorber relying on the coexistence of hybridization and stacking effects. JOURNAL OF PHYSICS D-APPLIED PHYSICS[J]. 2021, 54(14): https://www.webofscience.com/wos/woscc/full-record/WOS:000612330800001.
[3] 潘良泽, 刘诚, 朱健强. 基于时域剪切干涉的纳秒脉冲相位测量技术. 物理学报. 2021, 70(18): 138-145, http://lib.cqvip.com/Qikan/Article/Detail?id=7105612817.
[4] Pu, Dong, Pan, Xingchen, Tao, Hua, Liu, Cheng, Zhu, Jianqiang. Iterative reconstruction method for the accurate measurement of optical transfer function. APPLIED OPTICS[J]. 2021, 60(26): 8164-8173, [5] 孙劭伟, 齐乃杰, 孔艳, 刘诚, 高淑梅. 熔石英玻璃激光损伤的三维应力场研究. 中国激光. 2021, 48(1): 25-35, http://lib.cqvip.com/Qikan/Article/Detail?id=7104412339.
[6] 潘良泽, 刘诚, 朱健强. 基于时域剪切的纳秒脉冲在线测量算法. 中国激光. 2021, 103-110, https://t.cnki.net/kcms/detail?v=3uoqIhG8C44YLTlOAiTRKu87-SJxoEJu6LL9TJzd50kSWInUBY3P8VzHJDdpE87EXO4IJDfN8pCTUZ8AwzG2lKbkSHnuri6u&uniplatform=NZKPT.
[7] 潘兴臣. 二元振幅调制的单次曝光光束质量分析技术研究. 中国激光. 2021, [8] He, Siyuan, Pan, Xingchen, Liu, Cheng, Zhu, Jianqiang. Further improvements to iterative off-axis digital holography. OPTICS EXPRESS[J]. 2021, 29(12): 18831-18844, [9] Chang, Chengcheng, Pan, Xingchen, Tao, Hua, Liu, Cheng, Veetil, Suhas P, Zhu, Jianqiang. 3D single-shot ptychography with highly tilted illuminations. OPTICS EXPRESS[J]. 2021, 29(19): 30878-30891, [10] 潘兴臣, 刘诚, 陶华, 刘海岗, 朱健强. Ptychography相位成像及其关键技术进展. 光学学报[J]. 2020, 40(1): 157-174, http://lib.cqvip.com/Qikan/Article/Detail?id=7101495112.
[11] He, Xiaoliang, Jiang, Zhilong, Kong, Yan, Wang, Shouyu, Liu, Cheng. Fourier ptychography via wavefront modulation with a diffuser. OPTICS COMMUNICATIONS[J]. 2020, 459: http://dx.doi.org/10.1016/j.optcom.2019.125057.
[12] Qiu, Peng, Hu, Zhengda, Liu, Ting, Jiang, Zhilong, Liu, Cheng, Kong, Yan, Wang, Shouyu. Simultaneous and Quantitative Spin and Orbital Angular Momentum Detector. IEEE PHOTONICS TECHNOLOGY LETTERS[J]. 2020, 32(15): 944-947, https://www.webofscience.com/wos/woscc/full-record/WOS:000548752700001.
[13] Jiang, Zhilong, Pan, Xingchen, He, Xiaoliang, Kong, Yan, Wang, Shouyu, Liu, Cheng. Phase Retrieval of On-Axis Digital Holography With Modified Coherent Diffraction Imaging. IEEE PHOTONICS JOURNAL[J]. 2020, 12(6): https://doaj.org/article/ce87b098c2384bdfae1f73483c086cc4.
[14] He, Xiaoliang, Tao, Hua, Jiang, Zhilong, Kong, Yan, Wang, Shouyu, Liu, Cheng. Single-shot optical multiple-image encryption by jointly using wavelength multiplexing and position multiplexing. APPLIED OPTICS[J]. 2020, 59(1): 9-15, https://www.webofscience.com/wos/woscc/full-record/WOS:000506807000002.
[15] He, Xiaoliang, Veetil, Suhas P, Jiang, Zhilong, Kong, Yan, Wang, Shouyu, Liu, Cheng. High-speed coherent diffraction imaging by varying curvature of illumination with a focus tunable lens. OPTICS EXPRESS[J]. 2020, 28(17): 25655-25663, https://www.webofscience.com/wos/woscc/full-record/WOS:000560936200105.
[16] Qiu, Peng, Kong, Yan, Hu, Zhengda, Jiang, Zhilong, He, Xiaoliang, Liu, Cheng, Liu, Ting, Wang, Shouyu. Simultaneous light spin and orbital angular momentum detection using orthogonal nanoslit pairs in semi-ring array. PHOTONICS AND NANOSTRUCTURES-FUNDAMENTALS AND APPLICATIONS[J]. 2020, 41: http://dx.doi.org/10.1016/j.photonics.2020.100814.
