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Design method and application of a transmission-reflection gradient metasurface unit

A reflective gradient and design method technology, applied in the field of communication, can solve the problem of single function of the gradient plate, and achieve the effect of expanding the research scope and high efficiency

Inactive Publication Date: 2019-07-12
AIR FORCE UNIV PLA
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

[0004] Although researchers have conducted in-depth and extensive research on GMS, the research objects are only for transmission systems or reflection systems, and transmission-reflection integrated systems have never been reported. Traditional GMS has made great progress in improving beam steering capabilities and expanding the application of metamaterials. However, in the face of the current increasing beam control in the entire space, multi-functional requirements, and integration trends, traditional GMS still has many shortcomings: First, the high-efficiency principle of anisotropic metasurfaces under multiple polarization excitations has become an urgent need to solve Second, there are various beam manipulation methods, but the function of the gradient plate is relatively single. For example, GMS realizes the singular deflection effect, focusing, vortex light, etc., but there are few reports on the gradient plate integrating two or more functions at the same time; The third is that the beam control range is concentrated in 0-180°, and the beam control in the whole airspace has not been reported yet.

Method used

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  • Design method and application of a transmission-reflection gradient metasurface unit
  • Design method and application of a transmission-reflection gradient metasurface unit
  • Design method and application of a transmission-reflection gradient metasurface unit

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Embodiment 1

[0029] Embodiment 1 Transmission-reflection gradient metasurface unit design

[0030] For the design of TRGMS, the key factors to consider are three aspects. One is to realize the transmission and reflection characteristics at the same time, and the two cannot interact with each other to ensure the high efficiency of the system; the other is that no matter for the transmission system or the reflection system, the phase coverage must exceed 360° to ensure the arbitrary manipulation of the metasurface to the beam; The third is that the transmission and reflection coefficients need to be kept at a very high level to ensure the high efficiency of different functions. Considering the above three points, we designed the image 3 TRGMS unit. The unit is realized by a 4-layer orthogonal cascaded patch structure, and the unit period p=p=11mm, w 1 = 4mm, w 2 = 3mm, the dielectric board is an F4B dielectric board with a thickness of h=1.5mm, a dielectric constant of 2.65, and a metal...

Embodiment 2

[0031] Embodiment 2 Transmission-reflection beam deflector design

[0032] Based on the TRGMS unit designed above, different transmission-reflection functional devices with excellent performance can be designed. Here, the full-space transmission-reflection beam deflector is taken as an example to verify the powerful beam control capability of TRGMS. For the reflective system, the phase gradient is along the x direction, a superunit is composed of 6 basic units, and the phase gradient is -60°, taking two superunits as an example, Figure 4 (c) The amplitude and phase distribution of the reflection unit is given. The simulated (theoretical) reflection phase is in good agreement, and the reflection amplitude is better than 0.93; for the transmission system, the gradient is along the y direction, and the phase gradient is -60°. The cells are arranged along the x-direction, and the transmission phase and transmission amplitude are as Figure 4 As shown in (d), the simulated (theor...

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Abstract

The invention discloses a design method and an application of a transmission-reflection gradient meta-surface unit. The method comprises the following steps: the unit is designed in a four-layer orthogonal cascade patch structure; the cycle of the unit p=p=11mm, w1=4mm, and w2=3mm; an F4B dielectric plate of which the thickness (h) is 1.5mm and the dielectric constant is 2.65 is adopted; the thickness of a metal layer is 0.018mm; and the transmitted wave is controlled by a vertical patch. The characteristics of a designed transmission-reflection deflector are represented by near-field characteristics. Under x polarization excitation, beams undergo reflection singular deflection, an incidence field is cut, and there is only a response field. Under y polarization excitation, beams undergo transmission singular deflection, and the efficiency is high. For a TRGMS, both transmitted beams and reflected beams can be controlled, which cannot be realized by a GMS previously reported; and meanwhile, the research category of the GMS is expanded.

Description

technical field [0001] The invention belongs to the technical field of communication, and relates to a design method and application of a transmission-reflection gradient metasurface unit. Background technique [0002] The theoretical discovery of the generalized refraction / reflection law and the experimental verification of the gradient metasurface have opened up a new way and field for people to regulate electromagnetic waves, and are promoting deep technological innovation in this field. The so-called gradient metasurfaces (GradientMetasurfaces, GMS) are designed based on the idea of ​​phase mutation and polarization control, and are composed of artificial microstructure units, a two-dimensional new artificial structure surface that obeys the generalized Snell's law, and can flexibly excite and transmit electromagnetic waves. control. GMS has potential applications in stealth surfaces, conformal antennas, digital coding, lithography, etc., and has developed into a hot sp...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): H01Q15/23
CPCH01Q15/23
Inventor 梁建刚蔡通王光明李唐景许河秀庄亚强
Owner AIR FORCE UNIV PLA
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