Navegando por Assunto "Power dividers"

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Dispositivos de controle não recíprocos baseados em cristais fotônicos para utilização na faixa de frequências óptica
(Universidade Federal do Pará, 2015-09-11) PORTELA, Gianni Masaki Tanaka; DMITRIEV, Victor Alexandrovich; http://lattes.cnpq.br/0684541646225359
The study of the photonic crystals technology is being performed by many research groups, mostly because of their many practical applications. Photonic crystal structures are comprised by materials with different refractive indexes, periodically arranged in one, two or three dimensions. They can be employed in the construction of passive photonic devices, for use in optical systems. Photonic crystal based devices have reduced dimensions when compared to the traditionally employed ones, favoring an increase on the component integration density in optical systems. On the basis of studies related to the symmetry groups of several geometrical configurations of photonic crystals and by performing many computational simulations, eight unprecedented passive devices were developed, with new operating principles. Five switches, one circulator, one nonreciprocal power divider and one multifunctional device were designed, on the basis of photonic crystals technology. The designed devices can be used, for example, in the next generation optical computers, as well as in optical communication systems.
Acesso aberto (Open Access)
Dispositivos não-recíprocos baseados em grafeno na região de THz
(Universidade Federal do Pará, 2019-02-28) CASTRO, Wagner Ormanes Palheta; DMITRIEV, Victor Alexandrovich; http://lattes.cnpq.br/3139536479960191
Four new types of nonreciprocal graphene-based devices operating in the Terahertz region are suggested and theoretically analyzed in this work. They are two three-port circulators with Y and W geometries and two power dividers with different geometries. The cross section of the components has a three-layer structure, composed of graphene, silica and silicon. The planes of the figures of these components consist of a circular resonator of graphene and waveguides connected to it. The graphene resonator is magnetized normally of its plane by an external DC magnetic field, and the physical principle of operation of the devices is based on the dipole resonance of the magnetized graphene resonator. Using the Magnetic Group Theory, we analyze the scattering matrices of the symmetrical components of the devices. In addition, for the analysis of the circulators, the Analytical Temporal Coupled Mode Theory was also used. Numerical simulations were performed by a full wave computational program and the calculations demonstrate isolation levels better than -15 dB for both the circulators and the dividers. The Y-circulator has insertion losses around - 2.6 dB, bandwidth of 7.4% at the center frequency of 5.38 THz, whereas the circulator W showed insertion losses of - 2 dB, bandwidth of 4.5% at the center frequency of 7.5 THz. The DC bending magnetic field in the two cases was 0.45 T and 0.56 T, respectively. The power dividers have shown to posses the division of the signal between the two output ports of -4.4 dB with in the frequency band of 4.5% and 3.4% with magnetic filed of 0,8 T. The influence of geometric and physical parameters on the characteristics of the circulators is discussed. The frequency bands of the devices can be controlled dynamically by changing bias voltage applied between the graphene layer and the substrate.