Global ETD Search

1	Design considerations of MIMO antennas for mobile phones Usman, Muhammad, Abd-Alhameed, Raed, Excell, Peter S. January 2008 (has links) Yes / The paper presents a new modeling and design concept of antennas using polar- ization diversity of 2 £ 2 and 3 £ 3 Multiple Input Multiple Outputs (MIMO) system that is proposed for future mobile handsets. The channel capacity is investigated and discussed over Raleigh fading channel and compared to a linear/planner antenna array MIMO channel. The capacity is also discussed over three types of power azimuth spectrums. The results are compared to the constraints capacity limits in which the maximum capacity observed. MIMO antennas Mobile phones
2	Design of 2x2 U-shape MIMO slot antennas with EBG material for mobile handset applications Abidin, Z.Z., Ma, Y., Abd-Alhameed, Raed, Ramli, Khairun N., Zhou, Dawei, Bin-Melha, Mohammed S., Noras, James M., Halliwell, Rosemary A. 2011 March 1922 (has links) yes / A compact dual U-shaped slot PIFA antenna with Electromagnetic Bandgap (EBG) material on a relatively low dielectric constant substrate is presented. Periodic structures have found to reduce mutual coupling and decrease the separation of antenna and ground plane. A design with EGB material suitable for a small terminal mobile handset operating at 2.4 GHz was studied. Simulated and measured scattering parameters are compared for U-shaped slot PIFA antenna with and without EBG structures. An evaluation of MIMO antennas is presented, with analysis of the mutual coupling, correlation coefficient, total active reflection coefficient (TARC), channel capacity and capacity loss. The proposed antenna meets the requirements for practical application within a mobile handset. / Electronics and Telecommunications Antennas MIMO antennas Electromagnetic Bandgap (EBG)
3	LTE MIMO Antenna with High Isolation for Laptop Computer Wu, Tsung-Ju 14 June 2012 (has links) For applications of wireless communication of the fourth generation (4G LTE), the technique of using a printed parallel-resonant spiral strip for bandwidth enhancement of a small-size planar laptop computer (especially the thin Ultrabook) antenna for the LTE operation is first presented. The antenna is printed on a thin FR4 substrate of small size 45 x 9 mm2 with a simple uniplanar structure which is promising for Ultrabook application. Based on the proposed antenna structure, its application for MIMO operation to achieve enhanced isolation is also analyzed in this thesis. Different from the works for the relatively much smaller ground plane conditions such as in the mobile phones, the effect of different size of the supporting conductive plate of the upper corner of the Ultrabook is discussed for the isolation issue of the MIMO antennas. Finally, the technique of isolation improvement in the LTE700 band for the MIMO operation in the Ultrabook is presented. LTE antennas printed antennas internal laptop computer antennas isolation improvement MIMO antennas parallel-resonant spiral strip
4	Flexible, Reconfigurable and Wearable Antennas Integrated with Artificial Magnetic Conducting Surfaces January 2017 (has links) abstract: Flexibility, reconfigurability and wearability technologies for antenna designs are presented, investigated and merged in this work. Prior to the design of these radiating elements, a study is conducted on several flexible substrates and how to fabricate flexible devices. Furthermore, the integration of active devices into the flexible substrates is also investigated. A new approach of designing inkjet-printed flexible reconfigurable antennas, based on the concept of printed slot elements, is proposed. An alternate technique to reconfigure the folded slot antenna is also reported. The proposed radiator works for both Wireless Local Area Network (WLAN) and Worldwide Interoperability for Microwave Access (WiMAX) applications. The flexible reconfigurable antenna is also redesigned to resonate at both (2.4/5.2 GHz) for WLAN devices and its Multiple-Input Multiple-Output (MIMO) configuration is reported. Two orthogonal elements are used to form the MIMO antenna system for better isolation. The wearability of the proposed flexible reconfigurable radiator is also discussed. Since wearable antennas operate close to the human body, which is considered as a lossy tissue, an isolation between the radiating elements and human body is required to improve the radiation characteristics and to reduce the Specific Absorption Rate (SAR). The proposed antenna is redesigned on an Artificial Magnetic Conductor (AMC) surface that also functions as a ground plane to isolate the radiator from the human body. To examine its performance as a body-worn device, it is measured at different positions on the human body. Furthermore, simulations show that the SAR level is reduced when using the AMC surface. The proposed wearable antenna works for both Wireless Body Area Network (WBAN) and WiMAX body-worn wireless devices. Electromagnetic bandgap (EBG) structures are used to suppress surface wave propagation in printed antennas. However, due to the presence of vias, not all of them can be utilized in flexible radiators. Thus, a Perforated High Impedance Surface (PHIS) is proposed which suppresses the surface waves without the need of vias, and it also serves as a ground plane for flexible antennas. The surface wave suppression and the antenna applications of the proposed PHIS surface are discussed. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2017 Electrical engineering Artificial Magnetic Conductors (AMCs) Electromagnetic bandgap (EBG) structures Flexible Antennas MIMO Antennas Reconfigurable Antennas Wearable Antennas
