The Frontiers of Society, Science and Technology, 2023, 5(10); doi: 10.25236/FSST.2023.051009.
Zixuan Wang, Haoyang Li, Fengyuan Yan
Shandong University of Science and Technology, Jinan, 250031, China
The "Cheetah" photography glasses are small-sized high-speed photography equipment for use in the field of communication engineering. It employs high-speed photography technology and synchronous data transmission technology to capture target images in real-time through high-speed cameras and transmit them wirelessly using radio energy transmission technology. Meanwhile, under the IEEE1588 PTP precision time protocol, clock signals are transmitted in the form of network packets, achieving high-precision clock synchronization between different terminal devices. After the event ends, the glasses can also be used to replace traditional bulky and inconvenient-to-carry high-speed cameras by utilizing signal processing technology and digital analog technology for fine processing. Moreover, the "Cheetah" photography glasses fully leverage the scalability and adaptability of software, constantly adding new modules and functions to better suit the needs of different consumers.
Communication Engineering, Clock Synchronization, Signal Processing Technology, Digital Analog Technology
Zixuan Wang, Haoyang Li, Fengyuan Yan. Transformation of High-speed Photography in Communication Engineering through the "Cheetah" Photography Glasses. The Frontiers of Society, Science and Technology (2023) Vol. 5, Issue 10: 58-67. https://doi.org/10.25236/FSST.2023.051009.
[1] Kumar A, Sharma S K, Sharma G, et al. Silicate glass matrix@ Cu2O/Cu2V2O7 pn heterojunction for enhanced visible light photo-degradation of sulfamethoxazole: High charge separation and interfacial transfer. Journal of Hazardous Materials, 2021, 402: 123790.
[2] Odinokov S B, Shishova M V, Markin V V, et al. Augmented reality display based on photo-thermo-refractive glass planar waveguide. Optics Express, 2020, 28(12): 17581-17594.
[3] Xia M, Luo J, Chen C, et al. Semiconductor quantum dots‐embedded inorganic glasses: fabrication, luminescent properties, and potential applications. Advanced Optical Materials, 2019, 7(21): 1900851.
[4] Chen Z, Qi Y, Chen X, et al. Direct CVD growth of graphene on traditional glass: methods and mechanisms. Advanced Materials, 2019, 31(9): 1803639.
[5] Hernandez C, Cedeno E, Rojas T, et al. A comparison between thermal lens and conventional optical spectroscopy for monitoring of a photo catalytic process. Revista Mexicana de Fisica, 2022, 68(2): 1-7.
[6] Lin S, Wang H, Zhang X, et al. Direct spray-coating of highly robust and transparent Ag nanowires for energy saving windows. Nano Energy, 2019, 62: 111-116.
[7] Xiang X, Lin H, Xu J, et al. CsPb (Br, I) 3 embedded glass: Fabrication, tunable luminescence, improved stability and wide-color gamut LCD application. Chemical Engineering Journal, 2019, 378: 122255.
[8] Kaky K M, Sayyed M I, Mhareb M H A, et al. Physical, structural, optical and gamma radiation attenuation properties of germanate-tellurite glasses for shielding applications. Journal of Non-Crystalline Solids, 2020, 545: 120250.
[9] Tan D, Wang Z, Xu B, et al. Photonic circuits written by femtosecond laser in glass: improved fabrication and recent progress in photonic devices. Advanced Photonics, 2021, 3(2): 024002-024002.
[10] Rammah Y S, Kilic G, El-Mallawany R, et al. Investigation of optical, physical, and gamma-ray shielding features of novel vanadyl boro-phosphate glasses. Journal of Non-Crystalline Solids, 2020, 533: 119905.
[11] Liu Y, Zhang Z, Fang Y, et al. IR-Driven strong plasmonic-coupling on Ag nanorices/W18O49 nanowires heterostructures for photo/thermal synergistic enhancement of H2 evolution from ammonia borane. Applied Catalysis B: Environmental, 2019, 252: 164-173.
[12] Zhang K, Huang S, Wang J, et al. Transparent omniphobic coating with glass‐like wear resistance and polymer‐like bendability. Angewandte Chemie, 2019, 131(35): 12132-12137.
[13] Uosif M A M, Mostafa A M A, Issa S A M, et al. Structural, mechanical and radiation shielding properties of newly developed tungsten lithium borate glasses: an experimental study. Journal of Non-Crystalline Solids, 2020, 532: 119882.
[14] Al-Buriahi M S, Abouhaswa A S, Tekin H O, et al. Structure, optical, gamma-ray and neutron shielding properties of NiO doped B2O3–BaCO3–Li2O3 glass systems. Ceramics International, 2020, 46(2): 1711-1721.
[15] Zhang L, Pan J, Zhang Z, et al. Ultrasensitive skin-like wearable optical sensors based on glass micro/nanofibers. Opto-Electronic Advances, 2020, 3(3): 190022-1-190022-7.