Virtual Prototype of Innovative Ka-Band Power Amplifier Based on Waveguide Polarizer

Passi

et al. 2022

AEM

This paper outlines a novel approach to design a waveguide to microstrip Finline transition, that allows a division by three of the RF power traveling inside a rectangular waveguide. The possibility of obtaining and odd power division of microwave and millimeter wave signals with such Finline transition is completely unexplored yet harbinger of great opportunities. Starting from a 3D CAD model of the structure and continuing with Electromagnetic simulations, the obtained results completely describe a transition able to achieve an almost perfect power splitting by three. Multyphisics simulations, show an intrinsic resistance to vibrations of such transition, allowing it to be installed on aircraft or satellites modules. Thanks to this achievement a total new kind of power devices will come next, exploiting this odd power division in fact, it will be possible to realize different types of microwave amplifiers, increasing the efficiency and decreasing the occupied size. At the Author’s best knowledge it is the first time a divider by three Finline transition is reported in literature.

Section: Longitudinal and Transverse Probesmentioning

confidence: 99%

An Innovative Odd-Power Divider by means of a Triple FinLine Waveguide to Microstrip Transition

Passi

et al. 2022

AEM

“…Considering solid-state devices, recent advances in GaN technology allow us to obtain solid-state high power amplifiers (SSHPAs) at high frequencies and with high reliability [1]. Spatial power amplifiers (SPAs) [2], [3], [4], [5], [6], [7] are the most desired SSHPA-based devices whenever small size, solid-state highpower density, and graceful degradation are needed. The examples of application fields are strategic electronic warfare (EW), electronic counter measurement/electronic counter counter measurements (ECM/ECCMs) systems, and space communications applications.…”

Section: Introductionmentioning

confidence: 99%

Innovative Mode Enhancement for High Power Coaxial Vircators

IEEE Trans. Electron Devices

Paolo

2023

The size and weight of a high power microwave (HPM) source can make a difference in strategic use. The compactness of the virtual cathode oscillator (vircator) is undoubtedly the most significant advantage of this device. Civil industry and agriculture can use it to treat objects, food, and soils for disinfestation and disinfection. Vircators could also generate electromagnetic pulses (EMPs) to force the arrest of vehicles and drones; EMPs could inhibit or activate improvised explosive devices (IEDs). The coaxial type vircator is a highly compact device. Due to its symmetric geometry, coaxial vircator is typically designed to work with a TM 01 mode. Still, when radiated into space, this mode gives maximum RF energy away from the antenna axis, a situation not desired. Instead, the TE 11 is convenient in applications involving precise antenna pointing since this mode gives a maximum RF energy precisely aligned to the antenna axis. By studying Mathieu functions applied to elliptical waveguides, we improve the performances of a TE 11 mode coaxial vircator using an elliptic drift tube (EDT). This is a completely innovative solution to reduce the mode competition inside the coaxial vircator. The rms and peak output power efficiency of the EDT coaxial vircator were measured on the TE 11 mode, obtaining the values of 6.1% and 10%, respectively, with a peak power of 450 MW in a highly compact device.

“…SPAs have been developed using high powerhigh efficiency MMICs based on semiconductors such as GaN, GaAs and InP. Different finline to microstrip (FLuS) transitions [16] have been developed through the years with different topologies E. Brenna 1 , S. Fantauzzi 1 , L. Valletti 1 , F. Di Paolo 1 and EM field modes that can be pulled out from these structures using probes [17][18][19]. Basically, this type of transitions is based on Vivaldi antenna topologies [20,21] and they are massively implemented in broadband applications, even in the THz domain and with very interesting harvesting capabilities [22][23][24].…”

Section: Introductionmentioning

confidence: 99%

A New Theoretical Approach of Studying Resonances in Single Finline Transitions

Brenna

J. Microw. Optoelectron. Electromagn. Appl.

et al. 2023

Self Cite

In this article an innovative method of studying and removing the resonances, inherently exhibit by some waveguide to microstrip transitions, is presented. By modeling an equivalent circuit, this new approach allows to obtain the constructive parameters of a finline to microstrip transition, only using the values of the resistance and capacitance components of the equivalent circuit. This procedure will allow small microwave design Companies to realize these transitions only implementing circuit analysis software, and not having to afford electromagnetic analysis software, which are very expensive and time-consuming. A full 3D electromagnetic analysis confirms that the simulation results are in excellent agreement with the results obtained by the new equations discussed in this work.