Chairs: Tim Hancock, Raytheon Technologies; James Wilson, DARPA

8:00 AM – 5: UWB Hemispherical Vivaldi and BAVA Arrays for Wide Angle Scanning

Carl Pfeiffer (Air Force Research Laboratory)*; Jeffrey Massman (Air Force Research Laboratory)

We report the first ultra-wide band (UWB) arrays on a doubly curved surface for wide angle electronic scanning. Two different prototypes are developed employing Vivaldi antennas and balanced antipodal Vivaldi antennas (BAVAs) distributed over the surface of a hemisphere. The arrays employ 52 dual-polarized elements. Unit cell simulations demonstrate a good impedance match from 2-12 GHz, and finite array simulation have a realized gain that is within 1 dB of theory. The antennas and are metal 3D printed from titanium. Measurements of the arrays will be reported at the conference.

8:20 AM – 147: Low-Power K/Q-Band Digital Phased Array Chiplet

Craig A Hornbuckle (Jariet Technologies, Inc.)*; Eric Mrozek (Jariet Technologies, Inc.); Marcel Lugthart (Jariet Technologies, Inc.); Thomas Krawczyk (Jariet Technologies, Inc.)

The DARPA Millimeter Wave Digital Arrays (MIDAS) program has developed an extremely low-power integrated circuit (IC) operating from 18 to 50 GHz for use in a tiled Active Electronically Scanned Array (AESA) implementation. Each chiplet provides thirty-two transmit and thirty-two receive channels with partial beamforming in the digital domain, supporting dual-polarized operation over sixteen antenna elements with very high dynamic range. This chiplet is designed such that multiple copies of the higher-level tile assembly may be formed into arrays of an arbitrary size through abutment. This paper will describe the architecture, implementation, and performance for this ground-breaking CMOS monolithic device. Descriptions of the key circuit blocks are included as well as the simulated performance of key sub-circuits.

8:40 AM – 157: MIDAS mmW Aperture

James McSpadden (Raytheon Technologies)*; Jason Milne (Raytheon Technologies)

Raytheon Technologies teamed with Michigan State and Teledyne Scientific present a 16-element scalable AESA building block consisting of high efficiency InP HBT power amplifiers (PAs), low noise figure InGaAs HEMT Low Noise Amplifiers (LNA) with integrated T/R switches, a high-density tile interposer containing the TA1 Digital Tile, and wideband antenna to meet the MIDAS TA2 program goals. The architectural, device, and assembly technology choices are presented with Phase 1 results.

9:00 AM – 156: MIDAS Wideband mmW Digital Tile

James McSpadden (Raytheon Technologies)*; Lawrence Kushner (Raytheon Technologies)

Raytheon Technologies teamed with Michigan State University and Teledyne Scientific present a zero-IF, mixed-signal, 32-channel millimeter-wave CMOS transceiver design developed under the DARPA/MTO MIDAS program. The architectural choices, design overview, and measured results from two generations of ASIC development are presented. As part of the MIDAS 3D T/R module, element-level digital beamforming provided by this ASIC will allow multiple simultaneous beams over a wide field of regard.

9:20 AM – 142: An 18-50 GHz RF-CMOS Transmitter Front-End for a Digital Phased Array System

Shih-Chang Hung (Michigan State University)*; Asad Ali Nawaz (Michigan State University); Matt Hodek (Michigan State University); John Albrecht (Michigan State University); Sang-Min Yoo (Michigan State University)

An ultra-wideband 18–50 GHz millimeter-wave (mm-wave) transmitter is presented. The proposed mm-wave transmitter is designed for compact size and low-power consumption, and it is suitable for an element-level digital phased array system. The fully-integrated transmitter includes buffers, cascaded baseband amplifiers with sharp roll-off, a local oscillator (LO) driver, a broadband coupled line coupler, and a stacked active mixer fabricated in a 45-nm SOI CMOS process. The cascaded Sallen-Key filters are implemented to provide sharp roll-off to remove the aliasing tones from the DACs and have moderate gain to reduce the gain required of the following mixer and PA stages. The LO driver is paired with a differential broadside coupler to generate the differential in-phase (I) and quadrature (Q) LO signals locally to ensure abrupt switching of the mixer. The phase imbalance of the I and Q LO signals can be tuned out by the tunable resistance at the isolation port of the broadside coupler. The stacked double-balanced active mixer mitigates the requirement for bulky inductors between transmitter building blocks. This allows the whole transmitter to be implemented within a limited area much smaller than the array spacing to allow area for other chip functions. The resulting transmitter has a compact chip area of 0.550.85 mm2 including pads. The prototype demonstrates a maximum 14.8-dB power gain and excellent gain flatness across the frequency range of interest.

9:40 AM – 155: Millimeter Wave Digital Arrays (MIDAS) TA2: Millimeter-Wave Scalable Unconstrained Broadband Arrays (MMW SCUBA)

Josephine Chang (Northrop Grumman Mission Systems)*; Ryan Walsh (Northrop Grumman Mission Systems); Fadi Afiouni (Northrop Grumman Mission Systems); Sean McLoughlin (Northrop Grumman Mission Systems)

The Millimeter-Wave Scalable Unconstrained Broadband Array (MMW SCUBA) system leverages cutting edge chip integration, additive manufacturing, and packaging technology to realize an 18-50 GHz, dual-polarized, scalable phased array antenna with element-level digital beamforming. We report on the demonstration and test of a 16 element free-space-to-RF prototype, as well as progress on the development of a larger 64 element array prototype build which extends integration from free-space to digits.

