This review provides a comprehensive assessment of recent advances in polymer photonic sensing technologies, focusing on material systems, fabrication techniques, device architectures, and application domains. Waveguide technology represents a fundamental approach to controlling and directing electromagnetic waves, particularly in optical and microwave applications. This technology has evolved from basic optical fiber principles to sophisticated integrated photonic systems that enable high-speed data. Optical waveguides can be described as transparent structures which are more or less put onto solid carriers. In principle, they function just like fibers and are also described by the same parameters. However, there are also some fundamental differences: Waveguides are not produced ready-made by. The MZI structure consists of a polymer waveguide arm and a doped silica waveguide arm. Due to the opposite thermal optical coefficients of polymers and silica, the hybrid integrated MZI structure enhances the temperature sensing characteristics. The direct coupling method and side coupling method. Polymer-based photonic sensors are emerging as cost-effective, scalable alternatives to conventional silicon and glass photonic platforms, offering unique advantages in flexibility, functionality, and manufacturability. The design of the presented planar waveguides was realized on the bases of modified dispersion equation and was.
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To meet the needs of multi-way power distribution applied to high-power solid-state sources, a multi-way power distribution device based on coaxial waveguide is designed and studied. In this work, two dynamically tunable power dividers using waveguide ENZ media are proposed by precisely modulating the internal magnetic field and the widths of the output waveguides. The first approach features a mechanically reconfigurable ring-shaped ENZ waveguide. By analyzing the transmission characteristics of coaxial waveguides and by applying the theory of impedance. In this paper, an E -plane stepped-impedance transformer and Y-junction bifurcation are used to form a waveguide power divider with ceramic substrate loaded with thin film resistors. This structure is realized high isolation in V-band by inserting a ceramic substrate at the H -plane center of the. A numerical model of an equal power divider based on the 4-branch single-mode waveguide is proposed. This proposed design does not require extra fabrication process and supplementary structure modification compared to other typical multibranch waveguides. The condition of uniform output power.
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1 × 8 and 1 × 16 traditional/saddle arrayed waveguide grating (AWG) devices with different core layer materials applied in fiber Bragg grating (FBG) system were designed, fabricated and compared. We ap.
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Using OptiSystem software, we evaluated AWG performance in both multiplexer (MUX) and demultiplexer (DEMUX) configurations within the C-band (1530-1565 nm), analyzing key parameters including insertion loss (1. 4 dB), channel crosstalk (-32±2 dB), polarization-dependent loss. Array waveguide gratings (AWGs) have been widely used in multi-purpose and multi-functional integrated photonic devices for Microwave photonics (MWP) systems. In this paper, we compare the effect of output waveguide configurations on the performance of AWGs. The AWG with an output waveguide. Arrayed waveguide gratings (AWGs) are key optical components of various new applications in telecommunication, astrology, medical imaging, and spectroscopy. This study presents a comprehensive performance analysis and design optimization of AWG-based. A high-performance silicon arrayed-waveguide grating (AWG) with 0. 4-nm channel spacing for dense wavelength-division multiplexing systems is designed and realized successfully. The device design involves broadening the arrayed waveguides far beyond the single-mode regime, which minimizes random.
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