A sub 1 GHz ultra miniaturized folded dipole patch antenna for biomedical applications

Chishti, Abdul Rehman; Aziz, Abdul; Aljaloud, Khaled; Tahir, Farooq A.; Abbasi, Qammer H.; Khan, Zia Ullah; Hussain, Rifaqat

doi:10.1038/s41598-023-36747-4

Cited by 3 publications

(2 citation statements)

References 40 publications

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“…Patch 2 has a length of 30 mm and a width of 30 mm. Using a single varactor in an antenna reconfigurable system offers several benefits [17]. Firstly, it simplifies the overall design by reducing the number of components required.…”

Section: Methodsmentioning

confidence: 99%

“…In [17], a miniaturized folded dipole patch antenna design for biomedical application which operate at 1 GHz, the antenna side was reduce by 835 with lumped inductor places at the centre patch of the radiating which makes it suitable for hyperthermia, the proposed give an impendent band with 6 MHz. Several studies have demonstrated the potential of microwave hyperthermia in various cancer types, including breast cancer, head and neck cancer, and cervical cancer.…”

Section: Introductionmentioning

confidence: 99%

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The enhancing energy efficiency in hyperthermia treatment: a frequency-reconfigurable L-Shape antenna design and analysis

Akinola,

Leelakrishna

2023

TAPR

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The object of research is a frequency-reconfigurable L-Shape antenna. This paper presents an innovative study focusing on the design and analysis of a frequency-reconfigurable L-Shape antenna with a specific application in Hyperthermia Treatment. The antenna, operating in the frequency range of 2.5 to 8 GHz, utilizes a varactor to achieve agility and simplify design, thereby reducing component count. Constructed with a Roggers RT5880 (lossy) substrate, the L-Shape configuration ensures optimal performance. The incorporation of a single varactor, acting as a junction capacitance, not only enables straightforward tuning but also contributes to enhanced energy efficiency by reducing overall power consumption in the reconfigurable antenna system. The study employed CST Microwave Studio's 3D Electromagnetic field simulation software for time domain solver-based simulations, with validation conducted using the frequency domain solver. Results from the simulations showcase the antenna's performance at different frequency states. At the tuning state frequency of 2.7 GHz, the antenna exhibits an impressive gain of 1.905 dB and a directivity of 7.530 dB. Similarly, at the tuning state frequency of 6.89 GHz, the gain is measured at 6.806 dB with a directivity of 7.490 dB. The proposed L-Shape antenna design not only demonstrates significant potential for Hyperthermia Treatment, allowing targeted heating within the 2.5 to 8 GHz frequency range but also aligns with the multidisciplinary focus of medical science. This contribution reflects the commitment to advancing medical science through original research, fostering innovation, and promoting energy-efficient solutions with practical applications in clinical settings.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The enhancing energy efficiency in hyperthermia treatment: a frequency-reconfigurable L-Shape antenna design and analysis

Akinola,

Leelakrishna

2023

TAPR

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Miniaturized Mechanical Antennas: Advances, Challenges, and Future Directions

Ren

2024

Advanced Physics Research

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In the past decade, miniaturized mechanical antennas have become a research focus. Several types of mechanical antennas based on different operation principles, including mechanical antennas based on magnetoelectric effect, mechanical antennas based on permanent magnets, mechanical antennas based on electrets, and mechanical antennas based on piezoelectric resonators, are presented, all with sizes significantly smaller than conventional electrical antennas operating at the same resonant frequencies. This review focuses on the advances in mechanical antennas, potential applications as well as challenges and potential future directions for further performance improvement. Although the sizes of the state‐of‐the‐art mechanical antennas are several orders of magnitude smaller than traditional electrical counterparts with the same resonant frequencies, the reported maximum operation distance of mechanical antennas is still short, which is a major challenge for it to be widely implemented. By adopting new materials for mechanical antennas, adopting array configurations, adopting receiving antennas with higher sensitivity, and building new electromagnetic‐electromechanical coupled simulation methods, the maximum operation distance may be significantly improved, making mechanical antennas widely implemented in the Internet of Things (IoT), wireless sensor networks (WSN), implantable medical devices (IMD), and portable electronics applications.

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Conducting a Comparative Analysis of Performance Metrics within the IMT-E Band involves Evaluating the Effectiveness of Dipole and Helical Antennas at a Center Frequency of 2.6 GHz

Nagalakshmi,

Revanth

2024

2024 International Conference on Integrated Circuits and Communication Systems (ICICACS)

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A sub 1 GHz ultra miniaturized folded dipole patch antenna for biomedical applications

Cited by 3 publications

References 40 publications

The enhancing energy efficiency in hyperthermia treatment: a frequency-reconfigurable L-Shape antenna design and analysis

The enhancing energy efficiency in hyperthermia treatment: a frequency-reconfigurable L-Shape antenna design and analysis

Miniaturized Mechanical Antennas: Advances, Challenges, and Future Directions

Conducting a Comparative Analysis of Performance Metrics within the IMT-E Band involves Evaluating the Effectiveness of Dipole and Helical Antennas at a Center Frequency of 2.6 GHz

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