Horus—A Fully Digital Polarimetric Phased Array Radar for Next-Generation Weather Observations

Palmer, Robert D.; Yeary, Mark; Schvartzman, David; Salazar-Cerreño, Jorge L.; Fulton, Caleb F.; McCord, Matthew; Cheong, Boon Leng; Bodine, David J.; Kirstetter, Pierre‐Emmanuel; Sigmarsson, Hjalti H.; Yu, Tian-You; Zrnić, Dúsan S.; Kelley, Redmond; Meier, John; Herndon, Matthew

doi:10.1109/trs.2023.3280033

Cited by 30 publications

(3 citation statements)

References 100 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…PPC+ has been recently implemented as a software update on PX-1000, and data processed using it can be visualized through the RadarHub (https://radarhub.arrc.ou.edu), offering a variety of practical examples of the performance of PPC+ in different weather scenarios. It has also been implemented in Horus, an all-digital phased array radar recently completed at the ARRC [19][20][21]. The implementation of PPC+ in PX-1000 and Horus is a signifcant contribution since one of the takeouts of this work is that PPC+ can be easily implemented on any radar without any hardware modifcations and with good…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Improvements in the Compression Filter and Calibration Factor of the Progressive Pulse Compression Technique

Salazar,

Cheong,

Palmer

et al. 2024

IEEE Trans. Geosci. Remote Sensing

Self Cite

View full text Add to dashboard Cite

Progressive Pulse Compression (PPC) was introduced to mitigate the need for a fll pulse in pulse-compressionbased radar systems. It provides a method for recovering signals in the blind-range region created by the transmission of relatively long pulses. However, the initial implementation of PPC has limitations that need to be addressed for it to be more useful for meteorological applications. The proposed updated algorithm, named herein PPC+, brings signifcant improvements to mitigate these limitations. The methodology of PPC+ is similar to that of PPC, except that it uses a set of improved pulse compression flters. The improved compression flters are designed based on an amplitude modulation approach and are generated by multiplying the original flter by a range-dependent window. The window can be divided into two sections, the frst part has a number of nulled samples used for mitigating the mainlobe migration, and the remaining portion is a number of tapered samples to alleviate the "shoulder" effect from range sidelobes. Also, in contrast to PPC, the calibration factor used in PPC+ is further tuned to account for the tapering used in the improved compression flters. The PPC+ technique has been tested using data collected with PX-1000, a polarimetric X-band transportable solid-state radar system designed and operated by the Advanced Radar Research Center (ARRC) at the University of Oklahoma, and it is implemented and operational on that system (data available at https://radarhub.arrc.ou.edu). This technique has also been implemented on Horus, a fully digital phased array radar recently completed at the ARRC.

show abstract

Section: Discussionmentioning

confidence: 99%

“…Real-time and archived polarimetric variable felds processed with PPC+ are available through the RadarHub (https://radarhub.arrc.ou.edu), since July 2023. The PPC+ technique has also been implemented in the Horus system, a state-of-the-art fully digital phased array radar recently completed at the ARRC [19][20][21].…”

mentioning

confidence: 99%

Improvements in the Compression Filter and Calibration Factor of the Progressive Pulse Compression Technique

Salazar,

Cheong,

Palmer

et al. 2024

IEEE Trans. Geosci. Remote Sensing

Self Cite

View full text Add to dashboard Cite

show abstract

“…Therefore, DBF can sample a large sector of the atmosphere with an improved temporal resolution by reducing the need for mechanical rotation [4]. The "Horus" radar is a fully digital, S-band, polarimetric PAR that was developed by the Advanced Radar Research Center (ARRC) at the University of Oklahoma, and funded by the National Oceanic and Atmospheric Administration (NOAA) [5]. It is a rotating PAR (RPAR) that can steer the beam electronically in the elevation and/or azimuth and rotate mechanically in the azimuth.…”

Section: Introductionmentioning

confidence: 99%

Fast Adaptive Beamforming for Weather Observations with Convolutional Neural Networks

Kim,

Schvartzman,

et al. 2023

Remote Sensing

Self Cite

View full text Add to dashboard Cite

Polarimetric phased array radar (PAR) can achieve high temporal resolutions for improved meteorological observations with digital beamforming (DBF). The Fourier method performs DBF deterministically, and produces antenna radiation patterns with fixed sidelobe levels and angular resolution by pre-computing the beamforming weights based on the geometry of receivers. In contrast, the Capon method performs DBF adaptively in response to the changing environment by computing the beamforming weights from the received signals at multiple channels. However, it becomes computationally expensive as the number of receivers grows. This paper presents computationally efficient adaptive beamforming with an application of convolutional neural networks, named ABCNN. ABCNN is trained with the phase and amplitude of complex-valued time-series IQ signals and the Capon beamforming weights as input and output. ABCNN is tested and evaluated using simulated time-series data from both point targets and weather scatterers for a planar of fully digital PAR architecture. The preliminary results show that ABCNN lowers computation time by a factor of three, compared to the Capon method, for a phased array antenna with 1024 elements, while mitigating the contamination from sidelobes by placing nulls at the location of the clutter. Furthermore, ABCNN produces antenna patterns similar to those from the Capon method, which shows that it has successfully learned the data.

show abstract

Meteorological Observations

Sene

2024

Hydrometeorology

View full text Add to dashboard Cite

Horus—A Fully Digital Polarimetric Phased Array Radar for Next-Generation Weather Observations

Cited by 30 publications

References 100 publications

Improvements in the Compression Filter and Calibration Factor of the Progressive Pulse Compression Technique

Improvements in the Compression Filter and Calibration Factor of the Progressive Pulse Compression Technique

Fast Adaptive Beamforming for Weather Observations with Convolutional Neural Networks

Meteorological Observations

Contact Info

Product

Resources

About