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Статті в журналах з теми "Digital laser"

Автор: Grafiati
Опубліковано: 12 квітня 2025

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1

Guang Zheng, B. Wang, T. Fang, H. Cheng, Y. Qi, Y. W. Wang, B. X. Yan, et al. "Laser Digital Cinema Projector." Journal of Display Technology 4, no. 3 (September 2008): 314–18. http://dx.doi.org/10.1109/jdt.2008.924163.

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2

Shimura, Mikihiko, Koichi Imanaka, Hiroshi Sekii, Akira Fujimoto, and Takeshi Takagi. "Semiconductor laser digital scanner." Optical Engineering 29, no. 3 (1990): 230. http://dx.doi.org/10.1117/12.55582.

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3

Ichioka, Y., T. Kobayashi, H. Kitagawa, and T. Suzuki. "Digital scanning laser microscope." Applied Optics 24, no. 5 (March 1, 1985): 691. http://dx.doi.org/10.1364/ao.24.000691.

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4

Piqué, Alberto, Heungsoo Kim, Ray Auyeung, Jiwen Wang, Andrew Birnbaum, and Scott Mathews. "Laser-Based Digital Microfabrication." NIP & Digital Fabrication Conference 25, no. 1 (January 1, 2009): 394–97. http://dx.doi.org/10.2352/issn.2169-4451.2009.25.1.art00108_1.

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5

Li, Qingfeng, David Grojo, Anne-Patricia Alloncle, Boris Chichkov, and Philippe Delaporte. "Digital laser micro- and nanoprinting." Nanophotonics 8, no. 1 (October 16, 2018): 27–44. http://dx.doi.org/10.1515/nanoph-2018-0103.

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Анотація:
AbstractLaser direct writing is a well-established ablation technology for high-resolution patterning of surfaces, and since the development of additive manufacturing, laser processes have also appeared very attractive for the digital fabrication of three-dimensional (3D) objects at the macro-scale, from few millimeters to meters. On the other hand, laser-induced forward transfer (LIFT) has demonstrated its ability to print a wide range of materials and to build functional micro-devices. For many years, the minimum size of laser-printed pixels was few tens of micrometers and is usually organized in two dimensions. Recently, new approaches have been investigated, and the potential of LIFT technology for printing 2D and 3D sub-micrometer structures has become real. After a brief description of the LIFT process, this review presents the pros and cons of the different digital laser printing technologies in the aim of the additive nanomanufacturing application. The transfer of micro- and nano-dots in the liquid phase from a solid donor film appears to be the most promising approach to reach the goal of 3D nanofabrication, and the latest achievements obtained with this method are presented and discussed.
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6

Huang, Cing-Yi, Kuo-Chih Chang, and Shu-Chun Chu. "Experimental Investigation of Generating Laser Beams of on-Demand Lateral Field Distribution from Digital Lasers." Materials 12, no. 14 (July 10, 2019): 2226. http://dx.doi.org/10.3390/ma12142226.

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Анотація:
A new type of laser system, known as a digital laser, was proposed in 2013. Many well-known laser beams with known analytical forms have been successfully generated in digital lasers. However, for a light field that does not have an analytical form, such as a multi-point light field or a light field with an arbitrary lateral distribution, how to generate such a light field from a digital laser has not been explored. The goal of this study was to experimentally explore how to generate an on-demand lateral laser field in a digital laser. In this study, a multi-point Gaussian laser beam was successfully generated in a digital laser by both controlling the range of the laser gain and the modulation of the phase boundary of the end of the cavity. This study then generated laser beams with an on-demand lateral field distribution by generating a superimposed multi-point laser field in a digital laser. Examples of triangles, rectangles, and letter T-shaped light fields produced by digital lasers were experimentally demonstrated. In summary, this study experimentally showed that a laser beam with an on-demand lateral field distribution could be generated in a digital laser by generating a superimposed multi-point laser field in a digital laser, in which a laser gain region covering the entire intra-cavity multi-point light field and the projected SLM (spatial light modulator) modulation function adopting a mimic amplitude mask are both used.
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7

Plesch, A., U. Klingbeil, and J. Bille. "Digital laser scanning fundus camera." Applied Optics 26, no. 8 (April 15, 1987): 1480. http://dx.doi.org/10.1364/ao.26.001480.

