TEXTILE-BASED ABSORBER DESIGN FOR 5G APPLICATIONS
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Keywords:
absorbed, TEXTILE-BASED, 5GAbstract
In this study, a textile-based absorber structure The textile material comprises two layers, with the absorber layer consisting of copper and the weft-knitted fabric was designed for 5G applications is presented. The proposed structure consists of copper and weft-knitted fabric arranged in a square resonator configuration. The textile material comprises two layers, with the absorber layer made of copper and the weft-knitted fabric. The absorber was tested in the frequency range of 2.20 GHz to 3.30 GHz, showing strong agreement between the measured and simulated results. The findings indicate that lightweight, flexible, and durable textile-based electromagnetic interference (EMI) shielding materials can effectively replace traditional metal-based shielding materials. The results demonstrate that factors like material thickness and edge length play a significant role in improving shielding effectiveness. Thicker materials provided better shielding, especially at higher frequencies, making them ideal for 5G applications and other electromagnetic shielding needs.
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