toplogo
Iniciar sesión
Información - Antenna design - # Wideband and Wide Beam Unidirectional Dipole Antenna for WLAN

A Novel Wideband and Wide Beam High Gain Unidirectional Dipole Antenna for Next Generation WLAN Applications


Conceptos Básicos
A novel magneto-electric dipole antenna with a tilted design and a parasitic scatterer is presented, which achieves wide bandwidth and wide beam coverage for next-generation WLAN applications.
Resumen

The paper presents a novel wideband and wide beam unidirectional magneto-electric (ME) dipole antenna design for Wi-Fi-7 (5.18-7.125GHz) applications. The key aspects of the antenna design are:

  1. Conventional dipole antenna: The conventional printed dipole antenna is not capable of providing wide beam coverage in the required frequency range.

  2. Dipole with one scatterer: Adding one parasitic scatterer to the conventional dipole helps introduce an additional resonance at a lower frequency, broadening the overall bandwidth.

  3. Tilted dipole with one scatterer: Tilting the radiating elements of the dipole antenna, along with the addition of the parasitic scatterer, further improves the bandwidth and beamwidth performance. The tilted design reshapes the current distribution on the antenna, leading to wider azimuthal beamwidth.

The simulation and measurement results show that the proposed tilted dipole with one scatterer antenna achieves over 50% fractional bandwidth and wide beamwidth exceeding 100° in both E-plane and H-plane across the 5GHz to 8GHz frequency range. This makes the antenna well-suited for next-generation WLAN applications that require wide coverage and high throughput.

The authors also discuss the practical implementation aspects, such as the use of a gamma feed and the arrangement of two antenna elements at +45° and -45° inclinations to achieve cross-polarization and spatial diversity. The measured results closely match the simulated performance, validating the efficacy of the proposed antenna design approach.

edit_icon

Personalizar resumen

edit_icon

Reescribir con IA

edit_icon

Generar citas

translate_icon

Traducir fuente

visual_icon

Generar mapa mental

visit_icon

Ver fuente

Estadísticas
The antenna achieves an azimuthal beamwidth of 87° at 5.5GHz and 131.3° at 6.5GHz.
Citas
"By tilting the radiators and adding scatterer, it will affect the distribution of surface currents on the antenna structure. It will help reshape current distribution along the antenna element, and thereby improving antenna azimuthal beamwidth." "Our findings serve as a testament to the meticulous design and engineering efforts invested in crafting a high-performance solution tailored to meet evolving demands of modern wireless communications systems."

Consultas más profundas

How can the proposed antenna design be further optimized to achieve even wider beamwidth across the entire operating frequency band?

To further optimize the proposed antenna design for achieving even wider beamwidth across the entire operating frequency band, several strategies can be implemented. One approach could involve fine-tuning the dimensions and angles of the tilted radiators and scatterers to maximize the redirection of energy towards the sides, thereby broadening the beamwidth. Additionally, exploring advanced simulation tools to iteratively adjust the antenna geometry and material properties can help in achieving the desired beamwidth. Incorporating more sophisticated feeding techniques, such as phased array feeding or beamforming, can also enhance the beamwidth control and coverage. Moreover, investigating novel materials with unique electromagnetic properties that can manipulate the radiation pattern could lead to further improvements in beamwidth.

What are the potential challenges in scaling this antenna design for larger antenna arrays to meet the coverage requirements of next-generation WLAN systems?

Scaling the proposed antenna design for larger antenna arrays to meet the coverage requirements of next-generation WLAN systems may pose several challenges. One significant challenge is maintaining the uniformity and coherence of the radiation patterns across all elements in the array, especially when dealing with a large number of antennas. Ensuring proper spacing and mutual coupling between elements to avoid interference and achieve desired array characteristics can be complex. Another challenge lies in the practical implementation of the array, including the integration of multiple antennas, feed networks, and signal processing components, which can introduce complexities in system design and deployment. Additionally, the manufacturing and cost considerations associated with scaling up the antenna array while maintaining performance and reliability can be challenging.

What other antenna architectures or feeding techniques could be explored to enhance the performance and integration of this wideband and wide beam antenna for practical WLAN deployments?

To enhance the performance and integration of the wideband and wide beam antenna for practical WLAN deployments, exploring alternative antenna architectures and feeding techniques can be beneficial. One approach could involve investigating phased array antennas, which offer beam steering capabilities and adaptive beamforming to dynamically adjust the radiation pattern based on the communication requirements. Another option is to explore metamaterial-based antennas, which can provide unique electromagnetic properties for controlling the radiation characteristics. Additionally, considering multiband or dual-polarized antennas can enhance the versatility and coverage of the antenna system for diverse WLAN applications. Implementing advanced feeding techniques such as aperture-coupled feeding or substrate integrated waveguide feeding can also improve the efficiency and bandwidth of the antenna system. By exploring these alternative architectures and feeding techniques, the performance and integration of the wideband and wide beam antenna can be further optimized for practical WLAN deployments.
0
star