Pattern synthesis for small phased array antennas

Darwood, Peter B.

January 1998

No description available.

621.382

Mutual coupling; Digital beamforming

The effects of cultural noise on controlled source electromagnetic resonses of subsurface fractures in resistive terrain

Fernandes, Roland Anthony Savio

15 May 2009

Controlled source electromagnetic (CSEM) geophysics has been used with a fair amount of success in near surface hydrogeological studies. Recently, these investigations have been conducted frequently in human impacted field sites containing cultural conductors such as metal fences and buried pipes. Cultural noise adds an element of complexity to the geological interpretation of this type of data. This research investigates the influence of mutual induction between two buried targets in a CSEM experiment. In particular, it looks at the mutual coupling between a buried cultural conductor and a geological heterogeneity. We attempt to isolate the Hz field induced by tertiary currents in targets caused by mutual coupling. This is achieved with a Texas A&M 3D CSEM finite element code, which calculates the secondary Hz fields emanating from a target buried in a halfspace. Buried geological targets and cultural conductors are modeled as volumetric slabs embedded in a halfspace. A series of models have been simulated to study the effect of varying parameters such as target conductivity, transmitter location and shape of a target on the mutual inductance. In each case, the secondary Hz field is calculated for a model with two slabs, and two models with individual slabs. The mutual coupling is calculated by removing the secondary fields from the individual slab models from the response of a two slab model. The calculations of mutual inductance from a variety of such models suggests a complicated interaction of EM fields between the two targets. However, we can explain most of these complexities by adapting a simple approach to Maxwell’s equations. Although the tertiary Hz field is complicated, it may be useful in the characterization and delineation of electrical heterogeneities in the subsurface, which can then be related to geological features such as fractures or joints. It is seen that the most important factor affecting the mutual coupling is the host conductivity. The results have also shown that mutual coupling is very sensitive to transmitter (TX) location, especially when the TX is positioned near one of the targets.

Controlled source electromagnetics

mutual coupling

MIMO Antenna Array Using Cylindrical Dielectric Resonator for Wide Band Communications Applications

Majeed, Asmaa H., Abdullah, Abdulkareem S., Abd-Alhameed, Raed, Sayidmarie, Khalil H.

10 1900

Yes / The present work investigates the operation performance of 2-element configuration multiple input Multiple Output (MIMO) antennas system using Cylindrical Dielectric Resonator (CDR). The MIMO antenna arrays achieve 22.2% impedance bandwidth at S11 ≤ -10 covering the bandwidth from 10GHz to 12.5GHz that meets the essential requirements of wide band communications applications. The first array gives a maximum isolation of 27dB at an element spacing of 22mm, whereas the second array presents a maximum isolation of 42.55dB at element spacing of 12.25mm.

DRA

MIMO antennae

Mutual coupling

Mutual coupling suppression in multiple microstrip antennas for wireless applications

