Inkjet-Printed Ultra Wide Band Fractal Antennas

Maza, Armando Rodriguez

05 1900

In this work, Paper-based inkjet-printed Ultra-wide band (UWB) fractal antennas are presented. Three new designs, a combined UWB fractal monopole based on the fourth order Koch Snowflake fractal which utilizes a Sierpinski Gasket fractal for ink reduction, a Cantor-based fractal antenna which performs a larger bandwidth compared to previously published UWB Cantor fractal monopole antenna, and a 3D loop fractal antenna which attains miniaturization, impedance matching and multiband characteristics. It is shown that fractals prove to be a successful method of reducing fabrication cost in inkjet printed antennas while retaining or enhancing printed antenna performance.

Antenna

3D Antenna

Fractal

Ultra-Wideband

Inkjet-printing

Design Method for Optimized Wideband Iterative Differential Amplifier in MOS Technology

Minch, Steven L.

10 March 2010

Wideband amplifiers are an important part of analog design, and much effort has been expended in improving them. A popular implementation of a wideband amplifier is to use one or two stages with high gain in one or both stages. An alternative to this method is presented in this work, developed for Metal Oxide Semiconductor (MOS) amplifiers. The new approach, building on previous work in bipolar technology, uses multiple differential MOS stages to achieve similar gain requirements to other wideband amplifiers. It is shown that multiple stages with low gain, if implemented according to the present design method, can lead to better gain-bandwidth product (GBW) than a few stages. As part of the design process, GBW is optimized and current draw is reduced. Derived equations are used to find the ideal device widths of each stage to improve GBW. The amplifier's current draw is reduced through increasing the widths of each successive stage according to a derived, fixed taper factor. Simulation of the resulting amplifier shows that these optimization procedures can improve GBW by 20% or more over a nonoptimized cascaded amplifier.

wideband

MOS

differential

amplifier

iterative

Electrical and Computer Engineering

Wideband Amplifier Design for STO Technology

Chen, Tingsu

January 2011

Spin Torque Oscillator (STO) is a promising technology for microwave and radar applications due to its large tunability, miniature size, high operation frequency, high integration level, etc. However, the technology comes also with issues and challenges,such as low output power and spectrum impurity. For instance, in order to apply the STO technology into communication systems, an amplifier is required to compensate the STO’s low output power.     This thesis presents an amplifier for promising Magnetic Tunnel Junction (MTJ) STO devices. The motional resistance of different MTJ STO devices varies from several Ohms to hundreds Ohms, which makes the design challenging. This thesis focuses first on extracting the amplifier requirements using the state-of-the-art MTJ STO devices. The operation frequency of MTJ STO is in the range of 4-8GHzwith a -40～-60 dBm output power. Therefore, a wideband amplifier with 45-65 dB gain is required. Then based on the amplifier requirements, an amplifier topology is proposed, which is composed of two types of input balun-LNA stages depending onthe motional resistance of the STO, a broadband limiting amplifier and an outputbuffer. CG-CS architecture is suitable for the input balun-LNA in the small motional resistance case and cascoded-CS architecture is suitable for the large motional resistance case. The limiting amplifier and the output buffer are the common circuits shared by two cases via switches.     The wideband amplifier for STO is implemented using a 65nm CMOS process with 1.2 V supply and it exhibits 52.36 dB gain with 1.34-11.8 GHz bandwidth insmall motional resistance case and 59.29 dB gain with 1.171-8.178 GHz bandwidth in large motional resistance case. The simulation results show that the amplifier has very low power consumption and meets the linearity and noise performance requirements.

Wideband Amplifier STO CMOS microwave

Embedded Systems

Inbäddad systemteknik

A Frequency-Modulated Continuous Wave-Based Boundary Detection System in a Small PCB Profile

Asgarian, Hamid R

01 December 2012

Falls are a cause of concern for the elderly because it can make them unable to call for help. A monitoring system can detect automatically their immobility and provide help to the elderly if they fall. Ultra-wide band signals for a monitoring system is an excellent choice since it has low enough power to not interfere with other medical and household electronics as well as being able to transmit data to a central monitoring unit. One part of this monitoring system is a boundary detection system used to verify that the monitoring system is not capturing events outside the monitoring region such as an event outside the house or in a neighboring room. The work presented in the paper, “A Frequency-Modulated Continuous Wave-Based Boundary Detection System for Determination of Monitoring Region for an Indoor Ultra-Wideband Short Range Radar-Based Eldercare Monitoring System” has determined that a frequency modulated continuous wave (FMCW) based system is an acceptable solution for boundary detection. A FMCW system can measure distance with less than 10cm accuracy if the chosen spectrum bandwidth is 1GHz or more. This thesis presents the design of a low cost approach to small PCB footprint distance detection circuitry for the boundary detection system.

ultra-wideband

UWB

FMCW

monitoring system

boundary detection

falls

Dielectric resonator antenna design for UWB applications

Elmegri, Fauzi, See, Chan H., Abd-Alhameed, Raed, Zebiri, Chemseddine, Excell, Peter S.