10:00 AM – BREAK

10:30 AM – 57: A New Phased Array Construct: Intra-element Monoliths Printed & Attached to a CircuiT board (IMPACT)

Victor C Sanchez (Jacobs Technology Inc)*

A new realization of broadband phased array is introduced. The structure consists of individual additively manufactured metallic radiating elements excited through coaxial apertures on a conventional printed circuit feed board. Metallic intra-element structures which we refer to as “monoliths”, include well-known broadband features such as a Vivaldi-like flare, tight capacitive coupling to neighboring elements, and built-in shorting posts to provide a balanced feed. The construct includes additional performance-enhancing RF features such as height-variable capacitance as well as RF-benign mechanical features which make the construct light weight, repeatable, and suitable for automated pick-and-place fabrication.

10:50 AM – 71: Demonstration of X-Band Wideband Scanning Using Hybrid Beam Steering Components

Virendra Kumar (Defence Research and Development Organisation(DRDO))*; Shreeshail . (Defence Research and Development Organisation(DRDO)); Srinivas D (Defence Research and Development Organisation(DRDO)); Pramod Kumar (Defence Research and Development Organisation(DRDO)); K SREENIVASULU (DRDO); Beenamole KS (Defence Research and Development Organisation(DRDO)); Ravi Gangwar (IIT(ISM) Dhanbad)

This paper demonstrates the use of hybrid beam steering components for wideband electronic scanning. A uni- directional multifunction monolithic microwave integrated circuit (MMIC) core chip is combined with three numbers of single pole double throw (SPDT) switches to realize bi-directional TTD units for transmit and receive operation. The realized bi-directional TTD unit is characterized by its functionality at the four-element subarray for true-time delay beam steering. The 6-bit digitally controlled phase shifters and a 6-bit true-time delay (TTD) units are used in a hybrid configuration to realize an X- band wideband 16-element linear array. The element level phase delay (limited to a maximum 360 deg) and subarray level time delay in steps of 3.125 ps (maximum delay of 197ps) is applied for the array calibration and beam steering. The radiation pattern is measured at the center operating frequency f0, and the beam is steered at f0 + 0.5 GHz to validate squint-free beam scanning. The proposed configuration with a two-stage hybrid phase/time delay demonstrates the wideband beam steering and eliminates the beam squint for wide instantaneous signal bandwidth for high- resolution imaging active phased array radars.

11:10 AM – 77: Development of Balanced TCDA for MFAs

Alexander D Johnson (BAE Systems)*; Jacob Tamasy (BAE Systems); James Fung (BAE Systems Inc); Benjamin Mcmahon (BAE Systems Inc)

Multifunctional arrays (MFAs) are widely used in RF sensing, radar, and communications applications. Advancements in packaging technologies, high data rate converters, and ultra-wideband (UWB) RF electronics have enabled the proliferation of such systems. Another key enabler of the MFA is the advent of powerful electromagnetic software that allows for the design of novel UWB array apertures. In this paper, we present a new addition to the tightly coupled dipole array (TCDA) family of UWB array apertures. The presented balanced TCDA retains higher bandwidth, lower costs, better polarization purity, and lower volumes than current aperture solutions.

11:30 AM – 118: An Ultra-Wideband Fully-Planar Inverted-L Monopole (FILM) Array

Muhammad Hamza (Florida International University)*; Constantinos L. Zekios (Florida International University); Stavros Georgakopoulos (Florida International University)

A new ultra-wideband array is introduced, called the fully-planar inverted-L monopole (FILM) array. The proposed array is the first ever reported tightly coupled monopole array (TCMA). Our FILM array provides a unique solution to realize ultra-wideband tightly coupled apertures in the W and higher millimeter wave (mmWave) bands. The unit-cell architecture of the infinite FILM array is comprised of an inverted-L shaped monopole, and a capacitively coupled via-fence. This novel design eliminates the well-known broadside null from the radiation pattern of the traditional monopole element, and pushes both the common mode and loop mode resonances out of the band. To improve the impedance bandwidth and scanning ability, a dielectric-based superstrate is also used. The proposed array is extremely low profile with a maximum thickness of 0.4λ_H . Infinite array simulations of our array demonstrate a bandwidth of 3:1 (33 GHz to 101 GHz) with VSWR<3 for a maximum scan-angle of ±45 for all principal E-, H- and D-planes.

Chairs: Mark Yeary, Oklahoma State University; Caleb Fulton, Oklahoma State University

8:00 AM – 176: Analysis and Mitigation of the Reflected Power on an S-band Planar Phased Array Antenna Transmitting in a Wet Spherical Radome 

Christine PARRY (MIT Lincoln Laboratory)*; Alan Fenn (MIT-LL); Alexander F Morris (MIT Lincoln Laboratory); Henry Thomas (MIT Lincoln Laboratory)

An active S-band dual-polarized multifunction phased array radar, the Advanced Technology Demonstrator (ATD), has recently been developed for weather sensing and aircraft surveillance. The ATD is a 4-m diameter active electronically scanned array (AESA) with 4864 transmit/receive (T/R) modules was installed in a spherical radome. Simulations and a novel phased array measurement technique have been explored to assess the impact of high reflectivity from a wet radome during rain that can potentially induce voltages exceeding the transmit amplifier breakdown voltage. Simulations show that when the radome surface is wet and highly reflective due to lack of hydrophobicity, certain electronic steering angles sum to a large reflected signal focused on the array face. The measurement technique uses array elements radiating one at a time to illuminate the radome in dry and wet conditions, and uses superposition to quantify the received signal power in a reference antenna on the face of the array. This measurement technique is being used prior to high-power phased array radar operation to monitor the magnitude of reflections and help avoid element transmit amplifier failures.