Thuwaini, Alaa H. Radhi

January 2018

Mutual Coupling (MC) is the exchange of energy between multiple antennas when placed on the same PCB, it being one of the critical parameters and a significant issue to be considered when designing MIMO antennas. It appears significantly where multiple antennas are placed very close to each other, with a high coupling affecting the performance of the array, in terms radiation patterns, the reflection coefficient, and influencing the input impedance. Moreover; it degrades the designed efficiency and gain since part of the power that could have been radiated becomes absorbed by other adjacent antennas' elements. The coupling mechanism between multiple antenna elements is identified as being mainly through three different paths or channels: surface wave propagation, space (direct) radiation and reactive near-field coupling. In this thesis, various coupling reduction approaches that are commonly employed in the literature are categorised based on these mechanisms. Furthermore, a new comparative study involving four different array types (PIFA, patch, monopole, and slot), is explained in detail. This thesis primarily focuses on three interconnected research topics for mutual coupling reduction based on new isolation approaches for different wireless applications (i.e. Narrowband, Ultra-wide-band and Multi-band). First, a new Fractal based Electromagnetic Band Gap (FEBG) decoupling structure between PIFAs is proposed and investigated for a narrowband application. Excellent isolation of more than 27 dB (Z-X plane) and 40 dB (Z-Y plane) is obtained without much degradation of the radiation characteristics. It is found that the fractal structures can provide a band-stop effect, because of their self-similarity features for a particular frequency band. Second, new UWB-MIMO antennas are presented with high isolation characteristics. Wideband isolation (≥ 31 dB) is achieved through the entire UWB band (3.1-10.6 GHz) by etching a novel compact planar decoupling structure inserted between these multiple UWB antennas. Finally, new planar MIMO antennas are presented for multi-band (quad bands) applications. A significant isolation improvement over the reference (≥ 17 dB) is achieved in each band by etching a hybrid solution. All the designs reported in this thesis have been fabricated and measured, with the simulated and measured results agreeing well in most cases.

Design Low Mutual Coupling WLAN/WiMAX Antenna for MIMO applications

Huang, Chun-Chieh

01 February 2008

In recent year, wireless communications systems require transmission of higher and higher data rates to foster various multimedia services. The multiple-input multiple-output (MIMO) antennas system has been studied to increase wireless channel capacity and reliability. The mutual coupling of MIMO antennas affects the capacity of the wireless channel. Traditionally, the minimal mutual coupling distance between antenna elements needs to be at least one half wavelength. When MIMO antenna system is used in miniature mobile device, the problem of mutual coupling becomes even more serious. In the first part of this thesis we propose a WLAN/WiMAX antenna that can be operated in 2.4 GHz (2.4¡V2.48 GHz) WLAN band; 2.5 GHz (2.5¡V2.7 GHz) and 3.5 GHz (3.4¡V3.7 GHz) WiMAX band. We use the inverted U slot band notch and omega slot band notch to reduce the mutual coupling in MIMO antennas. Our design is able to reduce the mutual coupling to be less than ¡V20 dB in all interested bands. In the second part, we propose a planar WLAN/WiMAX antenna that can be operated in 2.4 GHz (2.4¡V2.48 GHz), 5.2/5.8GHz (5.15-5.35GHz/5.725-5.825GHz) WLAN band; 2.5 GHz (2.5¡V2.7 GHz), 3.5 GHz (3.4¡V3.7 GHz) and 5.5 GHz (5.25-5.85 GHz) WiMAX band and mutual coupling of MIMO antenna is less than ¡V20 dB in all interested bands.

Multiple-Input Multiple-Output

Antenna

Mutual Coupling

MIMO Performance of Low Mutual Performance of Low Mutual Coupling Antennas in Indoor and Hallway Environments

He, Yuchu

12 July 2013

In this thesis, the 2×2 MIMO performance of several low mutual coupling antennas has been investigated in indoor and hallway scenarios. Three compact antennas intended for mobile applications with low mutual coupling between the input ports are presented in this thesis. To gauge the performances of the three designed antennas, two reference antennas are also used. Channel capacity measurements were conducted in Bahen Center Antenna Lab room 8175 and the Bahen Center 8th floor hallway by using the five antennas as receivers. The antenna spatial location, orientation, line-of-sight and non-line-of-sight situation and richness of multipath effect were considered in the measurements. By averaging the results, it is found that in an indoor environment, low mutual coupling antennas can outperform the reference high mutual coupling antennas especially in higher SNR scenarios. In the hallway environment, low mutual coupling antennas always outperform the reference high mutual coupling antennas due to pattern diversity.

