1 |
Miniaturized Balanced Antenna with Integrated Balun for Practical LTE ApplicationsElfergani, Issa T., Rodriguez, Jonathan, Abdulssalam, F., See, Chan H., Abd-Alhameed, Raed 20 December 2016 (has links)
Yes / A design of dual-band balanced antenna structure operating in the 700 and 2600MHz LTE bands is studied and investigated. The overall dimensions of the radiator are 50 × 18 × 7 mm3 allowing it to be easily concealed within mobile handsets. A broad-band balun is designed and integrated with the antenna handset in order to provide the feeding network and perform the measurements of the antenna radiation performance. Prototypes of proposed antenna with and without balun are fabricated and verified. The simulated and practical results with and without the handheld effects in terms of reflection coefficient, power gain and radiation pattern, are studied and shown reasonable agreement. / H2020
|
2 |
Interaction Between Electromagnetic Field and Human Body for Dual Band Balanced Antenna Using Hybrid Computational MethodAlhaddad, A.G., Ramli, Khairun N., Abd-Alhameed, Raed, Zhou, Dawei 11 August 2010 (has links)
Yes / This paper describes a hybrid computational method
which efficiently models the interaction between a small antenna
placed in proximity with the human body. Results for several test
cases of placed in different locations on the body are presented
and discussed. The near and far fields were incorporated into the
study to provide a full understanding of the impact on human
tissue. The cumulative distribution function of the radiation
efficiency and absorbed power is also provided. The antennas are
assumed to be operating over the 2.4 GHz and 5.2 GHz WLAN
frequencies.
|
3 |
A review of lunar communications and antennas: assessing performance in the context of propagation and radiationSerria, E., Gadhafi, R., AlMaeeni, S., Mukhtar, H., Copiaco, A., Abd-Alhameed, Raed, Lemieux, F., Mansoor, W. 29 December 2023 (has links)
Yes / Over the previous two decades, a notable array of space exploration missions have been initiated with the primary aim of facilitating the return of both humans and robots from Earth to the moon. The significance of these endeavors cannot be emphasized enough as numerous entities, both public and private, from across the globe have invested substantial resources into this pursuit. Researchers have committed their efforts to addressing the challenges linked to lunar communication. Even with all of these efforts, only a few of the many suggested designs for communication and antennas on the moon have been evaluated and compared. These designs have also not been shared with the scientific community. To bridge this gap in the existing body of knowledge, this paper conducts a thorough review of lunar surface communication and the diverse antenna designs employed in lunar communication systems. This paper provides a summary of the findings presented in lunar surface communication research while also outlining the assorted challenges that impact lunar communication. Apart from various antenna designs reported in this field, based on their intended usage, two additional classifications are introduced: (a) mission-based antennas-utilized in actual lunar missions-and (b) research-based antennas-employed solely for research purposes. Given the critical need to comprehend and predict lunar conditions and antenna behaviors within those conditions, this review holds immense significance. Its relevance is particularly pronounced in light of the numerous upcoming lunar missions that have been announced. / This work is part of the “Performance Evaluation of Lunar Rashid Rover Communication System” research project, supported by the University of Dubai.
|
4 |
Balanced dual-segment cylindrical dielectric resonator antennas for ultra-wideband applicationsMajeed, Asmaa H., Abdullah, Abdulkareem S., Sayidmarie, Khalil H., Abd-Alhameed, Raed, Elmegri, Fauzi, Noras, James M. 22 October 2015 (has links)
Yes / In this paper, balanced dual segment cylindrical dielectric antennas (CDRA) with ultra wide-band operation are reported. First a T-shaped slot and L-shaped microstrip feeding line are suggested to furnish a balanced coupling mechanism for feeding two DRAs. Performance of the proposed antenna was analyzed and optimized against the target frequency band. The proposed antenna was then modified by adding a C-shaped strip to increase the gain. The performances of both balanced antennas were characterized and optimized in terms of antenna reflection coefficient, radiation pattern, and gain. The antennas cover the frequency range from 6.4 GHz to 11.736 GHz, which is 58.7% bandwidth. A maximum gain of 2.66 dB was achieved at a frequency of 7 GHz with the first antenna, with a further 2.25 dB increase in maximum gain attained by adding the C-shaped strip. For validation, prototypes of the two antennas were fabricated and tested. The predicted and measured results showed reasonable agreement and the results confirmed good impedance bandwidth characteristics for ultra-wideband operation from both proposed balanced antennas.
|
Page generated in 0.0872 seconds