8:20 AM – 25: Design of a Dual-Polarized Low Sidelobe Slotted Waveguide Antenna for C-Band Phased Array Weather Radar

Takashi Uno (Mitsubishi Electric Corporation)*; Takashi Uesaka (Mitsubishi Electric Corporation); Narihito Nakamoto (Mitsubishi Electric Corporation); Toru Fukasawa (Mitsubishi Electric Corporation); Toru Takahashi (Mitsubishi Electric Corporation); Yoshio Inasawa (Mitsubishi Electric Corporation); Takeshi Yamamoto (Mitsubishi Electric Corporation); Tomoyuki Koyanagi (Mitsubishi Electric Corporation); Ikuya Kakimoto (Mitsubishi Electric Corporation); Yoshihiko Konishi (Hiroshima Institute of Technology)

This paper presents a dual-polarized low sidelobe slotted waveguide array antenna manufactured by resin injection molding for a C-band phased array weather radar. A slotted waveguide array has high efficiency and low cross-polarization, but it is generally manufactured by metal machining process, which increases its weight and cost. To solve the problems, the developed antenna is made by manufacturing approach that combines resin injection molding and plating. The vertically-polarized (V-pol.) and horizontally-polarized (H-pol.) antennas are a single-ridged slotted waveguide array and an edge-slotted waveguide array, respectively. In this paper, we focus on the V-pol. antenna, and simulation shows that −32.5 dB sidelobe level is obtained for the array, and the bandwidth with the active reflection coefficient less than −10 dB is 3.6%.

8:40 AM – 56: Untapped Capabilities of the Advanced Technology Demonstrator at the National Severe Storms Laboratory

Sebastian Torres (University Of Oklahoma)*; Christopher Curtis (University Of Oklahoma)

The Advanced Technology Demonstrator (ATD) is located in Norman, Oklahoma and is the first full-scale, S-band, dual-polarization, active, electronically scanned phased-array radar (PAR) for weather observations. The ATD became operational in the spring of 2021 after reaching its Initial Operating Capabilities (IOC). Because the ATD IOC are somewhat limited, many untapped capabilities of the ATD will be demonstrated through a process of periodic software upgrades. Research conducted with the ATD will help determine the feasibility of PAR technology for the next generation of operational weather-surveillance radars in the US.

9:00 AM – 27: Effects of Horus Antenna Patterns on Polarimetric Weather Observations

Dusan Zrnic (NOAA/NSSL)*; David Schvartzman (Univ. of Okla., ARRC); José Díaz-Díaz (Johns Hopkins University – Applied Physics Laboratory); Bob Palmer (Univ. of Okla., ARRC); Alexander Ryzhkov (Univ. of Okla., CIWRO/NSSL)

The all-digital polarimetric Horus radar is being built by the Advanced Radar Research Center at the University of Oklahoma in collaboration with NOAA’s National Severe Storms Laboratory. The radar is destined for polarimetric observations of weather. Herein we discuss polarimetric characteristics of copolar and cross-polar patterns that are required to achieve satisfactory polarimetric measurement on weather radars. Among these are matching of the beam main lobes for the horizontal and vertical polarizations. Measurements on an 8×8 element panel of the Horus antenna are used to test the theoretical postulates.

9:20 AM – 47: UAS-Mounted FMCW Radar for Observation of Weather Events

Marshall Bruner (Colorado State University)*; Chandrasekar Venkatachalam (Colorado State University)

Frequency-modulated continuous wave (FMCW) radar has seen a significant increase in use due to its ability to operate in low-power and mobile environments suited for low peak power solid state transmitters. Though there are many current applications for the FMCW technique, the majority are focused on measuring “”hard”” targets (e.g., cars, humans, etc.) and it is not heavily used in the measurement of volume targets such as precipitation. Moreover, current FMCW radars used for volumetric measurements are generally focused on very specific use cases such as vertical profiling. This work presents DARMA, a low-power, dual-polarized, FMCW radar with a phased array antenna capable of being deployed on unmanned aircraft systems (UAS). It will be used to test the feasibility of measuring and classifying complex weather events on a mobile platform which will provide different perspectives at the lowest kilometer of precipitation volumes.