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8

Ngcobo, Sandile, Igor Litvin, Liesl Burger, and Andrew Forbes. "Demonstrating a Rewritable Digital Laser." Optics and Photonics News 24, no. 12 (December 1, 2013): 28. http://dx.doi.org/10.1364/opn.24.12.000028.

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9

Lang, Marion, Rudolf Neuhaus, and Jürgen Stuhler. "Digital Revolution in Laser Control." Optik & Photonik 10, no. 1 (February 2015): 38–41. http://dx.doi.org/10.1002/opph.201500005.

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10

Kowalik, John, John J. Rosinski, and Bradford R. Siepman. "Digital business telephones-project laser." Bell Labs Technical Journal 3, no. 1 (August 14, 2002): 122–33. http://dx.doi.org/10.1002/bltj.2097.

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11

Graf, Thomas. "The Laser Boosts Digital Manufacturing." PhotonicsViews 17, no. 3 (May 28, 2020): 1. http://dx.doi.org/10.1002/phvs.202070301.

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12

Huang, Xue Lin, and Wen Yan Jiang. "Research on Reproduction Characteristics of Digital Laser Plate." Advanced Materials Research 499 (April 2012): 293–97. http://dx.doi.org/10.4028/www.scientific.net/amr.499.293.

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Анотація:
Flexographic printing is growing at explosive rate now. With many kinds of plate has introduced, digital laser plate becomes mainstream technique. By experiment method, the microscopic of digital laser plate was analysis, the difference of platemaking process and printing results between digital laser plate and traditional plate was detail probed and the reproduction characteristics of digital laser plate were discusses. Results showed that digital laser plate brings smaller dot gains, broader color gamut and higher printing contrast; it greatly improved the quality of flexographic printing.
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13

Lee, Younggeun, Jinhyeong Kwon, Jaemook Lim, Wooseop Shin, Sewoong Park, Eunseung Hwang, Jaeho Shin, et al. "Digital Laser Micropainting: Digital Laser Micropainting for Reprogrammable Optoelectronic Applications (Adv. Funct. Mater. 1/2021)." Advanced Functional Materials 31, no. 1 (January 2021): 2170002. http://dx.doi.org/10.1002/adfm.202170002.

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14

Lin, Yuan-Yao. "Digital laser with composite resonator for optiocal vortex laser generation." EPJ Web of Conferences 307 (2024): 04020. http://dx.doi.org/10.1051/epjconf/202430704020.

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15

Zhiyuan Song, Zhiyuan Song, Li Feng Li Feng, Shaolan Zhu Shaolan Zhu, Haodong He Haodong He, Cunxiao Gao Cunxiao Gao, and Linquan Niu Linquan Niu. "All-digital pulse generator for gradually modulated semiconductor laser." Chinese Optics Letters 9, s1 (2011): s10306–310307. http://dx.doi.org/10.3788/col201109.s10306.

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16

Kanev, Kamen D., Petro V. Gnatyuk, and Volodymyr A. Gnatyuk. "Laser Marking in Digital Encoding of Surfaces." Advanced Materials Research 222 (April 2011): 78–81. http://dx.doi.org/10.4028/www.scientific.net/amr.222.78.

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Анотація:
In this work we consider some laser based methods and technologies for surface engraving and layered marking of opaque and transparent materials. Based on that, physical object surface and sub-surface layers can be enhanced with digital codes for augmented security and more advanced human-computer interactions. Laser procedures for creating digitally encoded layers in various materials are investigated and one of the mechanisms of laser-induced formation of marks (micro-cracks) in transparent materials is discussed in more details.
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17

Tsai, Zheng-Xian, Kuo-Chih Chang, and Shu-Chun Chu. "Pattern control of a Q-switched pulsed laser with a dual-cavity configuration digital laser." Chinese Optics Letters 23, no. 1 (2025): 011404. https://doi.org/10.3788/col202523.011404.

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18

Nancarrow, Jane-Heloise. "Countering the "Digital Uncanny"." Studies in Digital Heritage 3, no. 2 (June 13, 2020): 170–85. http://dx.doi.org/10.14434/sdh.v3i2.27748.

