Broadband RF Phased Array Design with MEEP: Comparisons to Array Theory in Two and Three Dimensions

Hanson, Jordan C.

doi:10.3390/electronics10040415

Cited by 6 publications

(5 citation statements)

References 27 publications

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“…The Meep software package was used for numerical modeling using the FDTD method [101,103], which used standard Yee mesh sampling. The simulation was carried out using the FDTD method.…”

Section: Methodsmentioning

confidence: 99%

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The Features of the Optical Traps Formation Using Silicon Ring Gratings with Variable Height

Savelyev

2023

Photonics

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Features of the diffraction of Gaussian beams and Laguerre–Gaussian modes on subwavelength optical 3D microstructures with variable relief heights are calculated and studied in this paper. Silicon subwavelength ring gratings and diffraction axicons were considered as such optical microstructures. The height of individual relief elements varied. The propagation of laser light through the proposed optical elements was simulated using the finite difference time domain (FDTD) method. It was shown that it is possible to select the height of individual relief rings of ring gratings in such a way that it is possible to reduce the size of the focal spot down to 0.36 λ, form an extended light segment (up to 5.79 λ), and form optical traps.

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“…The Meep software package was used for numerical modeling using the FDTD method [101,103], which used standard Yee mesh sampling. The simulation was carried out using the FDTD method.…”

Section: Methodsmentioning

confidence: 99%

“…The finite difference time domain (FDTD) method [96][97][98][99][100] was used to numerically calculate the propagation of the laser radiation. The calculations were performed using the freely available Meep software [46,[101][102][103][104] on a computing cluster with a capacity of 850 Gflop.…”

Section: Introductionmentioning

confidence: 99%

The Features of the Optical Traps Formation Using Silicon Ring Gratings with Variable Height

Savelyev

2023

Photonics

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“…Simulations using finite-difference timedomain [51] and parabolic equation codes [52,53] are underway to determine if nonuniform antenna spacing or antennas with asymmetric zenith angle gain can increase transmitter efficiency in the direction the beam is "steered". Some recent studies also indicate that broadband phased arrays may be possible in ice [54], though focus here is on higher frequencies than those of interest to RET-CR.…”

Section: Transmit Array and Transmitter Modulationmentioning

confidence: 99%

The Radar Echo Telescope for Cosmic Rays: Pathfinder experiment for a next-generation neutrino observatory

Prohira¹,

Vries²,

Allison³

et al. 2021

Phys. Rev. D

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The Radar Echo Telescope for Cosmic Rays (RET-CR) is a recently funded experiment designed to detect the englacial cascade of a cosmic ray-initiated air shower via in-ice radar, toward the goal of a fullscale, next-generation experiment to detect ultrahigh energy neutrinos in polar ice. For cosmic rays with a primary energy greater than 10 PeV, roughly 10% of an air shower's energy reaches the surface of a high elevation ice sheet (≳2 _ km) concentrated into a radius of roughly 10 cm. This penetrating shower core creates an in-ice cascade orders of magnitude more dense than the preceding in-air cascade. This dense cascade can be detected via the radar echo technique, where transmitted radio waves are reflected from the ionization deposit left in the wake of the cascade. RET-CR will test the radar echo method in nature, with the in-ice cascade of a cosmic ray-initiated air shower serving as a test beam. We present the projected event rate and sensitivity based upon a three part simulation using CORSIKA, GEANT4, and RadioScatter. RET-CR expects ∼1 radar echo event per day.

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“…Further, let the beam angle be Δ = − 0 , where 0 is some reference angle (usually in the direction orthogonal to the phased array). According to [10], the radiation pattern is (…”

Section: Radiation Patterns and Beam Widthmentioning

confidence: 99%

Broadband RF Phased Array Design for UHE neutrino detection

Hanson¹

2021

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

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Radio-frequency (RF) phased array systems have a wide variety of applications in engineering and physics research. Among these applications is ultra-high energy neutrino (UHE-) detection above 100 PeV via the Askaryan effect. Phased array design usually requires numerical modeling with expensive commercial computational packages. Using the open-source MIT Electrogmagnetic Equation Propagation (MEEP) package, a set of phased array designs relevant for UHEdetection is presented. Specifically, one-dimensional arrays of Yagi-Uda and horn antennas were modeled in the bandwidth of the Askaryan effect [0.1 -5] GHz, and compared to theoretical expectations. Precise matches between MEEP simulation and radiation pattern predictions at different frequencies and beam angles are demonstrated. Finally, the effect of embedding a phased array within Antarctic ice is studied. Askaryan-class UHE-detectors are being constructed in Antarctic ice because it is an ideal detection medium for UHE-. Future work will develop the phased array concepts with parallel MEEP, in order to increase the detail, complexity, and speed of the computations.

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Broadband RF Phased Array Design with MEEP: Comparisons to Array Theory in Two and Three Dimensions

Cited by 6 publications

References 27 publications

The Features of the Optical Traps Formation Using Silicon Ring Gratings with Variable Height

The Features of the Optical Traps Formation Using Silicon Ring Gratings with Variable Height

The Radar Echo Telescope for Cosmic Rays: Pathfinder experiment for a next-generation neutrino observatory

Broadband RF Phased Array Design for UHE neutrino detection

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