9:40 AM – 48: Cross-Polar Canceller (XPC): A Technique to Reduce Cross-Polar Pattern Contamination in Polarimetric Weather Observations

Cesar Salazar (Univ. of Okla., ARRC)*; David Schvartzman (Univ. of Okla., ARRC); Boon Leng Cheong (Univ. of Okla., ARRC); Bob Palmer (Univ. of Okla., ARRC)

“This paper proposes a novel technique to improve cross-polar isolation for polarimetric phased array antennas used for meteorological observations, referred to as cross-polar canceller (XPC). It is based on the use of canceller antenna elements transmitting a scaled version of the original waveform in the polarization where the cross-polar contamination is observed but with opposite phase. The technique involves calculating the correct number of canceller elements, their location in the array, and a scaling factor for the amplitude and phase of the selected canceller elements such that maximum cross-polar isolation is possible. It is intended for dual-polarization, fully digital, phased array radar systems. It can also be applied to sub-array architectures if amplitude and phase control is possible at the element level. Previous similar efforts illustrated the potential of this technique for the alternating transmission/reception of horizontally and vertically polarized waves. In this paper, we present progress towards using this technique for the simultaneous transmission/reception of horizontally and vertically polarized waves. Preliminary results show that this technique is capable to improve cross-polar isolation by 15 dB on average, at the cost of ∼0.32 dB loss in copolar pattern gain per canceller element used. The XPC technique is being implemented in the Horus system, an S-band, polarimetric, fully digital phased array system developed by the Advanced Radar Research Center (ARRC) at the University of Oklahoma (OU).
Index Terms—polarimetric phased array radar, cross-polarization, signal processing, weather radar, simultaneous H/V.”

10:00 AM – BREAK

10:30 AM – 59: Airborne Polarimetric Doppler Phased Array Weather Radar: Digital Twin of the Active Electronically Scanned Array

Jothiram Vivekanandan (N.C.A.R>)*; Adam Karboski (N.C.A.R.); Christtopher Burghart (National center for Atmospheric Research); Turing Eret (National center for Atmospheric Research)

A weather radar using an active electronically scanned array (AESA) enables rapid scanning of the antenna beam for Doppler and polarimetric radar observation measurements. An AESA consists of radiating elements, power amplifiers, attenuators, phase shifters, array controllers, and digital converters. This paper describes a digital twin, the AESA Simulator, which models both the AESA and weather radar returns, developed to explore and validate the optimal configuration of the APAR subsystems. Using a hybrid digital beamforming architecture, multiple, simultaneous receive beams are realized upon reception. Traditional analog beamforming will be performed along each row, while digital beamforming will be performed across the per-row outputs of the AESA. The simulator sums over a spatial grid, rather than using a prescribed antenna pattern, in order to support testing of multiple receive beams, clutter mitigation algorithms, and other developments that require accurate modeling of spatial diversity. The digital twin allowed NCAR/EOL to accelerate the timeline for engineering development of the APAR radar back end (RBE) and provides the necessary configurability to conform to the eventual AESA digital data acquisition and control interfaces as AESA and RBE development converge. Together the simulator and RBE are used to evaluate/validate the radar at the system level.

10:50 AM – 115: A Novel Portable Phased Array Radar for Meteorological Remote Sensing

Mohit Kumar (Agile RF Systems)*

“The Portable Weather Radar (PWR) demonstrates a robust radar system to substantially improve weather observation for the US Air Force (USAF). The PWR uses solid-state, distributed phased-array RF electronics, implemented as a hybrid phased array and mechanical spin, scanning system. PWR supports electronic scan in elevation and mechanical scan in azimuth to provide full hemispherical volumetric coverage for
weather surveillance. The phase-spin architecture removes a mechanical elevation gimbal to significantly decrease system costs and increase lifetime. Furthermore, the radar control the system utilizes a System on Chip (SoC) to leverage an embedded Linux platform for ease of use as well as dedicated custom FPGA logic for faultless real-time radar operations and data archiving. The radar data products are provided in a
variety of file formats for compatibility with open-source and proprietary weather forecasting software applications. PWR takes advantage of faster scan times in elevation using electronic beam scanning and simultaneously overcomes the inherent differences in the gain phase of these electronic elevations beams using precise calibration methods.”

11:10 AM – 58: Two-Way Pattern Synthesis for the Airborne Phased Array Radar (APAR)

Eric Loew (N.C.A.R.)*; Randy Haupt (Haupt Associates)

Airborne, atmospheric radars need to detect the presence of relatively weak weather echoes near the earth’s surface. In order to accomplish this, both antenna sidelobes and range-time sidelobes must be suppressed considerably. This paper focuses on antenna sidelobe suppression by means of using a genetic algorithm to optimize both the thinning of the transmit aperture and the receive taper simultaneously in order to get desirable two-way sidelobe levels.

11:30 AM – 20: Novel All-Digital Beamforming Techniques for L/S/C-Band Multi-Channel Systems Leveraging Hardened DSP on Integrated Circuits

Michael Jones (Analog Devices)*; Peter Delos (Analog Devices)

As data converter sample rates increase there is a push to quantify the feasibility of all-digital beamforming solutions in L/S/C-band and beyond. For those systems requiring multiple channels to achieve the performance required, measured data on both the individual and combined-channel transmitter and receiver performance using these new converters is warranted for system architects to derive the required system-level models. This paper discusses measured multi-channel phase noise, noise spectral density, linearity and spurious improvements when using a direct-S-band-sampled digitizer transceiver as the backbone of the design. Over-the-air all-digital beamforming is also demonstrated using the hardened DSP on these new digitizer integrated circuits.