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Анотація:
Photogrammetry and laser scanning, or combinations of the two, are increasingly used in cultural heritage settings to create three-dimensional digital replicas. Yet the technical production processes involved can sometimes result in undesirable outcomes – flattening shadows, light, and surface textural variations of original artifacts. Many of these important visual cues contribute to our understanding of digital models as ‘historical objects,’ and the resulting overly digitized photogrammetry – lacking visual context and depth – can impede user interactivity. Viewers of digital heritage can become deterred by the uncanny, static, or unreal aesthetic of some photogrammetric and laser scans. This article considers two digital heritage projects: “Emotions3D: Bringing Digital Heritage to Life,”and the Smithsonian Apollo 11 Command Module scans in order to explore how technical and curatorial decisions can address issues in photogrammetric and laser post-processing. While often subtle, different post-processing choices are perceived and deeply cognitively and emotionally internalized by viewers and users of digital cultural heritage. Therefore, this paper assesses the relevance of emotions studies, theories of the ‘uncanny’ and the ‘uncanny valley,’ and issues of authenticity and best-practice digital interventions to enhance user engagement and accessibility through digital post-processing techniques.
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19

Murzin, Serguei P. "Digital Engineering in Photonics: Optimizing Laser Processing." Photonics 11, no. 10 (October 4, 2024): 935. http://dx.doi.org/10.3390/photonics11100935.

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Анотація:
This article explores the transformative impact of digital engineering on photonic technologies, emphasizing advancements in laser processing through digital models, artificial intelligence (AI), and freeform optics. It presents a comprehensive review of how these technologies enhance efficiency, precision, and control in manufacturing processes. Digital models are pivotal for predicting and optimizing thermal effects in laser processing, thereby reducing material deformation and defects. The integration of AI further refines these models, improving productivity and quality in applications such as micromachining and cladding. Additionally, the combination of AI with freeform optics advances laser technology by enabling real-time adjustments and customizable beam profiles, which enhance processing versatility and reduce material damage. The use of digital twins is also examined as a key development in laser-based manufacturing, offering significant improvements in process optimization, defect reduction, and system efficiency. By incorporating real-time monitoring, machine learning, and physics-based modeling, digital twins facilitate precise simulations and predictions, leading to more effective and reliable manufacturing practices. Overall, the integration of digital twins, AI, and freeform optics into laser processing marks a significant progression in manufacturing technology. These advancements collectively enhance precision, efficiency, and adaptability, resulting in improved product quality and reduced operational costs. The continued evolution of these technologies is expected to drive further advancements in manufacturing practices, offering more robust solutions for complex production environments.
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20

AHRENS, Wilhelm H. "Application of Laser to Digital Printing. Digital Plate Making System." Review of Laser Engineering 25, no. 9 (1997): 639–42. http://dx.doi.org/10.2184/lsj.25.639.

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21

KITAMURA, Takashi. "Application of Laser to Digital Printing." Review of Laser Engineering 25, no. 9 (1997): 621–24. http://dx.doi.org/10.2184/lsj.25.621.

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22

Piqué, Alberlto. "Digital Microfabrication by Laser Decal Transfer." Journal of Laser Micro/Nanoengineering 3, no. 3 (December 2008): 163–69. http://dx.doi.org/10.2961/jlmn.2008.03.0007.

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23

Lohr, U. "Digital Elevation Models By Laser Scanning." Photogrammetric Record 16, no. 91 (April 1998): 105–9. http://dx.doi.org/10.1111/0031-868x.00117.

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24

Colbourne, Paul. "Digital laser microinterferometer and its applications." Optical Engineering 42, no. 5 (May 1, 2003): 1417. http://dx.doi.org/10.1117/1.1564103.

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25

Akiwowo, Kerri, Faith Kane, John Tyrer, George Weaver, and Andrew Filarowski. "Digital Laser-dyeing for Polyester Fabrics." Journal of Textile Design Research and Practice 2, no. 2 (November 2014): 133–51. http://dx.doi.org/10.2752/205117814x14228978833457.

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26

HUERTER, CHRISTOPHER J., RONALD G. WHEELAND, PHILIP L. BAILIN, and JOHN LOUIS RATZ. "Lasers: Treatment of Digital Myxoid Cysts with Carbon Dioxide Laser Vaporization." Journal of Dermatologic Surgery and Oncology 13, no. 7 (July 1987): 723–27. http://dx.doi.org/10.1111/j.1524-4725.1987.tb00541.x.

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27

Fidder, Herman, Joris P. J. Admiraal, Václav Ocelík, and Jeff Th M. De Hosson. "In Situ Digital Image Correlation Observations of Laser Forming." Metals 10, no. 1 (December 21, 2019): 17. http://dx.doi.org/10.3390/met10010017.