Antenna

MIMO

channel capacity

mutual coupling

0544

MIMO Performance of Low Mutual Performance of Low Mutual Coupling Antennas in Indoor and Hallway Environments

He, Yuchu

12 July 2013

In this thesis, the 2×2 MIMO performance of several low mutual coupling antennas has been investigated in indoor and hallway scenarios. Three compact antennas intended for mobile applications with low mutual coupling between the input ports are presented in this thesis. To gauge the performances of the three designed antennas, two reference antennas are also used. Channel capacity measurements were conducted in Bahen Center Antenna Lab room 8175 and the Bahen Center 8th floor hallway by using the five antennas as receivers. The antenna spatial location, orientation, line-of-sight and non-line-of-sight situation and richness of multipath effect were considered in the measurements. By averaging the results, it is found that in an indoor environment, low mutual coupling antennas can outperform the reference high mutual coupling antennas especially in higher SNR scenarios. In the hallway environment, low mutual coupling antennas always outperform the reference high mutual coupling antennas due to pattern diversity.

Antenna

MIMO

channel capacity

mutual coupling

0544

Metamaterials for Decoupling Antennas and Electromagnetic Systems

Bait Suwailam, Mohammed

13 April 2011

This research focuses on the development of engineered materials, also known as meta- materials, with desirable effective constitutive parameters: electric permittivity (epsilon) and magnetic permeability (mu) to decouple antennas and noise mitigation from electromagnetic systems. An interesting phenomenon of strong relevance to a wide range of problems, where electromagnetic interference is of concern, is the elimination of propagation when one of the constitutive parameters is negative. In such a scenario, transmission of electromagnetic energy would cease, and hence the coupling between radiating systems is reduced. In the first part of this dissertation, novel electromagnetic artificial media have been developed to alleviate the problem of mutual coupling between high-profile and ow-profile antenna systems. The developed design configurations are numerically simulated, and experimentally validated. In the mutual coupling problem between high-profile antennas, a decoupling layer based on artificial magnetic materials (AMM) has been developed and placed between highly-coupled monopole antenna elements spaced by less than Lambda/6, where Lambda is the operating wavelength of the radiating elements. The decoupling layer not only provides high mutual coupling suppression (more than 20-dB) but also maintains good impedance matching and low correlation between the antenna elements suitable for use in Multiple-Input Multiple-Output (MIMO) communication systems. In the mutual coupling problem between low-profile antennas, novel sub-wavelength complementary split-ring resonators (CSRRs) are developed to decouple microstrip patch antenna elements. The proposed design con figuration has the advantage of low-cost production and maintaining the pro file of the antenna system unchanged without the need for extra layers. Using the designed structure, a 10-dB reduction in the mutual coupling between two patch antennas has been achieved. The second part of this dissertation utilizes electromagnetic artificial media for noise mitigation and reduction of undesirable electromagnetic radiation from high-speed printed-circuit boards (PCBs) and modern electronic enclosures with openings (apertures). Numerical results based on the developed design configurations are presented, discussed, and compared with measurements. To alleviate the problem of simultaneous switching noise (SSN) in high-speed microprocessors and personal computers, a novel technique based on cascaded CSRRs has been proposed. The proposed design has achieved a wideband suppression of SSN and maintained a robust signal integrity performance. A novel use of electromagnetic bandgap (EBG) structures has been proposed to mitigate undesirable electromagnetic radiation from enclosures with openings. By using ribbon of EBG surfaces, a significant suppression of electromagnetic radiation from openings has been achieved.

