28 research outputs found

    Orbital angular momentum mode-demultiplexing scheme with partial angular receiving aperture

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    For long distance orbital angular momentum (OAM) based transmission, the conventional whole beam receiving scheme encounters the difficulty of large aperture due to the divergence of OAM beams. We propose a novel partial receiving scheme, using a restricted angular aperture to receive and demultiplex multi-OAM-mode beams. The scheme is theoretically analyzed to show that a regularly spaced OAM mode set remain orthogonal and therefore can be de-multiplexed. Experiments have been carried out to verify the feasibility. This partial receiving scheme can serve as an effective method with both space and cost savings for the OAM communications. It is applicable to both free space OAM optical communications and radio frequency (RF) OAM communications

    Simultaneous Measurement of Pressure and Temperature Using a Single Fiber Bragg Grating

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    Abstract A novel sensor based on a single fiber Bragg grating is described. The sensor is configured by encapsulating half of a fiber Bragg grating in a polymer filled metal cylinder and fixing the other half to the metal cylinder. The results show that this sensor is able to measure pressure and temperature simultaneously. Using a novel tactic to transfer the applied pressure to the axial extended-strain on the fiber Bragg grating, the pressure sensitivity reaches 9.65×10 −3 MPa −1 , which is about 4700 times larger than that of the bare fiber Bragg grating. The accuracy of the pressure measuring can also be improved through introducing a fixed Bragg wavelength as a reference

    Reconfigurable Mode Vortex Beam Generation Based on Transmissive Metasurfaces in the Terahertz Band

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    Combining Terahertz (THz) and Orbital Angular Momentum (OAM) technologies has great potential in high-speed wireless communication. Theoretically, OAM with different modes has strict orthogonality. The communication capacity of the system will improve significantly if OAM technology is applied to the THz communication system. Thus, the manner to generate a high-quality and dynamically controllable THz-OAM beam has been of significant interest to researchers in related fields. In this study, a double-layer transmissive metasurface that uses 3D printing as the processing method with a low cost and processing difficulty is designed. Note that the height of the unit cell for constructing the metasurface is configurable. As the height changes continuously, the phase of the transmitted wave covers 0~2\begin{document}π{\pi }\end{document} within 90~110 GHz, while the transmittance of the units is always higher than 88%. At 100 GHz, which is fed by a WR-10 standard waveguide horn antenna, OAM beams with different modes are generated by changing the relative rotation angle between the double-layer metasurface. The simulation results show that the metasurface antenna designed in this study can achieve OAM beams of \begin{document}l=1,2,3 l=1, \mathrm{2,3} \end{document}, and the two-dimensional amplitude and phase results correspond with the characteristics of the corresponding modes. When \begin{document}l=1, 2, 3 l=1,\mathrm{ }2,\mathrm{ }3 \end{document}, the OAM beam’s modal purity is 85.4%, 84.9%, and 83.4%, respectively. The measurement results include the results at frequency points of 90, 100, and 110 GHz. The results show that the OAM beam has a high-quality bandwidth of 20 GHz, which indicates that the metasurface antenna designed in this study has a wide working bandwidth at a high frequency and can be applied to high-frequency OAM communication

    Performance Analysis of Plane Spiral OAM Mode-Group Based MIMO System

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    Analyses of Whispering Gallery Modes in Circular Resonators by Transmission Line Theory

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    A novel frequency-doubling Brillouin optoelectronic oscillator

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    An optically tunable frequency-doubling Brillouin optoelectronic-oscillator using a dual-electrode Mach-Zehnder modulator (DEMZM) is presented. To achieve frequency-doubling, the DEMZM is biased at the maximum transmission point and only one of its electrodes is driven by the oscillation signal, whose frequency is determined by the stimulated Brillouin scattering effect in a high nonlinear dispersion-shifted fiber. Frequency tunability is obtained by utilizing the wavelength-dependent Brillouin frequency shift. Frequency-doubling microwave signals from 18.38 to 18.74 GHz with large suppression of the fundamental frequency component are generated. The proposed approach features low cost and simple in structure
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