Research on the Coupled Modulation Transfer Function of the Discrete Sampling System with Hexagonal Fiber-Optic Imaging Bundles
Abstract
:1. Introduction
2. Theory and Derivation
2.1. Image Transmission Mechanism of Hexagonally Aligned Fiber-Optic Imaging Bundles
2.2. Selection of CCD Image Elements and Sampling Direction
- Fiber-optic imaging bundles are manufactured using multi-component glass fiber, and unlike communication fiber, multi-component glass fiber has a large light im-aging area. In practice, the thickness of the single fiber cladding of the optical fiber bundle is controlled to be approximately 1/10 of the diameter of the fiber. In general, the light imaging area of various types of imaging bundles accounts for 60~90% of the total area of the image bundle. The attenuation of the 1000 m communication fiber at a wavelength of 1300 nm is approximately 1 dB, while the attenuation of image transmission of the multi-component glass fibers in the broad spectrum (400 nm~800 nm) beam is approximately 1 dB/m, and for a few tens of millimeters of the hexagonal fiber imaging bundle, the attenuation is much smaller than 1 dB, which is negligible;
- The multi-component glass fiber introduces a glass cladding structure that substantially reduces the severe crosstalk effect between adjacent fibers. Light-absorbing materials are introduced into the structure of the optical fiber imaging element to attenuate the inter-fiber crosstalk and absorb stray light. In this study, it was assumed that there was no crosstalk between fibers and that each monofilament fiber transmitted image information independently and efficiently;
- Broken filaments are undesirable, but likely to exist in fiber-optic bundles. A broken filament will block the path of a single filament, produce a black spot in the field of view, and even lose the target image information. If two or more adjacent fibers break to form a group of broken filaments, it causes even more distortion. In the actual process of fiber-optic beam production, the breakage rate should be <0.3‰ (small cross-sectional bundle) ~0.8‰ (large cross-sectional bundle), and the group breakage is restricted from appearing in the center of the beam;
- Since both the imaging objective lens and the coupling objective lens shown in Figure 2 are conventional optics, the modulation transfer function of each field of view is assumed to be constant. Since the magnification error of the coupling objective may lead to image element scaling and introduce other coupling errors, the magnification of the coupling objective needs to be precisely adjusted and calibrated during the actual setup process to ensure the dimensional coupling between the fiber-optic imaging bundle and the CCD.
2.3. Numerical Modeling of the Coupled-MTF
3. Simulation and Discussion
3.1. Effect of Number of Fibers on the Coupled-MTF
3.2. Effect of Nyquist Frequency Shift on the Coupled-MTF
3.3. Effect of Initial Position Deviation on the Coupled-MTF
4. Conclusions
Author Contributions
Funding
Conflicts of Interest
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Li, W.; Han, C.; Wu, C.; Huang, Y.; Zhang, H. Research on the Coupled Modulation Transfer Function of the Discrete Sampling System with Hexagonal Fiber-Optic Imaging Bundles. Appl. Sci. 2022, 12, 3135. https://doi.org/10.3390/app12063135
Li W, Han C, Wu C, Huang Y, Zhang H. Research on the Coupled Modulation Transfer Function of the Discrete Sampling System with Hexagonal Fiber-Optic Imaging Bundles. Applied Sciences. 2022; 12(6):3135. https://doi.org/10.3390/app12063135
Chicago/Turabian StyleLi, Wenxian, Chengshan Han, Congjun Wu, Yawei Huang, and Hang Zhang. 2022. "Research on the Coupled Modulation Transfer Function of the Discrete Sampling System with Hexagonal Fiber-Optic Imaging Bundles" Applied Sciences 12, no. 6: 3135. https://doi.org/10.3390/app12063135
APA StyleLi, W., Han, C., Wu, C., Huang, Y., & Zhang, H. (2022). Research on the Coupled Modulation Transfer Function of the Discrete Sampling System with Hexagonal Fiber-Optic Imaging Bundles. Applied Sciences, 12(6), 3135. https://doi.org/10.3390/app12063135