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Анотація:
In this study experimental and modelling methods are used to examine the microstructural and bending responses of laser-formed commercially pure titanium grade 2. The in situ bending angle response is measured for different processing parameters utilizing 3D digital image correlation. The microstructural changes are observed using electron backscatter diffraction. Finite element modelling is used to analyse the heat transfer and temperature field inside the material. It has been proven that the laser bending process is not only controlled by processing parameters such as laser power and laser beam scanning speed, but also by surface absorption. Grain size appears to have no influence on the final bending angle, however, sandblasted samples showed a considerably higher final bending angle. Experimental and simulation results suggest that the laser power has a larger influence on the final bending angle than that of the laser transverse speed. The microstructure of the laser heat-affected zone consists of small refined grains at the top layer followed by large elongated grains. Deformation mechanisms such as slip and twinning were observed in the heat-affected zone, where their distribution depends on particular processing parameters.
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28

Li, Jin Hua, De Qiang Zhang, Zhi Chao Su, and Fang Ping Yao. "The Research of Moulds Digital Repairing Based on Laser Cladding." Advanced Materials Research 860-863 (December 2013): 2678–81. http://dx.doi.org/10.4028/www.scientific.net/amr.860-863.2678.

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Анотація:
The technology was put forward on mould broken areas 3D digital remanufacturing. Based on CAD and laser cladding, it is finished including 3D repairing-trajectory modeling, editing manufacturing program and laser cladding processing. The pre-processing tasks are the experiment of laser cladding parameter, the broken areas pretreatment and measurement, and the repairing task is finished by machining after laser cladding.
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29

Yokoyama, H., and H. Chikatsu. "AUTOMATIC TREE DATA REMOVAL METHOD FOR TOPOGRAPHY MEASUREMENT RESULT USING TERRESTRIAL LASER SCANNER." ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XLII-2/W3 (February 23, 2017): 659–64. http://dx.doi.org/10.5194/isprs-archives-xlii-2-w3-659-2017.

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Анотація:
Recently, laser scanning has been receiving greater attention as a useful tool for real-time 3D data acquisition, and various applications such as city modelling, DTM generation and 3D modelling of cultural heritage sites have been proposed. And, former digital data processing were demanded in the past digital archive techniques for cultural heritage sites. However, robust filtering method for distinguishing on- and off-terrain points by terrestrial laser scanner still have many issues. In the past investigation, former digital data processing using air-bone laser scanner were reported. Though, efficient tree removal methods from terrain points for the cultural heritage are not considered. In this paper, authors describe a new robust filtering method for cultural heritage using terrestrial laser scanner with "the echo digital processing technology" as latest data processing techniques of terrestrial laser scanner.
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30

Murzin, Serguei P. "Digital Engineering in Diffractive Optics for Precision Laser Processing." Photonics 12, no. 4 (March 27, 2025): 306. https://doi.org/10.3390/photonics12040306.

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Анотація:
This article focuses on the application of digital engineering in diffractive optics for precision laser material processing. It examines methods for the development of diffractive optical elements (DOEs) and adaptive management approaches that enhance the accuracy and efficiency of laser processing. Key achievements are highlighted in numerical modeling, machine learning applications, and geometry optimization of optical systems, along with the integration of dynamic DOEs with laser systems for adaptive beam control. The discussion includes the development of complex diffractive structures with improved characteristics and new optimization approaches. Special attention is given to the application of DOEs in micro- and nanostructuring, additive manufacturing technologies, and their integration into high-performance laser systems. Additionally, challenges related to the thermal stability of materials and the complexity of adaptive DOE control are explored, as well as the role of artificial intelligence in enhancing laser processing efficiency.
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31

Nguyen Thi, Ly Ly, Ko-Fan Tsai, and Shu-Chun Chu. "Generating Optical Vortex Array Laser Beams of Superimposing Hermite–Gaussian Beams with a Dual–Phase Modulation Digital Laser System." Photonics 11, no. 6 (June 15, 2024): 563. http://dx.doi.org/10.3390/photonics11060563.

