Journal of Applied Optics, Volume. 43, Issue 4, 565(2022)
Progress and prospects in national defense optical metrology technology
Figures & Tables(21)
Fig. 1. Physical photo of calibration device of contrast distortion for visible light resolution transfer function
Fig. 2. Physical photo of calibration device for visible light image plane uniformity
Fig. 4. Physical photo of calibration device of terahertz source radiation parameters
Fig. 5. Physical photo of calibration device of linearity and wavelength of terahertz time-domain spectrometer
Fig. 6. Schematic diagram of transmittance-reflection ratio measuring device of micro-nano structure space
Fig. 7. Overall design diagram of tracking accuracy calibration device
Fig. 8. Physical photo of calibration device of missile system multi-spectral stealth
Fig. 9. Physical photo of calibration device of imaging seeker photoelectric detection equipment
Fig. 10. Physical photo of calibration device of multi-axial photoelectric system
Fig. 12. Measuring principle of laser polarization measuring instrument and its 3D model
Fig. 13. Physical photo of infrared materials emissivity measuring instrument
Fig. 14. Center deviation measuring instrument for dual-band optical elements
Fig. 15. Three-dimensional design diagram of TV imaging performance parameter measuring instrument
Fig. 16. Schematic diagram of infrared scanning radiometer composition
Fig. 17. Structure diagram of picowatt laser power and energy meter prototype
Fig. 18. Three-dimensional model of ultrashort laser pulse width tester
Fig. 19. Working principle diagram of UV visible light high-resolution image correction spectrometer
Table 1. Highest metrological standard indexes of national defense for laser parameter metrology major
View tableView in ArticleTable 1. Highest metrological standard indexes of national defense for laser parameter metrology major
标准名称 主要指标 激光小功率标准装置 0.1 mW~100 mW;Urel=1.5%(k = 2) 激光小能量标准装置 1×10−3 J~1 J;Urel=1.7%(k = 2) 激光能量标准装置 0.1 J~30 J;Urel=2.5%(k = 2) 激光中功率标准装置 1 W~100 W;Urel=2%(k = 2) 单脉冲激光峰值功率标准装置 峰值功率:1 W~50 MW;脉冲宽度:10 ns~100 ns 检定波长:1.06 μm, 10.6 μm;Urel=5%(1.06 μm),Urel=6%(10.6 μm) 重复脉冲激光峰值功率标准装置 峰值功率:0.1 μW~1 W;脉冲宽度:10 ns~100 ns 激光波长:0.91 μm,1.06 μm;Urel=5%
Table 2. Highest metrological standard indexes of national defense for spectral photometric chromaticity metrology major
View tableView in ArticleTable 2. Highest metrological standard indexes of national defense for spectral photometric chromaticity metrology major
标准名称 主要指标 光谱透射比标准 波长:200 nm~2 500 nm;透射比:0.01~1.00 测量不确定度:波长U=0.10 nm~0.30 nm(k=2) 透射比:Urel=0.5%(k=2)(可见) Urel=1.0%(k=2)(紫外、近红外) 光谱漫反射比标准 波长:250 nm~2 000 nm;反射比:0.01~1.00 测量不确定度:Urel=1.6%(k=2) 弱光度标准 测量范围:1×10−1 lx~1.2×10−7 lx 测量不确定度:Urel=2.5%(k=2),10−1 lx~10−3 lx Urel=3.5%(k=2),<10−3 lx~10−7 lx 光亮度标准 测量范围:2 cd/m2~1 000 cd/m2;Urel=1.4%(k=2) 发光强度标准 测量范围:1 cd~1 200 cd;Urel=1.0%(k=2) 光照度标准 测量范围:6 lx~3×103 lx;Urel=1.0%(k=2) 总光通量标准 总光通量范围:10 lm~4 000 lm;Urel=1.2%(k=2)
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Bing YU. Progress and prospects in national defense optical metrology technology[J]. Journal of Applied Optics, 2022, 43(4): 565
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Category: REVIEWS
Received: May. 30, 2022
Accepted: --
Published Online: Aug. 10, 2022
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