January 2013

No / A small dielectric resonator antenna has been designed for ultra wideband (UWB) communication system applications. The antenna element is a rectangular low permittivity ceramic block, with a dielectric constant of 9.4, and the modified T-shaped feed network includes a 50 ohm microstrip line to achieve strong coupling, and some bandwidth enhancement. The antenna performance is simulated and measured over a frequency band extending from 3100 MHz to 5500 MHz; the impedance bandwidth over this interval is 55.8% with VSWR <; 2, making the antenna suitable for UWB applications.

Dielectric resonator antennas

Dielectrics

Bandwidth

Ultra wideband antennas

Printed monopole antenna with tunable band-notched characteristic for use in mobile and ultra-wide band applications

Elfergani, Issa T., Hussaini, Abubakar S., See, Chan H., Abd-Alhameed, Raed, McEwan, Neil J., Zhu, Shaozhen (Sharon), Rodriguez, Jonathan, Clarke, Roger W.

06 1900

Yes / A tunable band-notch printed monopole antenna is presented, exhibiting a wide impedance bandwidth from 1.5 to 5.5 GHz with good impedance matching (VSWR ≤ 2) and a tunable rejected frequency band from 2.38 to 3.87 GHz. The band-notching is achieved by adding an inner chorded crescent element within a driven element of a similar shape. By varying the value of the varactor which is placed between the inner and outer arcs, the desired variable rejected can be obtained. Simulated and measured results show wide impedance bandwidth with a tunable band notch, stable radiation patterns, and consistent nearly constant gain. The antenna is suitable for mobile and portable applications.

Wideband antenna

Tunable notch

Varactor diode

Monopole antenna

A compact wideband printed antenna for free-space radiometric detection of partial discharge

Zhang, Y., Lazaridis, P., Abd-Alhameed, Raed, Glover, Ian A.

January 2016

Yes / A microstrip line-fed wideband printed antenna is presented for radio detection of partial discharge (PD). The novel simple structure antenna has compact size of 24 × 20 × 0.16 cm3 (0.28λs × 0.23 λs × 0.002 λs) and suitable for radiometric PD wireless sensor nodes, where λs is the wavelength of the lowest frequency of the band (i.e., 0.35 GHz). The stepped and beveled radiation patch is used in combination with a slotted ground plane to achieve a wide fractional bandwidth of 119% (0.35 to 1.38 12 GHz) for a return loss better than 10 dB. Good radiation pattern characteristics are obtained across the frequency band of interest. The match between simulated and experimental results suggests that the design is sound and robust.

Dielectric resonator antenna design for lower-UWB wireless applications

Elmegri, Fauzi, See, Chan H., Abd-Alhameed, Raed, Excell, Peter S.

January 2013

No / A small dielectric resonator antenna has been designed for ultra wideband (UWB) communication system applications. The antenna element is a rectangular low permittivity ceramic block, with a dielectric constant of 9.4, and the modified T-shaped feed network includes a 50 ohm microstrip line to achieve strong coupling, and some bandwidth enhancement. The antenna performance is simulated and measured over a frequency band extending from 3100 MHz to 5500 MHz; the impedance bandwidth over this interval is 55.8% with VSWR <; 2, making the antenna suitable for UWB applications.

Microstrip feed

Dielectric resonator antenna

DRA

Ultra wideband

UWB

A design procedure for a 1-to-4 Ultra-Wideband Wilkinson power divider

Ali, Ammar H., Abd-Alhameed, Raed, Hu, Yim Fun, Child, Mark B.

11 1900

No / The design of a physically small, equal phase and equal power, 1-to-4 ultra-wideband Wilkinson power divider is presented. Initially, a 1-to-2 divider was designed and optimized for the 3.1 GHz-to-10.6 GHz range. The 1-to-4 divider was then realized using three 1-to-2 dividers, and further optimized for full band insertion loss, return loss, and isolation. The circuits were constructed using a 0.75 mm thick Rogers RO3035 substrate, and experimentally validated.

CROSS LAYER TECHNIQUES TO ENHANCE LINK PERFORMANCE IN WIRELESS NETWORKS

SINGH, DAMANJIT

January 2007

No description available.

Wireless Networks

Ultra-wideband networks

Cross layer techniques

link adaptation