Wideband Gap Coupled Assembly of Rectangular Microstrip Patches for Wi-Max Applications
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Vijay Sharma
und
M.M. Sharma
Abstract
This paper presents a wideband gap coupled assembly of rectangular microstrip patches applicable in lower and upper band of Wi-Max applications utilizing six directly and parasitically coupled patches. Considered assembly of patches on glass epoxy FR4 substrate has overall dimension of 40.0 mm by 52.88 mm. The proposed antenna is designed to function in the lower band (2.4–2.69 GHz) and upper band (5.25–5.85 GHz) of Wi-Max systems. The antenna is simulated using IE3D simulation software in view of the Wi-Max standards adopted by IEEE 802.16 working group. The simulated and measured results are well in agreement and show that antenna resonates in two bands proposed for wireless communication applications and successfully achieves the bandwidth of 11.2% (at VSWR: 1.5) with respect to the center frequency of 2.84 GHz in lower band and 9.7% with respect to the center frequency of 5.39 GHz in upper band. Gain and efficiency of antenna in these two bands are however low due to lossy substrate but radiation patterns in each of these two bands are identical in shape in entire bandwidth region. In lower band maximum radiations may be achieved normal to patch geometry but in upper band, direction of maximum radiations is inclined at θ = 60° perhaps due to the generation of higher mode.
©[2014] by Walter de Gruyter Berlin Boston
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Artikel in diesem Heft
- Masthead
- Design of a 4-element Antenna Array for BDS Anti-jamming Applications
- Performance Analysis of Coaxial Fed Stacked Patch Antennas
- Dual-band Circularly Polarized Aperture Coupled Annular-ring Microstrip Antenna for GNSS Applications
- Wideband Gap Coupled Assembly of Rectangular Microstrip Patches for Wi-Max Applications
- Broadband SIW Sequential Feeding Network
- Hybrid SIW-GCPW Cruciform Directional Coupler
- Propagation Characteristics of Rectangular Waveguides at Terahertz Frequencies with Finite-Difference Frequency-Domain Method
- Novel Polarization Splitter Based on Highly Birefringent Dual-core Photonic Crystal Fibers with Hollow Ring Defects
- Optimal Design of Broadband Ultra-flattened Dispersion Photonic Crystal Fiber Using Genetic Algorithm
- Use of the Stokes Parameters of FBG for Transverse Strain Sensing and the Optimization of the Grating Structure
- Determination of Effective Constitutive Properties of Metal Powders at 2.45 GHz for Microwave Processing Applications
- Thermal Impact on the Performance of Highly Efficient Multi-stage Depressed Collector for Space TWT