[17] Luan, Jiayun, He, Xiaoliang, Jiang, Zhilong, Kong, Yan, Wang, Shouyu, Liu, Cheng. Speckle-illuminated Fourier ptychography: analysis of diffuser roughness and reconstruction aperture on imaging performance. APPLIED OPTICS[J]. 2020, 59(7): 2201-2210, https://www.webofscience.com/wos/woscc/full-record/WOS:000526525000060.
[18] Chengcheng, Chang, Xingchen, Pan, Hua, Tao, Cheng, Liu, Jianqiang, Zhu. Reconstruction Algorithm for Ptychographic Iterative Engine with Highly Tilted Illumination. ACTA OPTICA SINICA[J]. 2020, 40(17): [19] He, Xiaoliang, Jiang, Zhilong, Kong, Yan, Wang, Shouyu, Liu, Cheng. Optical multi-image encryption based on focal length multiplexing and multimode phase retrieval. APPLIED OPTICS[J]. 2020, 59(26): 7801-7812, https://www.webofscience.com/wos/woscc/full-record/WOS:000571484700008.
[20] 刘诚. 相干调制成像技术迭代收敛性及重建唯一性研究. 光学学报. 2020, [21] Cheng, Bei, Zhang, Xuejie, Liu, Cheng, Zhou, Li, Ren, Zhiyuan, Zhang, Lijuan, Yuan, Xiaodong, Zhu, Jianqiang. Measurement of stress vector based on polarization ptychography. OPTICS AND LASERS IN ENGINEERING[J]. 2020, 133: http://dx.doi.org/10.1016/j.optlaseng.2020.106058.
[22] Chang, Chengcheng, Pan, Xingchen, Tao, Hua, Liu, Cheng, Veetil, Suhas P, Zhu, Jianqiang. Single-shot ptychography with highly tilted illuminations. OPTICS EXPRESS[J]. 2020, 28(19): 28441-28451, https://www.webofscience.com/wos/woscc/full-record/WOS:000569207700097.
[23] 昌成成, 潘兴臣, 陶华, 刘诚, 朱健强. 大角度倾斜照明条件下的PIE迭代重建算法研究. 光学学报[J]. 2020, 40(17): 28-37, http://lib.cqvip.com/Qikan/Article/Detail?id=7103161801.
[24] Pan Xingchen, Liu Cheng, Zhu Jianqiang. Iterative Convergence and Reconstruction Uniqueness of Coherent Modulation Imaging. ACTA OPTICA SINICA[J]. 2020, 40(18): [25] Wei, Qi, Zhang, Mingyuan, Yu, Miao, Xue, Liang, Liu, Cheng, Vargas, Javier, Liu, Fei, Wang, Shouyu. Rapid quantitative interferometric microscopy using fast Fourier transform and differential-integral based phase retrieval algorithm (FFT-DI-PRA). OPTICS COMMUNICATIONS[J]. 2020, 456: http://dx.doi.org/10.1016/j.optcom.2019.124613.
[26] 齐乃杰, 袁晓东, 张丽娟, 刘诚. 激光损伤残余应力三维检测技术. 中国激光[J]. 2020, 47(10): 149-155, http://lib.cqvip.com/Qikan/Article/Detail?id=7103301800.
[27] Pan, Liangze, Ouyang, Xiaoping, Zhang, Xuejie, Zhu, Ping, Liu, Cheng, Li, Zhan, Zhu, Baoqiang, Zhu, Jian, Zhu, Jianqiang. Picosecond frequency-resolved optical gating based on a modified ptychographic-based algorithm for use in a petawatt laser. OPTICAL ENGINEERING[J]. 2020, 59(5): https://www.webofscience.com/wos/woscc/full-record/WOS:000542976000018.
[28] Qi, Naijie, Sun, Shaowei, Zhang, Lijuan, Yuan, Xiaodong, Kong, Yan, Veetil, Suhas P, Wang, Shouyu, Liu, Cheng. Microscopic three-dimensional inner stress measurement on laser induced damage. OPTICS EXPRESS[J]. 2020, 28(16): 24253-24261, http://dx.doi.org/10.1364/OE.399002.
[29] Ge YinJuan, Pan XingChen, Liu Cheng, Zhu JianQiang. Technique of detecting optical components based on coherent modulation imaging. ACTA PHYSICA SINICA[J]. 2020, 69(17): https://www.webofscience.com/wos/woscc/full-record/WOS:000567991500009.
[30] Jeon, Philjun, Lee, Heejung, Kim, Jongwu, Liu, Cheng, Kim, Dugyoung. Analysis of three-dimensional mapping problems in incoherent digital holography. OPTICS EXPRESS[J]. 2020, 28(4): 4501-4515, http://dx.doi.org/10.1364/OE.384477.
[31] 葛银娟, 潘兴臣, 刘诚, 朱健强. 基于相干调制成像的光学检测技术. 物理学报[J]. 2020, 69(17): 87-94, http://lib.cqvip.com/Qikan/Article/Detail?id=7102725375.
