UUnniivveerrssiittyy ooff MMaassssaacchhuusseettttss AAmmhheerrsstt SScchhoollaarrWWoorrkkss@@UUMMaassss AAmmhheerrsstt Doctoral Dissertations Dissertations and Theses March 2016 AApppplliiccaattiioonnss iinn LLooww--PPoowweerr PPhhaasseedd AArrrraayy WWeeaatthheerr RRaaddaarrss Robert A. Palumbo Jr University of Massachusetts Amherst Follow this and additional works at: https://scholarworks.umass.edu/dissertations_2 Part of the Signal Processing Commons RReeccoommmmeennddeedd CCiittaattiioonn Palumbo, Robert A. Jr, "Applications in Low-Power Phased Array Weather Radars" (2016). Doctoral Dissertations. 594. https://doi.org/10.7275/8212306.0 https://scholarworks.umass.edu/dissertations_2/594 This Open Access Dissertation is brought to you for free and open access by the Dissertations and Theses at ScholarWorks@UMass Amherst. It has been accepted for inclusion in Doctoral Dissertations by an authorized administrator of ScholarWorks@UMass Amherst. For more information, please contact [email protected]. APPLICATIONS IN LOW-POWER PHASED ARRAY WEATHER RADARS A Dissertation Presented by ROBERT A. PALUMBO Submitted to the Graduate School of the University of Massachusetts Amherst in partial fulfillment of the requirements for the degree of DOCTOR OF PHILOSOPHY February 2016 Electrical and Computer Engineering © Copyright by Robert A. Palumbo 2016 All Rights Reserved APPLICATIONS IN LOW-POWER PHASED ARRAY WEATHER RADARS A Dissertation Presented by ROBERT A. PALUMBO Approved as to style and content by: Stephen J. Frasier, Chair Paul Siqueira, Member Michael Zink, Member Gopal Narayanan, Member Christopher V. Hollot, Department Head Electrical and Computer Engineering DEDICATION This is dedicated to my family, who has stuck by me for so long. And to Mikey, who is one of the few friends who hasn’t given up on me. Two roads diverged in a wood, and I took the one less traveled by, and that has made all the difference —Robert Frost ACKNOWLEDGMENTS First and foremost, I’d like to thank Raytheon for giving me the opportunity to workwitharadarsystemforsolongasIhave. It’saluxurythat’snotoftenaffordedin large companies, and I’m grateful to have been given the chance to prove myself. I’m very thankful to both Paul Ferraro and Christopher McCarroll from Raytheon, who got me started on my graduate career in Amherst and have done everything possible to keep me going. I’d also like to thank Ilene Hill and everyone in SRSI/SVTAD at Raytheon for being patient with me through my endeavors. The radar system wouldn’t nearly be this capable if it weren’t for the efforts of Ken Wood from Raytheon and Eric Knapp from the University of Massachusetts at Amherst. Thanks for the long days we spent trying to build and calibrate the first system and the months trying to commercialize and sell it internationally. I’d also like to thank the rest of the staff and students at the Microwave Remote Sensing Laboratory (MIRSL), who have provided a great learning environment with all the lab equipment and tools needed to get the job done. And special thanks to my advisor, Steve Frasier, for taking me on as a student and keeping me through the sometimes long months without contact. I appreciate all the support and effort from the engineers at FIRST RF Corpora- tion (Boulder, CO), specifically Luke Sankey, who have built an extremely capable, affordable, and commercialized phased array system. Thanks to Professor Douglas Gray and Waddah Al-Ashwal from the University of Adelaide (South Australia, AU), for the whirlwind of field experiments and trips we made in such a short time in Australia. That was one of the culminating experiences of my graduate career, and I’m grateful for all the help. vi Last, but not least, thanks to Richard Moro, Terry Kirn, and David Payne from AT and SED in Raytheon, who have done a great job in educating me in the finer points of radar program capture and marketing. It’s an often overlooked and under- appreciated task, but I’m grateful to be a part of it (and look forward to more future wins). vii ABSTRACT APPLICATIONS IN LOW-POWER PHASED ARRAY WEATHER RADARS FEBRUARY 2016 ROBERT A. PALUMBO B.Sc., RENSSELAER POLYTECHNIC INSTITUTE M.Sc., UNIVERSITY OF MASSACHUSETTS AMHERST Ph.D., UNIVERSITY OF MASSACHUSETTS AMHERST Directed by: Professor Stephen J. Frasier Low-cost X-band radars are an emerging technology that offer significant ad- vantages over traditional systems for weather remote sensing applications. X-band radars provide enhanced angular resolution at a fraction of the aperture size com- pared to larger, lower frequency systems. Because of their low cost and small form factor, these radars can now be integrated into more research and commercial ap- plications. This work presents research and development activities using a low-cost, X-band (9410MHz) Phase-Tilt Radar. The phase-tilt design is a novel phased ar- ray architecture that allows for rapid electronic scanning in azimuth and mechanical tilting in elevation, as a compromise between cost and performance. This work focuses on field studies and experiments in three meteorological appli- cations. The first stage of research focuses on the real-world application of phased array radars in forest fire monitoring and observation. From April to May 2013, a viii phase-tilt radar was deployed to South Australia and underwent a field campaign to make polarimetric observations of prescribed burns within and around the Adelaide Hills region. Measurements show the real-time evolution of the smoke plume dynam- ics at a spatial and temporal resolution that has never before been observed with an X-band radar. This dissertation will perform data analysis on results from this field campaign. Results are compared against existing work, theories, and approaches. In the second stage of research, field experiments are performed to assess the data quality of X-band phased array radars. Specifically, this research focuses on the mea- surement of and techniques to improve the variance of weather product estimators for dual-polarized systems. Variability in the radar products is a complicated rela- tionship between the radar system specifications, scanning strategy, and the physics governing precipitation. Here, the variance of the radar product estimators is mea- sured using standard radar scanning strategies employed in traditional mechanical antenna systems. Results are compared against adaptive scan strategies such as beam multiplexing and frequency diversity. This work investigates the improvement that complex scanning strategies offer in dual-polarized, X-band phased array radar systems. In the third stage of research, simulations and field experiments are conducted to investigate the performance benefits of adaptive scanning to optimize the data quality of radar returns. This research focuses on the development and implemen- tation of a waveform agile and adaptive scanning strategy to improve the quality of weather product estimators. Active phased array radars allow radar systems to quickly vary both scan pointing angles and waveform parameters in response to real- time observations of the atmosphere. As an evolution of the previous research effort, this work develops techniques to adaptively change the scan pointing angles, trans- mit and matched filter waveform parameters to achieve a desired level of data quality. Strategies and techniques are developed to minimize the error between observed and ix