11:50 AM – 26: A Polarimetric Antenna-Calibration Method for the Horus Radar based on E-Field Back Projection

David Schvartzman (Univ. of Okla., ARRC)*; José Díaz Díaz (Johns Hopkins University – Applied Physics Laboratory); Bob Palmer (Univ. of Okla., ARRC); Dusan Zrnic (NOAA/NSSL); Caleb Fulton (Univ. of Okla., ARRC); Jorge Salazar (Univ. of Okla., ARRC); Patrick Kenworthy (Univ. of Okla., ARRC)

Phased Array Radar (PAR) technology can provide tailored, high-quality meteorological observations and is rapidly rising as a candidate for future weather radars. To conduct precise measurements of polarimetric weather variables, it is desired that the radar transmits and receives linearly polarized horizontal (H) and vertical (V) fields through beams well matched in gain and shape at every scanning direction. These characteristics are difficult to achieve because the radiation patterns of phased array antennas inherently depend on polarization, beam shape, and gain in the intended pointing direction. Polarimetric array calibration is critical to produce symmetric and matched co-polar antenna patterns at the two polarizations. In this paper, we present a new polarimetric antenna calibration procedure for the all-digital Horus radar based on holographic back projection of electric fields. Near-field Horus measurements are back-projected onto the plane of the array to derive the co-polar magnitude and phase of the H/V fields radiated by each antenna element. Digital calibration parameters are derived from back-projected fields to compensate for excitation differences and produce uniform radiation at the plane of the array. Preliminary results show that through digital calibration based on back-projected fields, co-polar H and V beam matching can be considerably improved. This naturally improves polarimetric measurement accuracy of the Horus radar by mitigating antenna-induced biases in meteorological estimates.

Chairs: Glenn Hopkins, Georgia Tech Research Institute; Jacob Houck, Georgia Tech Research Institute

8:00 AM – 9: Flat-Top Beam Shaped Phased Array Design Using Multi-Beam Superposition

Wilfredo Rivas-Torres (Keysight Technologies Inc.)*; Murthy Upmaka (Keysight Technologies Inc.)

Several useful techniques are in use to shape Phased Array antenna patterns with optimized side lobe ratio (SLR) and wide beamwidth. The design commences with a spoiled beam Phased Array. The beam weights for the spoiled array can be obtained without using numerical optimization techniques inside an EDA tool. The beam flattening and array thinning are accomplished directly from windowing functions. A new flat-top beam shape design procedure is proposed and validated. Various studies are performed to account for the effects of different window functions, component variability, and beam scanning including a two-way beam pattern radar application.

8:20 AM – 35: True Time Delay line RFIC for X-band Timed Array Radars

K SREENIVASULU (DRDO)*; KP Ray (Department of Electronics Engineering, Defence Institute of Advanced Technology, Girinagar, Pune); Dr. Vengada Rajan (DRDO)

“In this paper, a naval design of RFIC based 4bit
True Time Delay (TTD) line circuit at X-band (8-12GHz) is
presented for wideband Timed Array Radar application. The
designed TTD line circuit is configured using eight numbers of
transmission line structures as 100ps delay element along with
distributed switching network to offer maximum time delay of
800ps. The circuit is implemented in a compact size of 25mm2
by using bulk 65nm CMOS technology. The size of the switches
and characteristic impedance of the transmission lines are scaled
optimally for low insertion loss variation across different delay
states, while maintaining flat delay performance over a wide
bandwidth. The designed circuit simulation demonstrated input
and output return loss of better than 10dB, insertion loss of
13.5dB 1dB and group delay variation of 6ps across 4GHz
bandwidth.”

8:40 AM – 44: A Composite Off-Axis Scan Method for Active Phased Array

Avnish Kumar (Indian Institute of Science, Bengaluru)*; Debasish Ghose (Indian Institute of Science); Abhijit Bhattacharyya (DRDL Hyderabad)

Phased Array Seekers (PAS) can be used to achieve longer tracking range in all-weather endo-atmospheric interceptors intended to engage long range ballistic targets or highly menuvering aerial targets. The Digital Phase Shifters (DPS) employed in PAS lead to quantization of scan steps which leads to beam pointing errors, off-boresight range losses, or poorer angular accuracies resulting in poorer engagement efficacies. In the classical phased array scanning methods, either an On-Axis target tracking is carried out over narrowly spaced beams, or a pure Off-Axis target LOS estimation is implemented over sparsely spaced ideal beams. Both the classical methods result in lower LOS confidence, the former due to the larger beam pointing errors, and the latter due the poorer off-axis estimation accuracies. This paper proposes a new idea of composite beamforming and scanning methodology. The proposed method uses a novel composite approach of formation of closely spaced phased array beams and implementation of the off-axis DOA estimation technique. The proposed method gives better accuracy in beam pointing, and better DOA estimation. In addition, the proposed approach has mathematical tractability which will help to avoid need of extensive seeker calibration and result in better angle accuracies as well. The proposed method has been integrated with the guidance algorithm to demonstrate its effectiveness during target homing.

9:00 AM – 165: Two-Dimensional Adaptive Beamforming Based On Atomic-Norm Minimization

Zeren He (Southeast University); Shengheng Liu (Southeast University)*; Xiaolong Miao (Southeast University); Yongming Huang (Southeast University)

Adaptive beamformers usually require a great number of snapshots to update the weight vectors for large phased array antennas and the training data can easily corrupted by target signals. These challenges hinder real-time applications and significantly degrade existing methods. In this context, we propose a two-dimensional (2-D) adaptive beamforming scheme based on atomic-norm optimization. The steering matrix is first reconstructed as a vector using Kronecker product. Then, the interference covariance matrix and target direction are estimated simultaneously by formulating an atomic-norm minimizing problem. This non-convex problem is solved efficiently using alternative optimization which decomposes it into two iterative stages. The proposed beamformer is free from the influence of target signals and able to adjust pointing direction adaptively. The superiority of the proposed method over other competitive methods are verified using numerical simulations.