[32] Dong, Xue, Pan, Xingchen, Liu, Cheng, Zhu, Jianqiang. An online diagnosis technique for simultaneous measurement of the fundamental, second and third harmonics in one snapshot. HIGH POWER LASER SCIENCE AND ENGINEERING[J]. 2019, 7(3): 102-110, http://lib.cqvip.com/Qikan/Article/Detail?id=7100485073.
[33] 程北, 张雪洁, 刘诚, 朱健强. 基于衍射重叠相位恢复术的平面偏振双折射测量. 中国激光[J]. 2019, 46(12): 164-170, http://lib.cqvip.com/Qikan/Article/Detail?id=7100906505.
[34] Bei, Cheng, Zhang Xuejie, Cheng, Liu, Zhu, Jianqiang. Full-field stress measurement based on polarization ptychography. JOURNAL OF OPTICS[J]. 2019, 21(6): [35] Zhang, Xuejie, Cheng, Bei, Liu, Cheng, Shen, Weixing, Dong, Xue, Ma, Xiaojun, Zhu, Jianqiang. Measurement of mid-frequency wavefront error for large optical components with ptychography. APPLIED OPTICS[J]. 2019, 58(2): 264-269, [36] Jiang, Zhilong, Li, Yuanjie, Kong, Yan, Meng, Lei, Wang, Shouyu, Liu, Cheng. Mollenstedt biprism based shearing ptychographic iterative engine method. ULTRAMICROSCOPY[J]. 2019, 202: 57-67, [37] Shan, Yanke, Gong, Qingtao, Wang, Jian, Xu, Jing, Wei, Qi, Liu, Cheng, Xue, Liang, Wang, Shouyu, Liu, Fei. Measurements on ATP induced cellular fluctuations using real-time dual view transport of intensity phase microscopy. BIOMEDICAL OPTICS EXPRESS[J]. 2019, 10(5): 2337-2354, https://www.webofscience.com/wos/woscc/full-record/WOS:000466477700013.
[38] Jiang, Zhilong, Kong, Yan, Qian, Weiying, Wang, Shouyu, Liu, Cheng. Resolution and signal-to-noise ratio enhancement for synthetic coded aperture imaging via varying pinhole array. APPLIED OPTICS[J]. 2019, 58(22): 6157-6164, https://www.webofscience.com/wos/woscc/full-record/WOS:000478073200046.
[39] Xu, Jing, Kong, Yan, Jiang, Zhilong, Gao, Shumei, Xue, Liang, Li, Fei, Liu, Cheng, Wang, Shouyu. Accelerating wavefront-sensing-based autofocusing using pixel reduction in spatial and frequency domains. APPLIED OPTICS[J]. 2019, 58(11): 3003-3012, [40] Sun, Aihui, Jiang, Zhilong, Kong, Yan, Xue, Liang, Wang, Shouyu, Liu, Cheng. Multi-probe ptychographic iterative engine method. OPTICS COMMUNICATIONS[J]. 2019, 436: 174-179, http://dx.doi.org/10.1016/j.optcom.2018.11.077.
[41] Zong, Bangming, Luan, Jiayun, Jiang, Zhilong, Kong, Yan, Wang, Shouyu, Liu, Cheng. Quantitative aberration measurement with extended ptychographic iterative engine. OPTICAL ENGINEERING[J]. 2019, 58(5): https://www.webofscience.com/wos/woscc/full-record/WOS:000481889500022.
[42] Zhang, Xuedan, Veetil, Suhas P, Liu, Cheng, Zhu, Jianqiang. Three-dimensional target monitoring technique based on a morphology correlation for high-power laser applications. APPLIED OPTICS[J]. 2019, 58(17): 4781-4786, https://www.webofscience.com/wos/woscc/full-record/WOS:000470847200030.
[43] Wei, Qi, Li, Yangyang, Vargas, Javier, Wang, Jian, Gong, Qingtao, Kong, Yan, Jiang, Zhilong, Xue, Liang, Liu, Cheng, Liu, Fei, Wang, Shouyu. Principal component analysis-based quantitative differential interference contrast microscopy. OPTICS LETTERS[J]. 2019, 44(1): 45-48, https://www.webofscience.com/wos/woscc/full-record/WOS:000454111300012.
[44] Ai, Lingyu, Shi, Xiao, Yan, Zhiqiang, Liu, Cheng, Wang, Shouyu. Adaptive periodic delta-function array-based three-dimensional optical refocusing from elemental image array. OPTICAL ENGINEERING[J]. 2019, 58(11): [45] Pan, Xingchen, Liu, Cheng, Zhu, Jianqiang. Phase retrieval with extended field of view based on continuous phase modulation. ULTRAMICROSCOPY[J]. 2019, 204: 10-17, http://dx.doi.org/10.1016/j.ultramic.2019.05.002.