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Анотація:
This study presents an efficient and practical intra-cavity approach for selectively generating vortex array laser beams employing a dual-phase modulation digital laser system, which has not yet been completed in single-phase modulation digital laser. The stable optical vortex array laser beams were formed by superimposing cavity Hermite–Gaussian (HG) eigenmodes. In particular, when the selected cavity HG modes shared the same Gouy phase, the resulting optical vortex beam could preserve its light field pattern, thereby maintaining the optical vortex properties in the near and far fields. Numerical results demonstrated that employing dual-phase modulation could establish optimal boundary conditions for the selection of HG modes within the cavity, successfully generating various vortex array laser beams. The experimental validation of the proposed method confirmed the ability to select optical vortex array lasers solely by controlling the loaded phase of the dual-phase modulation digital laser. These results demonstrate the ability of digital lasers to generate and dynamically control optical vortex array lasers.
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32

Gao, X., M. Li, L. Xing, and Y. Liu. "JOINT CALIBRATION OF 3D LASER SCANNER AND DIGITAL CAMERA BASED ON DLT ALGORITHM." ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XLII-3 (April 30, 2018): 377–80. http://dx.doi.org/10.5194/isprs-archives-xlii-3-377-2018.

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Анотація:
Design a calibration target that can be scanned by 3D laser scanner while shot by digital camera, achieving point cloud and photos of a same target. A method to joint calibrate 3D laser scanner and digital camera based on Direct Linear Transformation algorithm was proposed. This method adds a distortion model of digital camera to traditional DLT algorithm, after repeating iteration, it can solve the inner and external position element of the camera as well as the joint calibration of 3D laser scanner and digital camera. It comes to prove that this method is reliable.
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33

Luo, Yingxin, Hongyin Li, and Hsien-Chi Yeh. "Note: Digital laser frequency auto-locking for inter-satellite laser ranging." Review of Scientific Instruments 87, no. 5 (May 2016): 056105. http://dx.doi.org/10.1063/1.4950862.

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34

Bura, M., J. Janowski, P. Wężyk, and K. Zięba. "THE DIGITAL VON FAHRENHEID PYRAMID." ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XLII-2/W5 (August 18, 2017): 105–11. http://dx.doi.org/10.5194/isprs-archives-xlii-2-w5-105-2017.

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Анотація:
3D Scanners Lab from Digital Humanities Laboratory at the University of Warsaw initiated the scientific project, the purpose of which was to call attention to systematically penetrated and devastated pyramid-shaped tomb from the XVIII/XIX century, of family von Fahrenheid in Rapa in Banie Mazurskie commune (NE Poland). By conducting a series of non-invasive studies, such as 3D inventory using terrestrial laser scanning (TLS), thermal imaging, georadar measurements (around and inside the tomb) and anthropological research of mummified remains as well - the complete dataset was collected. Through the integration of terrestrial (TLS) and airborne laser scanning (ALS) authors managed to analyse the surroundings of Fahrenheid pyriamid and influence of some objects (like trees) on the condition and visibility of the Pyramids in the landscape.
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35

Barnowski, Daniel, Martin Dahmen, Tamás Farkas, Dirk Petring, Ulrich Petschke, Marcel Pootz, Ralf Schäl, and Stoyan Stoyanov. "Multifunctional laser processing with a digital twin." Procedia CIRP 111 (2022): 822–26. http://dx.doi.org/10.1016/j.procir.2022.08.091.

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36

Kaleris, Konstantinos, Bjoern Stelzner, Panagiotis Hatziantoniou, Dimosthenis Trimis та John Mourjopoulos. "Laser-Sound Transduction From Digital ΣΔ Streams". Journal of the Audio Engineering Society 70, № 1/2 (26 січня 2021): 50–61. http://dx.doi.org/10.17743/jaes.2021.0053.

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37

Silverstein, Barry D., Andrew F. Kurtz, Joseph R. Bietry, and Gary E. Nothhard. "25.4: A Laser-Based Digital Cinema Projector." SID Symposium Digest of Technical Papers 42, no. 1 (June 2011): 326–29. http://dx.doi.org/10.1889/1.3621311.

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38

Chirkin, M. V., A. V. Molchanov, V. V. Klimakov, V. Yu Mishin, A. E. Serebryakov, and G. V. Davydov. "LASER GYROSCOPE MECHANICAL DITHER DIGITAL CONTROL SYSTEM." Vestnik of Ryazan State Radio Engineering University 72 (2020): 3–12. http://dx.doi.org/10.21667/1995-4565-2020-72-3-12.

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39

Shi, Bing-Chuan, Xiao-Lei Wang, Wen-Gang Guo, and Li-Pei Song. "Characteristic of femtosecond laser pulsed digital holography." Chinese Physics B 24, no. 8 (August 2015): 084202. http://dx.doi.org/10.1088/1674-1056/24/8/084202.