9:20 AM – 65: Full 3D Coverage Beamforming Phased Array with Reduced Phase Shifters and Control 2D Tunable 3 × 3 Nolen Matrix

Hanxiang Zhang (Florida State University)*; Bayaner Arigong (Florida State University)

“In this paper, a 3D beamforming phased array with
2D stacked tunable Nolen matrix is presented. The fundamental
building block – tunable Nolen matrix is proposed to relax phase
tuning range of phased shifters and reduce the complexity of
control mechanism by embedding tunable phase shifters within
Nolen matrix. For each input port excitation of proposed tunable
Nolen network, a tunable progressive phase difference within
range of 120° is obtained at its output ports, and full 360° range is
achieved by exciting all three input ports. By stacking and
cascading six 3×3 Nolen matrices, nine radiation beams in unique
cubic sector can be continuously steered on azimuth and elevation
planes, realizing full 3D beamforming function. To verify the
design concept, the network has been simulated at 5.8GHz, and
the simulation results agree well with theoretical analysis”

9:40 AM – 81: Beamformer Calibration Using Coded Correlations

Zhangjie Hong (NC STATE UNIVERSITY)*; Brian Floyd (NC STATE UNIVERSITY)

Code-modulated embedded test (CoMET) has been investigated for simultaneous testing and calibration of phased-array elements using phase-shifter modulation and a single scalar detector together with an off-line equation solver. To improve the speed and reduce the complexity of the calibration, this work presents a revised methodology relying only on correlations and eliminating equation solvers within the calibration loop. The new technique, beamformer calibration using coded correlations (BC3), operates by calibrating the phased-array’s in-phase and quadrature-phase correlations between elements. Within BC3, a first method calibrates the array’s response by using two two-dimensional (2-D) correlations. A second method further reduces the total calibration time and improves accuracy by using two one-dimensional (1-D) correlations together with an empirical model to predict gain-dependent phase variation. Also, we investigate ways to improve the speed of calibration by reducing the code length and the number of searching states per iteration. The phase and gain accuracy, calibration time, and antenna beam patterns are measured and compared using original and proposed calibration methods on an eight-element receiver at 10 GHz. The most accurate BC3 method achieves 1.4 deg. and 0.23 dB root-mean-squared (RMS) phase and gain error, 1.1 dB maximum gain error and -37.8 dB calculated residual sidelobe level (RSL) for the calibrated array, with 12X speedup compared to CoMET. The fastest BC3 method achieves 2.1 deg. and 0.27 dB root-mean-squared (RMS) phase and gain error, 1.2 dB maximum gain error and -35.3 dB RSL for the array with 33X speed up compared to CoMET.

10:00 AM – BREAK

10:30 AM – 95: A Simple Analytic Technique for the Design of Linear Apertures Generating Piece-wise Polynomial Shaped Beams 

Giovanni Toso (European Space Agency)*

A simple technique for the synthesis of shaped beams defined by piecewise polynomial expressions is proposed. The technique, derived generalizing an algorithm previously introduced by Ksienski, provides a continuous linear tapering in analytical format. The technique can be used to preliminary assess the fundamental parameters of a shaped pattern i.e. the ripple within the beam, the slope at the end of the shaped region, and the sidelobe level. The obtained tapering can be used as an excellent starting point in a full wave numerical analysis where additional requirements and contributions, like the mutual coupling, can be rigorously evaluated. Several examples are presented to prove the simplicity and the effectiveness of the technique.

10:50 AM – 103: A New Class of Ultra-Wideband Beamforming Networks for sub-6 GHz Bands

Dimitrios Lialios (Florida International University)*; Constantinos Zekios (Florida International University); Stavros Georgakopoulos (Florida International University)

In this work, a novel beamforming scheme is introduced that covers the sub-6 GHz bands for both satellite and terrestrial communication systems. To achieve multi-octave performance, we adopt the concept of microwave photonics and we appropriately implement it in the microwave-millimeter waves (mmWaves) regime. Specifically, in our proposed network, the desired sub-6 GHz signals are first upconverted to a mmWave frequency band where the beamforming signal processing takes place. The resulting signals are then downconverted to their original frequency band before being fed to their corresponding antenna ports for transmission. To validate our concept, a novel analog beamformer is designed, fabricated and measured, and a virtual test-bed is designed and simulated. Based on our measured and simulated results we show that our beamforming network can support bandwidths up to 6:1, which to our knowledge are the highest reported in the literature.

