Department of ECE Overview of Present and Recent Research Projects http://www.egr.uh.edu/ael/
EM Faculty Ji Chen Ph.D. 1998 U. Illinois David Jackson Ph.D. 1985 UCLA Stuart Long Ph.D. 1974 Harvard Don Wilton Ph.D. 1970 U. Illinois Ji Chen David Jackson Stuart Long Don Wilton
Computational ElectroMagnetics One of the most significant challenges in computational electromagnetics (CEM) is the development of powerful simulation tools that can model very large and complex structures such as an entire ship! Navy Destroyer Induced Currents The Applied Electromagnetics group has played a key role in developing a powerful CEM simulation tool called EIGER (Electromagnetic Interactions GEneRalized). The figures above show a Navy Destroyer being modeled with EIGER. The icons below show the participating team members who have developed EIGER (Lawrence Livermore National Laboratory, Sandia National Laboratory,, SPAWAR (Navy), NASA, and ANT-S).
Time-Domain EM Modeling and Applications Time-domain EM modeling tools provide capability for transient and harmonic electromagnetic analysis for complex geometries. Application areas include nanoscale EM effects and the design of medical devices. Nano-scale FSS modeling medical safety in MRI Design of periodic structures y W L PEC patches wireless safety and propagation study h ε r a silver substrate x aperture
Amplitude (ma) Applied Electromagnetics Laboratory High-Frequency Effects High-frequency effects that occur on microwave integrated circuits are of increasing concern. At high frequency leaky modes (radiating types of modes) may be excited, resulting in significant interference and other effects. ε r w side view h The figure on the left shows a microstrip line, a typical structure for which leaky modes may be excited at high frequency. The figure at the bottom left shows that a leaky mode (red curve) exists above about 27 GHz. Because of the leaky mode, a large amount of interference effects are observed at higher frequencies in a plot of the current on the line versus distance from a gap voltage source, as seen in the figure on the lower right. Normalized Phase Constant 1.45 1.4 1.35 LM 1.3 RIM 1.25 TM0 BM 1.2 1.15 1.1 1.05 1 0.95 0 10 20 40 50 60 70 80 Freq (GHz) 5.8 5.6 5.4 5.2 5 4.8 4.6 4.4 4.2 4 3.8 3.6 0 1 2 3 4 5 6 7 8 z/λ0 Total Current 1GHz 5GHz 10GHz 20GHz 40GHz
Microstrip Antennas Microstrip antennas are commonly used at microwave frequencies due to their low-profile nature, simplicity, small size, and low cost. They can be easily manufactured by using photolithographic techniques. 0 - feed E-plane circularvias 60-10 -20 - -60 aρ o b H-plane 90 120-40 - -20-10 Measurement Theory 240-90 150 210 180 RSW Microstrip Antenna The example shown here is a type of microstrip antenna called the Reduced Surface Wave (RSW) antenna. It has low levels of radiation at the horizon, making it well-suited for applications such as GPS, where ground reflections could be a problem.
Dielectric Resonator Antennas These are efficient high-frequency antennas made from dielectric material, which eliminate the effects of conductor loss. A significant bandwidth enhancement has been achieved by properly dimensioning a cylindrical DRA. Aspect Ratio d/a 4 3.5 40 3 2.5 2 46 46 46 20 10 10 20 1.5 40 1 0.7 2 3 4 5 6 7 8 9 10 ε r 50 45 40 35 25 20 15 10 5 Impedance bandwidth (SWR 2.0)
Leaky-Wave Antennas Novel periodic leaky-wave antennas have been developed, which allow for a continuous beam scan from the backward region to the forward region. 3 0 15 0 5 60-5 270-15 -5 5 15 90 240 120 Realized Gain [db] 25 20 15 10 210 180 150 H-plane co-pol 9.90 GHz 9.95 GHz 10.00 GHz 10.05 GHz 10.10 GHz 10.15 GHz 10.20 GHz 5 0-5 -10-5 -4-3 -2-1 0 1 2 3 4 5 Angle away from broadside, θ [deg]
Two-Dimensional Leaky-Wave Antennas Leaky-wave antennas are simple structures that can provide highlydirective radiation patterns at microwave and millimeter-wave frequencies. 180 150 120 90-10 -20 - -40-50 -50-50 -40-60 -20 E-plane f=12ghz h=1.333cm for broadside h=1.9cm for scan 45 degree E broadside E-pane -10 0 210 3 patch array 3D view 240 270 0 substrate patch array feed antenna ground plane coax side view The above figure shows a planar leaky-wave antenna consisting of a periodic array of metal patches that is placed over a ground substrate. The structure is excited by a simple feed antenna.
Plasmon Enhanced Optics Plasmon-enhanced optics can be used to greatly increase the transmission of power through a small sub-wavelength hole in a metal film. It can also be used to create very narrow beams of light from a small hole. 60 0 silver h 90 270 a 180 150 120 210 0 3 Direct Source Field Periodic Structure Field Total Field 240 In the structure shown above on the left, a periodic structure is shown on the exit side of a metal (silver) film, surrounding a small hole in the film. The use of such periodic structure can create a sharp beam in the exit region, as shown in the figure on the right.
Wireless Power Transmission Wireless power transmission is being explored for geophysical applications. Power is transmitted wirelessly from a transmit coil to a receive coil, in order to power a sensor underground.