Metamaterials

mutual coupling

switching noise

EMI radiation

Electrical and Computer Engineering

Metamaterials for Decoupling Antennas and Electromagnetic Systems

Bait Suwailam, Mohammed

13 April 2011

This research focuses on the development of engineered materials, also known as meta- materials, with desirable effective constitutive parameters: electric permittivity (epsilon) and magnetic permeability (mu) to decouple antennas and noise mitigation from electromagnetic systems. An interesting phenomenon of strong relevance to a wide range of problems, where electromagnetic interference is of concern, is the elimination of propagation when one of the constitutive parameters is negative. In such a scenario, transmission of electromagnetic energy would cease, and hence the coupling between radiating systems is reduced. In the first part of this dissertation, novel electromagnetic artificial media have been developed to alleviate the problem of mutual coupling between high-profile and ow-profile antenna systems. The developed design configurations are numerically simulated, and experimentally validated. In the mutual coupling problem between high-profile antennas, a decoupling layer based on artificial magnetic materials (AMM) has been developed and placed between highly-coupled monopole antenna elements spaced by less than Lambda/6, where Lambda is the operating wavelength of the radiating elements. The decoupling layer not only provides high mutual coupling suppression (more than 20-dB) but also maintains good impedance matching and low correlation between the antenna elements suitable for use in Multiple-Input Multiple-Output (MIMO) communication systems. In the mutual coupling problem between low-profile antennas, novel sub-wavelength complementary split-ring resonators (CSRRs) are developed to decouple microstrip patch antenna elements. The proposed design con figuration has the advantage of low-cost production and maintaining the pro file of the antenna system unchanged without the need for extra layers. Using the designed structure, a 10-dB reduction in the mutual coupling between two patch antennas has been achieved. The second part of this dissertation utilizes electromagnetic artificial media for noise mitigation and reduction of undesirable electromagnetic radiation from high-speed printed-circuit boards (PCBs) and modern electronic enclosures with openings (apertures). Numerical results based on the developed design configurations are presented, discussed, and compared with measurements. To alleviate the problem of simultaneous switching noise (SSN) in high-speed microprocessors and personal computers, a novel technique based on cascaded CSRRs has been proposed. The proposed design has achieved a wideband suppression of SSN and maintained a robust signal integrity performance. A novel use of electromagnetic bandgap (EBG) structures has been proposed to mitigate undesirable electromagnetic radiation from enclosures with openings. By using ribbon of EBG surfaces, a significant suppression of electromagnetic radiation from openings has been achieved.

Metamaterials

mutual coupling

switching noise

EMI radiation

Electrical and Computer Engineering

The Impact of Antenna and RF System Characteristics on MIMO System Capacity

Morris, Matthew Leon

26 July 2005

The recent growth in demand for wireless services coupled with the limited spectrum available for these services has spawned new efforts to increase the spectral efficiency of wireless links. Recent research has shown that in multipath propagation environments, the spatial characteristics of the propagation channel can be exploited to increase spectral efficiency through the use of multiple antennas at the transmitting and receiving nodes. Such multiple-input multiple-output (MIMO) systems show promise for dramatic performance gains over their single-antenna counterparts. However, MIMO system performance is influenced by many different factors. Antenna array configuration directly contributes to MIMO system performance. The ability to build and integrate adaptive antenna arrays into MIMO systems requires the development of strategies for determining which antenna array configuration best enhances performance. Since an exhaustive search of all configurations is computationally prohibitive, this dissertation develops information theoretic based, computationally tractable solutions for determining favorable array configurations. The characteristics of the MIMO receiver front-end also play a large role in determining how well the system performs. Where portable MIMO devices will be forced to closely space antenna elements, mutual coupling can greatly impact both capacity and diversity performance. To study strategies for mitigating mutual coupling performance degradation, an accurate receiver front-end model is necessary. This work realistically models amplifier noise in the receiver and determines how matching networks may be used to improve system performance in the presence of antenna mutual coupling and amplifier coupling. Since MIMO systems operate by identifying optimal antenna array weights for the channel of interest, it is surprising that array superdirectivity has yet to be observed in theoretical solutions to the problem. When formulating system capacity using a radiated power constraint, the capacity is shown to be overestimated due to superdirectivity. Since superdirectivity provides for elegant theoretical results and poor realistic performance, this work incorporates constraints into the formulation of system capacity to arrive at phyically achievable capacity values.

MIMO

capacity

superdirectivity

mutual coupling

antenna selection

Electrical and Computer Engineering