[46] Jian, Dan, Wang, Bin, Huang, Huachuan, Meng, Xin, Liu, Cheng, Xue, Liang, Liu, Fei, Wang, Shouyu. Sunlight based handheld smartphone spectrometer. BIOSENSORS & BIOELECTRONICS[J]. 2019, 143: http://dx.doi.org/10.1016/j.bios.2019.111632.
[47] Hu, Junbao, Wei, Qi, Kong, Yan, Jiang, Zhilong, Xue, Liang, Liu, Fei, Kim, Dug Young, Liu, Cheng, Wang, Shouyu. Higher Order Transport of Intensity Equation Methods: Comparisons and Their Hybrid Application for Noise Adaptive Phase Imaging. IEEE PHOTONICS JOURNAL[J]. 2019, 11(3): https://doaj.org/article/85d792eadd7645ef9b2e05f9000a80cd.
[48] He, Xiaoliang, Tao, Hua, Zhang, Lijuan, Yuan, Xiaodong, Liu, Cheng, Zhu, Jiangiang. Single-Shot Optical Multiple-Image Encryption Based on Polarization-Resolved Diffractive Imaging. IEEE PHOTONICS JOURNAL[J]. 2019, 11(5): https://doaj.org/article/e1abd10cabc249178e77b80af5b6733c.
[49] 陶华, 潘兴臣, 刘诚, 王海燕, 姚玉东, 何小亮, 董学, 朱健强. 新型光场测量仪. 现代科学仪器. 2018, 12-17, http://lib.cqvip.com/Qikan/Article/Detail?id=675486576.
[50] 雷耀. 基于强度传输方程的激光损伤应力检测技术研究. 中国激光. 2018, 45(9): 256-262, http://lib.cqvip.com/Qikan/Article/Detail?id=676417841.
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[123] Pan, Xinchen, Liu, Cheng, Lin, Qiang, Zhu, Jianqiang. Ptycholographic iterative engine with self-positioned scanning illumination. OPTICS EXPRESS[J]. 2013, 21(5): 6162-6168, http://www.irgrid.ac.cn/handle/1471x/701955.
[124] Pan, Xingchen, Veetil, Suhas P, Liu, Cheng, Lin, Qiang, Zhu, Jianqiang. High-contrast imaging for weakly diffracting specimens in coherent diffraction imaging. CHINESE OPTICS LETTERS[J]. 2013, 11(2): http://www.irgrid.ac.cn/handle/1471x/701956.
[125] Liu Cheng, Pan XingChen, Zhu JianQiang. Coherent diffractive imaging based on the multiple beam illumination with cross grating. ACTA PHYSICA SINICA[J]. 2013, 62(18): https://www.webofscience.com/wos/woscc/full-record/WOS:000324907000027.
[126] Pan, Xingchen, Liu, Cheng, Zhu, Jianqiang. Single shot ptychographical iterative engine based on multi-beam illumination. APPLIED PHYSICS LETTERS[J]. 2013, 103(17): http://www.irgrid.ac.cn/handle/1471x/737752.
[127] Liu Cheng, Pan XingChen, Zhu JianQiang. Coherent diffractive imaging based on the multiple beam illumination with cross grating. ACTA PHYSICA SINICA[J]. 2013, 62(18): https://www.webofscience.com/wos/woscc/full-record/WOS:000324907000027.
[128] 潘兴臣, 林强, 刘诚, 朱健强. A Lens Assisted Phase Microscope Based on Ptychography. CHINESE PHYSICS LETTERS[J]. 2012, 29(8): 143-145, https://www.webofscience.com/wos/woscc/full-record/WOS:000307667100037.
[129] Pan, Xingchen, Veetil, Suhas P, Liu, Cheng, Zhu, Jianqiang. High contrast imaging for weakly diffracting specimens with ptychographical iterative engine. OPTICS LETTERS[J]. 2012, 37(16): 3348-3350, https://www.webofscience.com/wos/woscc/full-record/WOS:000307956700019.
[130] 潘兴臣, Veetil, Suhas P., 刘诚, 朱健强. High contrast imaging for weakly diffracting specimens with ptychographical iterative engine. Opt. lett.[J]. 2012, 37(16): 3348-3350, http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=PARTNER_APP&SrcAuth=LinksAMR&KeyUT=WOS:000307956700019&DestLinkType=FullRecord&DestApp=ALL_WOS&UsrCustomerID=3a85505900f77cc629623c3f2907beab.
