A Polarization Reconfigurable Low-Profile Ultrawideband VHF/UHF Airborne Array for Fine-Resolution Sounding of Polar Ice Sheets

Yan, Jiahao; Hale, Richard; Mahmood, Ali; Rodriguez‐Morales, Fernando; Leuschen, C.; Gogineni, S.

doi:10.1109/tap.2015.2456974

Cited by 17 publications

(7 citation statements)

References 13 publications

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“…This work develops a new class of low cross-polarization, ultra-wideband (UWB) electronically scanned arrays (ESA) to meet the needs of modern multifunctional RF systems [1], high-throughput or low-power communication systems [2][3][4], high resolution radars and sensing imagers [5][6][7][8], polarimeters and radio telescopes [9][10][11], and electronic warfare systems [12][13][14]. Although a number of accomplished UWB-ESAs have been proposed over the past decades [15][16][17][18][19][20][21][22][23] Most high-efficiency (low-loss) UWB-ESA apertures, certainly those that archive BWRs wider than 6:1 such as the Vivaldi array [24], are subject to an inherent bandwidth versus cross-polarization trade-off.…”

Section: Problem Statementmentioning

confidence: 99%

“…(1.23)) and thus the ability to correct the receiver system cross-polarization. As discussed in Section 1.2, IXR is a measure of the resulting polarimeter calibratability, and is directly related to the degree of orthogonality between the dual-polarized channels 5 . As a result, low antenna array CPR is an extremely important factor to ensure good IXR (and high channel orthogonality) for high measurement accuracy.…”

Section: Radars and Sensingmentioning

confidence: 99%

“…A dual-polarized 9:1 Vivaldi array was recently used for full polarimetric airborne measurements of snow-over-sea-ice [6]. 5 It is noteworthy to point out that IXR is invariant to the incident polarization coordinate system and the calibration procedure by nature of its definition, unlike typical cross-polarization FoMs used in dual-polarized communication systems that will inevitably change due to such factors like CPR, XPD, XPI, etc. …”

Section: Radars and Sensingmentioning

confidence: 99%

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Low Cross-Polarization Vivaldi Arrays

Logan

Kindt

Vouvakis

2018

IEEE Trans. Antennas Propagat.

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ACKNOWLEDGMENTSI would like to begin by extending my gratitude for having the opportunity and privilege to study under the guidance of my advisor, Prof. Marinos Vouvakis, over the course of five years for my Master's and PhD research. His energy, drive, and motivation to not only teach but also to stimulate critical thinking, to invoke a practical mindset, and to create with meaning have left me with invaluable principles. I am indebted to him for challenging me and his endless patience and support throughout this research.I'd like to also thank Prof. Do-Hoon Kwon and Prof. Gopal Narayanan for serving on my dissertation committee and providing many insightful comments and support.I would like to additionally extend my gratitude to Prof. Robert Jackson, Prof.Paul Siqueira, and Prof. Joseph Bardin for serving on my research qualifying exam committee. Also, although I never had the pleasure of having him as a professor at UMass, I'd like to thank Prof. Dan Schaubert for taking the time to inadvertently introduce Vivaldi arrays to a curious kid at a phased array conference nearly six years ago; likewise thanks to Prof. Jorge Salazar for seeing some potential in that kid to encourage him to apply for graduate study at UMass. I appreciate it greatly. Ultra-wideband (UWB) electronically scanned arrays (ESA) with high efficiency, excellent polarization agility, and wide-scan matching remain essential for servicing multifunctional RF front-ends and other communications, sensing, and jamming or countermeasure systems. To this day, the most popular antenna array element in modern UWB-ESA systems is the Vivaldi, or flared notch, due to its superior widescan wide impedance bandwidth, well-known design guidelines, and practical embodiment versatility. Despite their popularity, these arrays tend to radiate unacceptably high cross-polarization levels, thus encouraging a great research opportunity.This dissertation presents the theory and design of a new class of UWB-ESAs, termed Sliced Notch Antenna (SNA) arrays, that remedy the high cross-polarization problems in Vivaldi arrays while maintaining their desirable impedance performance.The critical enabling insight of this work lays in revealing the nature of polarization viii purity or cross-polarization ratio (CPR) degradation in Vivaldi arrays to arise from a highly imbalanced ratio of longitudinal and transverse currents within the element.This work introduces a novel design strategy that intrinsically balances these currents over a UWB operating band, achieving decade-order (10:1) bandwidths and low cross-polarization. Moreover, the design approach is simple, intuitive, and can be implemented in a manner that does not inflate cost expenditures. In fact, the proposed topology can facilitate significantly reduced costs and manufacturing times

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Section: Problem Statementmentioning

confidence: 99%

Section: Radars and Sensingmentioning

confidence: 99%

Section: Radars and Sensingmentioning

confidence: 99%

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Low Cross-Polarization Vivaldi Arrays

Logan

Kindt

Vouvakis

2018

IEEE Trans. Antennas Propagat.

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“…The polarization of each antenna element can be individually reconfigured depending on the target of interest. Details on the antenna array design as well as laboratory measurements of the array performance can be found in [3].…”

Section: Antenna Array and In-flight Radiation Pattern Measurementsmentioning

confidence: 99%

Multi-channel ultra-wideband radar sounder and imager

Hale

Miller

Gogineni

et al. 2016

2016 IEEE International Geoscience and Remote Sensing Symposium (IGARSS)

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In this paper, we present the development of a multi-channel VHF/UHF ultra-wideband airborne radar sounder and imager for measurements of polar ice sheets. The radar was developed at the Center for Remote Sensing of Ice Sheets (CReSIS) for operation onboard the German Alfred Wegener Institute (AWI) Basler BT-67 aircraft. The system operates from 150 to 600 MHz corresponding to a vertical resolution of 33 cm in free space. The radar is equipped with three 4-m long 8-element antenna subarrays installed under the fuselage and both wings to support 8 transmit and 24 receive channels. The radar waveform from each transmit channel can be configured individually to enable real-time transmit beamforming for wide-swath ice bed imaging of up to 10 km wide. The radar system was deployed to Greenland in the spring of 2016 as a part of the joint AWI/CReSIS test campaign to conduct measurements over glaciers. Sample radar data from this field campaign are presented to illustrate the capability of the radar.

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“…Antenna polarization, pattern, and frequency can be adjusted to meet application needs. Principle antenna tuning mechanisms include diodes, varactors, RF switches, and MEMS switches . To cope with diversified band allocations of modern wireless standards, numerous frequency reconfigurable designs are devised for handsets .…”

Section: Introductionmentioning

confidence: 99%