We present a high precision fiber roughness sensor based on annular core optical fiber (ACF). The ACF has a cone-frustum-shaped tip to enable the annular core to generate a focused ring light. When the incident light passing from the ACF is focused on the rough surface to be measured, the specular light will also be collected by using the ACF, which realizes the integration of the incident optical path and collecting optical path about optical roughness detection. Because the focused ring light has a smaller spot radius than that of the emergent light of a single-mode fiber, the proposed sensor has a higher spatial resolution. Moreover, the ACF with a cone-frustum tip can reduce the diffuse light coupling into the sensor; in this way, we improve the measurement precision. The experimental results show that for the surface roughness of 10 nanoscales, the error between the measured value and the theoretical value is about 5% and the spatial resolution reaches 6 µm. Thus, our sensor can be widely used in high precision nondestructive surface roughness measurements.
The development of a photonic device based on a non-diffracting surface plasmon polariton (SPP) beam can effectively improve the anti-interference ability. Furthermore, an easily adjustable on-chip routing device is highly desirable and extremely important in practical optical communication applications. However, no non-diffracting SPP-beam-based spin routing devices with high tunability in multiple degrees of freedom have been reported. In this study, we theoretically designed a simple micro-nano structure to realize a highly adjustable non-diffracting SPP-beam-based spin router using Finite-Difference Time-Domain (FDTD) simulation. The simulation results show that the structure enables spin-controlled nondiffracting SPP-beam directional launching. The launching direction of the nondiffracting SPP beam can be dynamically rotated counterclockwise or clockwise by changing the incident angle. Hence, the routing SPP beam can be coupled to different output waveguides to provide dynamic tunability. Moreover, this device shows good broadband response ability. This work may motivate the design and fabrication of future practical photon routing devices.
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