5	8-Port Semi-Circular Arc MIMO Antenna with an Inverted L-Strip Loaded Connected Ground for UWB Applications Addepalli, T., Desai, A., Elfergani, Issa T., Anveshkumar, N., Kulkarni, J., Zebiri, C., Rodriguez, J., Abd-Alhameed, Raed 19 June 2021 (has links) yes / Multiple-input multiple-output (MIMO) antennas with four and eight elements having connected grounds are designed for ultra-wideband applications. Careful optimization of the lines connecting the grounds leads to reduced mutual coupling amongst the radiating patches. The proposed antenna has a modified substrate geometry and comprises a circular arc-shaped conductive element on the top with the modified ground plane geometry. Polarization diversity and isolation are achieved by replicating the elements orthogonally forming a plus shape antenna structure. The modified ground plane consists of an inverted L strip and semi ellipse slot over the partial ground that helps the antenna in achieving effective wide bandwidth spanning from (117.91%) 2.84–11 GHz. Both 4/8-port antenna achieves a size of 0.61 λ × 0.61 λ mm2 (lowest frequency) where 4-port antenna is printed on FR4 substrate. The 4-port UWB MIMO antenna attains wide impedance bandwidth, Omni-directional pattern, isolation >15 dB, ECC 4.5 dB making the MIMO antenna suitable for portable UWB applications. Four element antenna structure is further extended to 8-element configuration with the connected ground where the decent value of IBW, isolation, and ECC is achieved. 4-elements 8-elements Ultra-wide broadband (UWB) Envelope correlation coefficient (ECC) Isolation
6	Conception de systèmes antennaires MIMO multi-standards LTE pour les nœuds relais / Design of LTE MIMO antenna systems dedicated to relay nodes Sadaoui, Lamia 13 December 2018 (has links) Pour déployer la quatrième génération de téléphonie 4G/LTE ou « LTE advanced », les opérateurs mobiles sont confrontés à de fortes contraintes : d’une part assurer une bonne couverture géographique mais aussi une excellente qualité de service. Ceci nécessite une ingénierie du réseau qui dépasse largement ce qui a été mis en place pour les réseaux GSM ou 3G. L’industrie des télécoms a créé pour cela le concept de « small cells » ou petites cellules qui viennent en renfort des « macrocells » ou grosses cellules. Cette thèse cherche à apporter une solution à cette problématique à travers notamment le développement d'antennes pour « smart cells ». Cette étude, supportée par le projet FUI NETCOM, doit permettre aux opérateurs d’étendre la couverture et la capacité de leurs réseaux à moindre coût tout en préservant la qualité de service. Pour cela, l’objectif plus précis de cette thèse est de concevoir un système multi-antennaire multistandard MIMO (Multiple-Input Multiple-Output) dédié à des noeuds relais pour le déploiement de la quatrième génération de téléphonie LTE. Cette conception doit être compatible avec 3 bandes de fréquences du LTE : (700-900 MHz) pour les bandes LTE 700 et LTE 800, (1710-1880 MHz) pour les bandes GSM 1800 / LTE 1800 et la dernière (2500-2690 MHz) pour le LTE 2600. Pour cela, nous avons étudié tout d’abord un système à 4 accès mono-bande, en nous concentrant uniquement sur la bande basse de 700 à 900 MHz. Dans une seconde étude, nous avons cherché à couvrir les deux autres bandes supérieures en nous servant d’éléments parasites pour constituer un système MIMO à 4 accès tri-bande. Nous avons ensuite étudié l’influence de l’environnement proche du système antennaire, avec la présence d’un radiateur métallique. Un problème important et fréquent dans les systèmes multi-antennes étant le couplage, nous avons également étudié et réalisé une technique de découplage. Celle-ci servira à isoler les éléments rayonnants à espacement réduit, conçus pour nos trois bandes LTE. / To deploy the fourth generation called 4G/LTE or "LTE advanced", mobile operators face strong constraints: they must ensure a good geographic coverage but also an excellent quality of service. This requires new methods that go far beyond what has been implemented for GSM or 3G networks. The telecom industry has created the concept of "small cells" that reinforce the "macrocells" deployed by the operators. This thesis tries to provide a solution to this problem and more particularly through the development of antennas for a product called "smart cell". This study, supported by the FUI project NETCOM, should enable mobile operators to extend the coverage and capacity of their networks at a lower cost while maintaining a good quality of service. To do that, the aim of this thesis more particularly is the design of a multi-band multi-antennas MIMO system (Multiple-Input Multiple-Output) dedicated to relay nodes for the deployment of the fourth generation 4G/LTE or "LTE advanced". The antenna design considers the coverage of the three LTE operating frequency bands and must be compatible with them. The (700-900 MHz) frequency band is used for the LTE 700 and LTE 800 bands, (1710-1880 MHz) for the GSM 1800/LTE 1800 bands and the last (2500-2690 MHz) for the LTE 2600 bands. In our first study, a reference system with 4 access was studied in simulation and measured, for only the low band 700-900 MHz. In a second study, we tried to cover the other two higher bands to have a tri-band system using the parasitic elements to get a three-band MIMO system with 4 access. We studied then, the influence of the environment close to the antenna system, with the presence of a metallic radiator. As we often encounter a frequent problem in multi-antenna systems which is the coupling problem between the different access of a multi antenna system, so we have studied and realized a decoupling technique. This technique was used to enhance the isolation between the different access. Antennes MIMO Antennes multi-bandes LTE Éléments parasites Technique de découplage Environnement métallique MIMO antennas Multiband antennas LTE Parasitic elements Decoupling technique Metallic environment
7	Downlink Transmission Techniques For Multi User Multi Input Multi Output Wireless Communications Coskun, Adem 01 August 2007 (has links) (PDF) Multi-user MIMO (MIMO-MU) communication techniques make use of available channel state information at the transmitter to mitigate the inter-user interference. The goal of these techniques is to provide the least interference at the mobile stations by applying a precoding operation. In this thesis a comparison of available techniques in the literature such as Channel Decomposition, SINR Balancing, Joint-MMSE optimization is presented. Novel techniques for the MIMO multi-user downlink communication systems, where a single stream is transmitted to each user are proposed. The proposed methods, different from the other methods in the literature, use a simple receiver to combat the interference. It has been shown that MRC based receivers are as good as more complicated joint MMSE receivers.

1

Page generated in 0.0564 seconds