Novel Design of High-Gain Planar Dipole-Array Antenna for RFID 2 . 45 GHz

This paper presents a novel high-gain planar dipole-array antenna for 2.45GHz which consists of four planar dipole elements placed in two parallel lines. Phase retardation of each element is set by feeding network to form controllable radiation direction. The radiation pattern of the array is discussed according toArraysTheorem.Themeasured−10 dBband is from2.3GHz to 2.57GHz, and peak gain in this band is 7.5 dBi. The gain can even reach 10.5 dBi after installing additional ground.The proposed antenna has advantages of high gain, controllable direction, and planarity which are suitable for 2.45GHz RFID base station.


Introduction
As an integral part of our life, RFID increases productivity and convenience [1].It is ubiquitous in solving problems in fields such as supply chain management, security, personal identification, and asset tracking [2].Low-gain tag antennas are used for transponder, and a high-gain reader antenna is required to increase the reading range [3].To meet the high-gain demand of RFID base station, antenna arrays are arranged in certain position.With certain matching condition of amplitude and phase of current for each element, the radiation vectors superpose and gain enhances according to Arrays Vector Sum Theorem [4].Among various kinds of element structure, microstrip and dipole are popularly used to provide high gain.Microstrip antenna has characteristics of easy integration, planar structure, light weight, small size, and low profile.However, it suffers from low directivity, narrow bandwidth typically 5%, and low efficiency [5].Dipole-printed antenna is fit for high-gain systems for its wide bandwidth and simple structure [6].
Recently, a composite dipole antenna array with direct feed is discussed [7].Efficiency and omnidirectional radiation gain are enhanced due to the load of antenna.Another novel omnidirectional antenna with bandwidth broadened is presented [8].Two half-wavelength dipoles are printed on both sides, and the parasitical elements are connected to the fed ones by metal pins.The antenna is fed by coupled lines.
In this work, a novel high-gain planar dipole-array antenna with wide bandwidth and controllable radiation direction is presented.Dipoles are printed on both sides of the substrate, and all dipoles are fed by CPW line, with advantages of low radiation loss (especially from the feed point), less dispersion, planar configuration, and amenability to integrate with active microwave devices [9,10].

Structure of Proposed Array Antenna
Structure of proposed antenna is shown in Figure 1. Figure 1(a) presents the structure of four-element arrays which is printed on a substrate with relative permittivity of 4.4, a loss tangent of 0.02, and a thickness of ℎ = 1.6 mm. Figure 1(b) presents structure of one element.Top layer contains planar coaxial feed lines, radiation dipoles, and ground.Bottom layer is ground with similar dipole structure of top layer.Two rows vias connect upper and lower ground plane.Structure of the coplanar waveguide feeding network is shown in Figure 2, which not only divides power for four ports, but also acts as a phase shifter to make 180 deg phase retardation.In this case, current of arrays has 180 deg phase  retardation with the same direction.By controlling phase retardation of each array, radiation direction is identified.By setting variables l and l e , phase retardation can be tuned using Ansoft HFSS.Table 1 lists the possible combinations of l and l e for 180 deg phase retardation.In our design, l and l e are selected as 60 mm and 7.2 mm.

Analysis of Proposed Arrays Using Arrays Theorem
In this section, analysis of proposed arrays using Arrays Theorem is given.Firstly, two dipole elements in one line comprise a Binary Side Fire Array.The two Binary Side Fire Arrays with four elements comprise a Binary End Fire Array [11].For Binary Side Fire Array, assuming that the array distance is half wavelength, namely,  = /2, and the phase difference of the two elements is  = 90 deg, the current relation of the two elements can be expressed as For Binary Side Fire Array, the total far electric field   is expressed as ( The corresponding radiation direction pattern is ) . ( For the Binary End Fire Array, the phase retardation of its two elements (i.e., two Binary Side Fire Arrays) is  = −90 deg, and the distance between the elements is  = /2.Substituting  = /2 and  = 0 deg, the total far electric field of the Binary End Fire Array   is expressed as The final radiation pattern of the four element array is calculated as ) . ( The calculated radiation pattern of the four-element array by MATLAB is shown in Figure 3 left with side lobe towards right.So by controlling phase of each array  and , radiation direction can be controlled.Hence, the proposed antenna is suitable for base station application with particular beam angle requirement.

Simulated and Measured Result
The distance of two adjacent arrays in the same row , length of impedance tuner on CPW line  14 , and width of impedance tuner for dipole  4 are key parameters of the proposed antenna due to their dominant effects on the It can be concluded that decreasing array distance  enhances the total realized gain in the range from 2.3 GHz to 2.8 GHz.Distance  also controls antenna impedance matching and resonant frequency.Figure 5 shows the effect of  14 on return loss.It can be noticed that length of impedance tuner on CPW has a remarkable effect on resonant frequency.Figure 6 shows the effect of  4 on impedance matching.After optimization by HFSS, main parameters of arrays with maximum gain by different arraying forms in 915 MHz and 2.45 GHz are shown in Table 2. Final parameters of the Fabricated antenna with additional ground is shown in Figure 7.The bottom layer of antenna is 15 mm above additional ground.Simulated and measured return loss results are shown in Figure 8. Figure 8(a) presents simulated

Conclusion
This paper presents a design method of high-gain planar dipole-array antenna for 2.45 GHz.Gain is enhanced due to the same direction of current by reversing phase of two adjacent ports.By setting phase retardation of each array, radiation direction is controllable.Expressions of two and four elements are given and radiation pattern is calculated by MATLAB.Simulated return loss at resonant point is −35.3 dB with gain up to 7 dBi.Simulated gain with additional ground is up to 9.9 dBi.The maximum measured gain without additional ground is 7.5 dBi and with additional ground is 10.5 dBi.In general, the proposed planar dipole-array antenna is suitable for 2.45 GHz high-gain base station antenna with characteristics of high gain, controllable direction, and planarity.

2 InternationalFigure 1 :Figure 2 :
Figure 1: Geometries of the proposed antenna.(a) Four-element arrays and (b) top layer and bottom layer of one element.

Figure 3 :
Figure 3: Radiation pattern of arrays calculated by MATLAB.(a) Binary Side Fire Array and (b) Binary End Fire Array.

Figure 4 :
Figure 4: Array distance  effect on simulated return loss and simulated gain of four-element arrays without additional ground.(a)  effect on simulated return loss and (b)  effect on simulated gain.

Figure 5 :w 4 Figure 6 :
Figure 5: Length of CPW line impedance tuner  14 effect on simulated return loss of four-element arrays without additional ground.

Table 1 :
Values of l and   with 180 deg phase retardation.

Table 2 :
Values of main parameters.
With additional ground, simulated gain increases to 9.9 dBi.Measured gain without additional ground is from 5.9 dBi to 7.5 dBi and with additional ground is from 9.1 dBi to 10.5 dBi within bandwidth.The simulated and measured gains are approximately the same and meet the requirements of RFID 2.45 GHz high-gain base station antenna.