Int. Journal of Electrical & Electronics Engg.
Vol. 2, Spl. Issue 1 (2015)
e-ISSN: 1694-2310 | p-ISSN: 1694-2426
A Review of Multi Resonant Slotted Micro Strip Patch Antenna (MPA) for IMT, WLAN & WiMAX Applications Tejinder Kaur Gill, Ekambir Sidhu, Amarveer Singh Abstract: In this paper, a stacked multi resonant slotted micro strip patch antenna (MPA) has been proposed which is suitable to be used for GSM, WLAN standard and WiMAX applications. The antenna has been designed using substrate of FR4 material. In the designed stacked antenna, substrates having different thickness has been used. The bottom stack of designed antenna has a radiating patch of circular shape and the patch on the upper stack has rectangular shape and is flexible in nature. The antenna has a feed line which is connected to circular patch to feed power to the antenna. The feed line has to be of suitable width to match the antenna impedance with port impedance of 50 ohms. The designed antenna has a defected ground structure in order to improve the antenna performance. The antenna performance has been measured in terms of antenna parameters such as impedance bandwidth (GHz), Return loss (dB), antenna impedance (ohms), VSWR and Directivity (dBi). The designed antenna results have been simulated in CST Microwave Studio 2010. The practically designed antenna has been tested successfully by using Network analyzer E5071C. It has been observed that the practical results closely match with theoretical results.[11] Index Terms— Micro strip patch antenna, Multi resonant air gap stacked antenna, Defected ground structure, Return loss (S11), Directivity, VSWR
I. INTRODUCTION1 Microstrip antenna, also known as printed circuit antenna or patch antenna is suitable for conformal and low profile applications. The Microstrip Patch Antenna has advantage of low cost and weight, design flexibility and ease of installation [4]. The radiating elements together with feed line are photo etched on a thin dielectric sheet on a ground plane. The patch can be square, rectangular or circular in shape. However, MPA suffers from disadvantage that they have narrow bandwidth. Extensive research has been carried out to overcome the band width problem in recent years and many techniques have been suggested and implemented to achieve the desired wide band characteristics [2][3]. One of these techniques is stacking antennas, realizing dual frequency operation with two resonant frequencies separated by certain range [8][9]. Stacked patch antenna is kind of microstrip which consists of two printed antenna. The lower patch is called driven patch and another patch is parasitically coupled to driven patch. To produce broadband responses the selection of the substrate of the first layer is very important. The current
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distribution on the lower patch has an important role on the bandwidth of the antenna. If the lower dielectric layer has a greater dielectric constant than the upper layer, the magnitude of the first order mode on the lower patch will be greater than on the top patch thus the broadest bandwidths can be achieved. The thickness of each layer has an important role to obtain broader bandwidth. In the design process the lower patch does not design for minimum return loss in the desired band, rather than the patch should be strongly capacitive over this frequency range. To provide this, feed position of the antenna become near the edge of the patch. The adding of the second element moves the very capacitive impedance region of the single patch locus to near a matched condition [10]. The air gap can also be inserted between the two stacked layers as air gap provides maximum efficiency with minimum loss. II. ANTENNA GEOMETERY Fig 1 shows the top view of the bottom stack of the antenna. The Fig1 shows circular slotted patch excited by feedline of suitable width. Fig 2 represents the top view of upper substrate. Fig 3 represents the bottom view of stacked antenna. The ground has been designed at the bottom of the lower stack which has been partially reduced. The antenna has been fabricated using FR4 as an substrate with dielectric constant of 4.4.The height of lower substrate is 1.57mm and that of upper substrate is 0.2mm.The feedline is designed in such a way that antenna will have 50 ohm resistance matched with the port impedance for maximum power transfer from port to patch. The dimensions of substrate, patch, feed, slots cut on patch and ground are listed in Table 2.
NITTTR, Chandigarh
EDIT-2015