11:10 AM – 163: Sidelobe Reduction and Mode-Purity Enhancement of Vortex Beams from a Programmable, Rectangular Phased Array Antenna

IAN R NEMITZ (NASA)*; Christine Chevalier (HX5, LLC); Ryan Toonen (NASA); Peter Schemmel (NASA)

Tapering the magnitude of the electric field excitation of a programmable, rectangular phased array has been employed to achieve sidelobe reduction and enhancement of mode purity in vortex beams, which carry non-zero orbital angular momentum. Far-field radiation patterns pertaining to a commercial-off-the-shelf, 256-element antenna were generated via electromagnetic simulation. The patterns were decomposed into weighted sums of Laguerre-Gaussian modes. The extracted coupling coefficients were used to gauge mode purity. In comparison to a uniform excitation of the phased array elements, our studies indicate that employing a tapering technique can result in a 10.7 dB reduction of sidelobe power and a 7.22 dB improvement in worst-case, mode-to-mode cross-talk

11:30 AM – 164: Joint Optimization of Transmitting and Multiple Receiving Beams within Overlapped Subarray Structure

Hui Zeng (National University of Defense Technology)*; Zhen Hai Xu (National University of Defense and Technology); Wei Dong (National University of Defense and Technology); Shun Ping Xiao (National University of Defense and Technology)

Overlapped subarray is an attractive structure to achieve low-cost multiple receive beams. However, satisfactory weights of overlapped subarray is hard to design, especially considering the transmit beam pattern. In this paper, a method to optimize the receiving excitation of overlapped subarrays on the basis of a given transmitting pattern is proposed. The relationship between the two-level weights and the two kinds of sidelobes is analyzed at first. Then, a squential convex programming stratagy is adapted to optimize the element-level and subarray-level weights jointly to match the pre-defined transmit beam pattern. The required multi-beam coverage region and minimal sidelobe level could be obtained after these steps. Numerical experiments are presented to verify the effectiveness of this method.

11:50 AM – 178: Large Scale Adaptive Beamforming

Michael A Parker (Raytheon)*; Michael Cervantes (Raytheon)

“Array antennas may be built with I/Q digital I/O
for each antenna element. Technology in data convertors and
digital signal processing components and packaging has
advanced sufficiently such that advanced algorithms may be
implemented in or adjacent to the array antenna. Digitization
down to the element level dramatically increases the array data
rates, but localized signal processing can significantly reduce
those data rates. However, the benefits of element level
digitization at or near the antenna can be achieved by
implementation of the algorithms in the FPGA.”

Chairs: Wajih Elsallal, MITRE; Pierre Dufillie, Raytheon

8:00 AM – 46: V-band Stacked Patch Phased Array

Pierre Dufilie (Raytheon Technologies)*; Elizabeth J Kowalski (MIT LL); M. David Conway (MIT Lincoln Laboratory); David Du Russel (MIT Lincoln Laboratory); Alan Fenn (MIT-LL)

MIT Lincoln Laboratory is developing a planar V-band phased array antenna. The radiator is required to provide 15% bandwidth with 30° elevation and 50° azimuth scanning capability with vertical polarization. Due to the high level of integration of the radiator and the RF front-end, the goal for the antenna array is to be integrated on printed circuit board (PCB) technology with the T/R module mounted on the opposing side. This design results in a very tightly integrated radiator and RF distribution network in a multi-layer PCB stack up that utilizes Ormet paste technology. A detailed description of the antenna array and RF feed network will be reviewed.

8:20 AM – 69: System-Level Model for mmWave-over-Fiber Distributed Antenna Systems

Arno Moerman (Ghent University)*; Olivier Caytan (Ghent University); Laura Van Messem (Ghent University); Igor Lima de Paula (Ghent University); Joris Van Kerrebrouck (Ghent University); Guy Torfs (Ghent University); Piet Demeester (Ghent University); Hendrik Rogier (Ghent University); Sam Lemey (Ghent University)

“A mmWave-over-fiber distributed antenna system (DAS), in combination with highly efficient air-filled substrate-integrated-waveguide (AFSIW) remote antenna units (RAUs), proves to be a prime candidate to counter the harsh propagation conditions that arise at mmWave frequencies. This paper proposes a system-level model to accurately analyze the link quality of a downlink mmWave-over-fiber wireless link in a time-efficient way.
The model includes a realistic antenna description, fiber losses, and non-linear effects of the opto-electrical/electro-optical transducers and the electrical amplifiers. This gives in-depth insight into the signal quality at each stage of the link and enables offline link optimization. In addition, the modular nature allows incorporating more advanced wireless channel models/measurements which can be used to optimize RAU placement in the future. Finally, the model is validated by means of a measurement campaign, demonstrating good agreement.”

8:40 AM – 97: Experimental Evaluation of a Variable Length Beam Selection Framework in a USRP based Testbed with mmWave Frontends and Butler Matrices

Mostafa Khalili Marandi (Technische Universität Dresden)*; Shizhang Wei (Technische Universität Dresden); Behnam Khodapanah (Technische Universität Dresden); Wolfgang Rave (Technische Universität Dresden); Gerhard Fettweis (TU Dresden)

In this work, we aim to experimentally evaluate the performance of the novel variable length beam selection framework known as the Sequential Competition and Elimination Test (SCET) in a realistic mmWave link. The experimental setup employs hardware in the loop including a pair of 16×16 Butler Matrices developed at TU Dresden which provides a codebook of orthogonal beams that are connected through an electronic switch to a single RF chain. We have designed multiple measurement scenarios in which beams with different main-lobe directions are automatically probed at the TX and RX through different channel realizations. The acquired measurements are processed in Matlab to benchmark the alignment accuracy and efficiency after beam selection. The results indicate the superior performance of the variable length detection framework for beam selection. SCET is adaptive to any channel realization while achieving a better efficiency/accuracy compared to the fixed-length test. Furthermore, it is resilient in the presence of hardware impairments and non-ideal pre-beamforming frequency and time synchronization.