[131] 潘兴臣, 林强, 刘诚, 朱健强. A Lens Assisted Phase Microscope Based on Ptychography. Chin. phys. lett.[J]. 2012, 29(8): 84216-, http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=PARTNER_APP&SrcAuth=LinksAMR&KeyUT=WOS:000307667100037&DestLinkType=FullRecord&DestApp=ALL_WOS&UsrCustomerID=3a85505900f77cc629623c3f2907beab.
[132] 刘诚. 样品厚度对PIE成像的影响. ultramicroscopy. 2009, [133] 刘诚, 金东永, 朱健强. 傅立叶分解法荧光层析成像. Chin. Opt. Lett.[J]. 2008, 6(9): 665-, http://lib.cqvip.com/Qikan/Article/Detail?id=28259774.
[134] 刘诚. 多功能数字全息显微镜. Optical Engineering. 2008, [135] 刘诚. Spatial Fourier Decomposition Fluorescence Microscopy. Chinese Optics Letters. 2008, [136] 刘诚. CRAS 显微镜的背景去除--高阶高斯光束激发. Optics Express. 2008, [137] Liu, Cheng, Kim, Dug Young, Zhu, Jianqiang. Spatial Fourier-decomposition optical fluorescence tomography-theoretical investigation. CHINESE OPTICS LETTERS[J]. 2008, 6(9): 665-668, http://lib.cqvip.com/Qikan/Article/Detail?id=28259774.
[138] 刘诚, Dug, Young, Kim, 朱健强. Spatial Fourier-decomposition optical fluorescence tomography-theoretical investigation. 中国光学快报:英文版. 2008, 6(9): 665-668, http://lib.cqvip.com/Qikan/Article/Detail?id=28259774.
[139] 刘诚. CARS显微镜的背景去除II--高斯光束探测. Optics Express. 2007, [140] 刘诚. 超强的纳米照明. Applied Physics Letters. 2006, [141] 刘诚. CARS显微镜的近场效应. 2006, [142] 刘诚. 负透镜表面倏逝波分析. Applied Physcs Letters. 2005, [143] 刘诚. 近场干涉的角度依赖性. Optics Express. 2005, [144] 刘诚. 固体浸润透镜的理论分析. Optics Letters. 2004, [145] 刘诚. 近场散斑的非对称性. Optics Letters. 2004, [146] 薄锋, 朱健强, 程笑天, 李银柱, 刘诚. 波片位相延迟的测量方法. 中国激光. 2003, 30(7): 651-654, http://lib.cqvip.com/Qikan/Article/Detail?id=8280844.
[147] 刘诚, 刘志刚, 程笑天, 薄峰, 王勇, 朱健强, 姜锦虎. 数字滤波法再现电子全息图. 光学学报. 2003, 23(2): 150-154, http://lib.cqvip.com/Qikan/Article/Detail?id=7439889.
[148] 汤更秀, 刘诚, 王国兴, 毛楚生, 朱健强. 大口径伺服的反射镜的十字簧板支承. 激光与光电子学进展[J]. 2003, 40(6): 45-, http://ir.siom.ac.cn/handle/181231/18306.
[149] 刘诚. 无直透光和共轭像的数字全息. 光学学报. 2002, 22(4): 427-431, http://lib.cqvip.com/Qikan/Article/Detail?id=6205896.
[150] 刘诚. 数字全息零级光去除. Optical Engineering. 2002, [151] 刘诚, 李良钰, 李银柱, 程笑天, 刘志刚, 薄锋, 朱健强. Measurement of Slopes of a Deformed Object Corresponding to Different Directions with Digital Holography. Chin. j. lasers b[J]. 2002, B11(6): 455-, http://ir.siom.ac.cn/handle/181231/17825.
[152] 李银柱, 戴亚平, 李良钰, 刘诚, 程笑天, 朱健强. 高功率激光装置中的三倍频Nd:YLF模拟激光系统. 中国激光. 2002, 29(2): 101-103, http://lib.cqvip.com/Qikan/Article/Detail?id=6062010.
[153] 李良钰, 王仕璠, 李银柱, 戴亚平, 刘诚, 程笑天, 朱健强. ICF瞄准定位系统的设计. 光子学报. 2002, 31(1): 107-109, http://lib.cqvip.com/Qikan/Article/Detail?id=5929170.
[154] Liu Cheng, Li Liangyu, Li Yinzhu, Liu Zhigang, Bo Feng, Zhu Jianqiang, Cheng Xiaotian. Measurement of Slopes of a Deformed Object Corresponding to Different Directions with Digital Holography. Chinese Journal of Lasers. B[J]. 2002, 11(6): 455-459, [155] 刘诚, 李良钰, 李银柱, 程笑天, 朱健强, 姜锦虎. 无直透光和共轭像的数学全息. 光学学报[J]. 2002, 22(4): 427-, http://ir.siom.ac.cn/handle/181231/17850.
[156] 刘诚. 数字全息的基本特性及其应用研究. 2002, http://ir.siom.ac.cn/handle/181231/15823.
[157] 朱健强, 刘诚. 数字全息形貌测量的基本特性分析. 强激光与粒子束. 2002, 14(3): 328-330, http://lib.cqvip.com/Qikan/Article/Detail?id=6381850.
[158] 刘诚, 李银柱, 戴亚平, 李良钰, 朱健强, 程笑天. 基于图像处理方法的导数场测量技术. 中国激光. 2001, 28(12): 1093-1095, http://lib.cqvip.com/Qikan/Article/Detail?id=5816346.