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40

Burt, James D., Mark Siddins, and Wayne A. Morrison. "Laser Photoirradiation in Digital Flexor Tendon Repair." Plastic and Reconstructive Surgery 108, no. 3 (September 2001): 688–94. http://dx.doi.org/10.1097/00006534-200109010-00013.

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41

Kuehne, Alexander J. C., Malte C. Gather, Irwin A. Eydelnant, Seok-Hyun Yun, David A. Weitz, and Aaron R. Wheeler. "A switchable digital microfluidic droplet dye-laser." Lab on a Chip 11, no. 21 (2011): 3716. http://dx.doi.org/10.1039/c1lc20405j.

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42

HIRAOKA, Toru, Tatsuro OCHI, and Yusuke ISOBE. "Digital Watermarking for Airborne Laser Scanner Data." Journal of the Japan society of photogrammetry and remote sensing 50, no. 5 (2011): 290–95. http://dx.doi.org/10.4287/jsprs.50.290.

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43

Taylor, Geoff W., and Heath Opper. "A New Digital OptoElectronic Switch (DOES) Laser." IEEE Journal of Quantum Electronics 53, no. 3 (June 2017): 1–10. http://dx.doi.org/10.1109/jqe.2017.2682699.

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Keller, P. J., and E. H. K. Stelzer. "Digital Scanned Laser Light Sheet Fluorescence Microscopy." Cold Spring Harbor Protocols 2010, no. 5 (May 1, 2010): pdb.top78. http://dx.doi.org/10.1101/pdb.top78.

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Horchani, R. "Femtosecond laser shaping with digital light processing." Optical and Quantum Electronics 47, no. 8 (May 26, 2015): 3023–30. http://dx.doi.org/10.1007/s11082-015-0188-0.

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Levi, A. F. J., R. N. Nottenburg, R. A. Nordin, T. Tanbun‐Ek, and R. A. Logan. "Multielectrode quantum well laser for digital switching." Applied Physics Letters 56, no. 12 (March 19, 1990): 1095–97. http://dx.doi.org/10.1063/1.102578.

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Chekurov, Sergei, and Tapio Lantela. "Selective Laser Melted Digital Hydraulic Valve System." 3D Printing and Additive Manufacturing 4, no. 4 (December 2017): 215–21. http://dx.doi.org/10.1089/3dp.2017.0014.

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Calloni, E., A. Brillet, C. N. Man, F. Barone, F. Fusco, R. DeRosa, L. DiFiore, A. Grado, L. Milano, and G. Russo. "Digital alignment system for a laser beam." Physics Letters A 193, no. 1 (September 1994): 15–20. http://dx.doi.org/10.1016/0375-9601(94)00598-2.

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Lee, Younggeun, Jinhyeong Kwon, Jaemook Lim, Wooseop Shin, Sewoong Park, Eunseung Hwang, Jaeho Shin, et al. "Digital Laser Micropainting for Reprogrammable Optoelectronic Applications." Advanced Functional Materials 31, no. 1 (September 28, 2020): 2006854. http://dx.doi.org/10.1002/adfm.202006854.

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Jo, Y. H., and J. Y. Kim. "THREE-DIMENSIONAL DIGITAL DOCUMENTATION OF HERITAGE SITES USING TERRESTRIAL LASER SCANNING AND UNMANNED AERIAL VEHICLE PHOTOGRAMMETRY." ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XLII-2/W5 (August 18, 2017): 395–98. http://dx.doi.org/10.5194/isprs-archives-xlii-2-w5-395-2017.

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Анотація:
Three-dimensional digital documentation is an important technique for the maintenance and monitoring of cultural heritage sites. This study focuses on the three-dimensional digital documentation of the Magoksa Temple, Republic of Korea, using a combination of terrestrial laser scanning and unmanned aerial vehicle (UAV) photogrammetry. Terrestrial laser scanning mostly acquired the vertical geometry of the buildings. In addition, the digital orthoimage produced by UAV photogrammetry had higher horizontal data acquisition rate than that produced by terrestrial laser scanning. Thus, the scanning and UAV photogrammetry were merged by matching 20 corresponding points and an absolute coordinate system was established using seven ground control points. The final, complete threedimensional shape had perfect horizontal and vertical geometries. This study demonstrates the potential of integrating terrestrial laser scanning and UAV photogrammetry for three-dimensional digital documentation. This new technique is expected to contribute to the three-dimensional digital documentation and spatial analysis of cultural heritage sites.
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