9:00 AM – 102: Fast Beam Alignment Via True Time Delay Frequency Dependent Beamforming Using Fixed and Variable Length Tests

Christoph Jans (TU-Dresden)*; Wolfgang Rave (TU Dresden); Gerhard Fettweis (TU Dresden)

“In this work, we present a time efficient solution to the initial beam alignment/acquisition of a hybrid beamforming millimeter wave communication system.  Our proposal is based on adding a frequency dependent beamforming device at the transmitter which is capable of simultaneously testing all spatial angles and, therefore, any set of possible beamformers from an analog codebook. Such a device employed outperforms any kind of consecutive beamformer testing, e.g., exhaustive search, in terms of testing overhead and receive power loss after beamforming. To further increase the time efficiency, a variable length testing technique in combination with the frequency dependent beamformer is described, which is adaptive to any signal to noise ratio or varying channel condition.  Especially in the low signal to noise ratio regime, an overall speed-up can be achieved.  The described radar-like solution to the initial beam alignment problem may act as an enabler for mmWave communication in fast-varying and challenging environments.”

9:20 AM – 113: Determining the OIP3 and Bias Network Resonances of Phased-Arrays Using Far-Field Techniques

Yusheng Yin (Extreme Waves)*; Gabriel Rebeiz (Extreme Waves)

“The output 3rd-order intercept point (OIP3) is a figure of merit to evaluate the linearity of an amplifier or a system of amplifier blocks. Also, the OIP3 is a useful term to estimate the 3rd-order intermodulation (IM3) components and the adjacent channel power ratio (ACPR) of a transmitter for complex modulation measurements. A phased array operating in a transmit mode combines the output of several power amplifiers in free space, and the far-field contains an average and a scaled version of the linear and nonlinear components of the individual power amplifiers. In this paper, a method to determine the OIP3 of phased-array amplifiers using a far-field measurement is derived and verified by experiment. The far-field OIP3 is then measured using a 5G 28 GHz 32-element phased array employing 2×2 beamformer chips, and the far-field derived OIP3 agrees well
with measurements done on a single amplifier. This technique therefore allows the user to determine the (average) OIP3 of the power amplifiers used in an array even if they do not have access to the individual beamformer chip. An additional benefit is the ability of characterizing the PCB bias network resonances in a
phased-array environment.”

9:40 AM – 171: An SICL-Fed Compact Magnetoelectric Dipole Antenna for 5G Millimeter Wave Bands

Aditya Singh (Queen’s University)*; Carlos E. Saavedra (Queen’s University)

A compact magnetoelectric (ME) dipole antenna element is proposed for design of wide beam steering arrays in the 5G millimeter wave (mm-wave) bands n257, n258 and n261. The antenna employs an substrate integrated coaxial line (SICL) based feed. The SICL line is transformed into a coplanar waveguide (CPW) to enable feed for ME dipole antenna. With adoption of a U-shaped shorting strip and SICL-CPW-based feed, the element achieves an -10 dB impedance bandwidth (IBW) of 22.5% at the center frequency (f0) of 26.8 GHz. Notably, the antenna offers nearly 100 degrees of 3 dB beam width and a compact size of 0.32 wavelengths x 0.32 wavelengths at f0. Using full-wave simulations, an 8-element uniform linear array (ULA) is shown to exhibit fractional IBW of 19%, max gain > 15 dBi with large beam steering angles up to 56 degrees. The antenna can be easily fabricated using standard four layer printed circuit board (PCB) technology on Rogers 5880 dielectric laminates.

10:00 AM – BREAK

10:30 AM – 129: Wide-Angle Flattened Luneburg Lens for Millimeter-Wave Beam Steering Applications 

Mohamed Elmansouri (University of Colorado Boulder)*; Dejan Filipovic (University of Colorado Boulder)

This paper discusses the design and performance of a three-dimensional (3D) Luneburg lens (LL) with a flat focal surface for wide-angle beam steering applications. The lens is designed based on the theory of quasi-conformal transformation optics (QCTO) where simple mathematical procedures are applied to flatten a portion of a spherical LL surface. Different design aspects to control the lens scan range are discussed. A wideband magneto-electric dipole antenna operating over the 24-40 GHz band is designed and used as a feed to demonstrate the lens performance. A flattened LL with beam steering capability up to ±65° is fabricated using 3D printing process and preliminary performance thereof is presented.

10:50 AM – 138: Compact Antenna Test Range EVM Measurements of a Millimeter-Wave Phased Array using a VNA

Dustin Brown (UCLA Antenna Lab)*; Yahya Rahmat-Samii 

Compact antenna test ranges (CATR) are favorable for over-the-air (OTA) measurements of millimeter-wave phased arrays because they use a feed and parabolic reflector to emulate the plane wave condition of far field ranges within a significantly-reduced volume, which lowers path loss and helps compensate for the limited dynamic range of test instruments such as vector network analyzers (VNA). Error vector magnitude (EVM) is a measure of digitally-modulated signal quality that is increasingly used as a benchmark of millimeter-wave array performance, since it includes the effects of each element’s radiated power and RF integrated circuit (RFIC) linearity across the signal bandwidth. This paper presents EVM measurements of independent phased array elements within a CATR using spectrum analysis on a VNA receiver, performed at Keysight in Santa Rosa, CA, USA.