科研活动

   
科研项目
( 1 ) 非相干相位测量, 主持, 部委级, 2012-06--2015-06
( 2 ) 在线波前检测仪, 主持, 国家级, 2014-01--2016-12
( 3 ) 基于PIE的激光驱动器大口径光学元件检测技术研究, 主持, 国家级, 2017-01--2020-12
( 4 ) XXX基频、二倍频和三倍频复合光束的在线检测技术研究, 主持, 国家级, 2016-01--2021-06
( 5 ) 新型激光光束光场在线测量仪研制, 参与, 国家级, 2018-01--2022-12

指导学生

已指导学生

潘兴臣  硕士研究生  430103-光学工程  

程君  硕士研究生  080300-光学工程  

王海燕  博士研究生  080300-光学工程  

潘兴臣  博士研究生  080300-光学工程  

孙晓鹏  硕士研究生  085202-光学工程  

陶华  博士研究生  080300-光学工程  

蒋志龙  博士研究生  080300-光学工程  

陈文  硕士研究生  085202-光学工程  

白晔然  博士研究生  080300-光学工程  

何西  博士研究生  080300-光学工程  

渠勍  硕士研究生  085202-光学工程  

张雪丹  博士研究生  080300-光学工程  

董学  博士研究生  080300-光学工程  

何思源  硕士研究生  080300-光学工程  

程北  博士研究生  080300-光学工程  

现指导学生

昌成成  博士研究生  080300-光学工程  

张栋俊  博士研究生  080300-光学工程  

王港伟  硕士研究生  085202-光学工程  

齐乃杰  博士研究生  080300-光学工程  

王宏昌  博士研究生  080300-光学工程  

浦东  博士研究生  080300-光学工程