Mayank A. Ardeshana , Falgunkumar N. Thakkar , Sunayana G. Domadia
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This configuration attains negative permittivity and permeability suitable for operational frequencies in the L-band and S-band. The study examines the electric field, impedance, and surface current to provide additional evidence for the absorption analysis. A validated RLC circuit equivalent to the proposed structure has been confirmed using Advanced Design System (ADS). The results indicate a slight deviation, especially at frequencies beyond the resonance frequencies. The structure underwent fabrication and testing in an anechoic chamber, revealing a strong correlation between the simulated and measured results. 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The results indicate a slight deviation, especially at frequencies beyond the resonance frequencies. The structure underwent fabrication and testing in an anechoic chamber, revealing a strong correlation between the simulated and measured results. 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引用次数: 0
摘要
这项研究介绍了一种三波段超材料吸收器,其特点是对偏振和入射角都不敏感。该结构包括上侧的方形环状谐振器和下侧的连续金属接地,并由 FR4 基板隔开。在最低工作频率下,单元尺寸的厚度和长度分别为 0.0128λ 和 0.156λ。在正常入射条件下,所提出的吸收器在 1.56、2.43 和 3.36 GHz 处显示出三个明显的吸收峰,吸收率分别达到 98%、99% 和 97%。由于其高度对称性,吸收响应随入射角度的变化而变化,在 TM 和 TE 极化下最高可达 70°。这种结构可获得适合 L 波段和 S 波段工作频率的负介电常数和负导磁率。研究对电场、阻抗和表面电流进行了检测,为吸收分析提供了更多证据。使用高级设计系统 (ADS) 确认了与拟议结构等效的 RLC 电路。结果表明存在轻微偏差,尤其是在超出共振频率的频率上。该结构在电波暗室中进行了制造和测试,结果显示模拟和测量结果之间具有很强的相关性。建议的吸收器有望用于 ISM 应用、雷达系统、传感技术和能量收集系统。
Robust Multi-Band DNG metamaterial absorber for GPS (L1), ISM, and 5G application with Enhanced polarization and angle stability
This research introduces a triple-band metamaterial absorber characterized by insensitivity to both polarization and incident angles. The structure includes square ring resonators on the upper side and a continuous metal ground on the lower side, separated by an FR4 substrate. At the lowest operating frequency, the unit cell’s thickness, and length measure 0.0128λ and 0.156λ, respectively. Under normal incidence, the proposed absorber demonstrates three clear absorption peaks at 1.56, 2.43, and 3.36 GHz, achieving absorption rates of 98 %, 99 %, and 97 %, respectively. The absorption response exhibits variation with incident angles up to 70° for both TM and TE polarizations due to its high-level symmetry. This configuration attains negative permittivity and permeability suitable for operational frequencies in the L-band and S-band. The study examines the electric field, impedance, and surface current to provide additional evidence for the absorption analysis. A validated RLC circuit equivalent to the proposed structure has been confirmed using Advanced Design System (ADS). The results indicate a slight deviation, especially at frequencies beyond the resonance frequencies. The structure underwent fabrication and testing in an anechoic chamber, revealing a strong correlation between the simulated and measured results. The suggested absorber holds promise for ISM applications, radar systems, sensing technologies, and energy harvesting systems.
期刊介绍:
The Journal of Magnetism and Magnetic Materials provides an important forum for the disclosure and discussion of original contributions covering the whole spectrum of topics, from basic magnetism to the technology and applications of magnetic materials. The journal encourages greater interaction between the basic and applied sub-disciplines of magnetism with comprehensive review articles, in addition to full-length contributions. In addition, other categories of contributions are welcome, including Critical Focused issues, Current Perspectives and Outreach to the General Public.
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