Design and analysis of microstrip slot array antenna ...193.226.7.140/lejpt/A25/072_083.pdfDesign and analysis of microstrip slot array antenna configuration for bandwidth enhancement

Leonardo Electronic Journal of Practices and Technologies

ISSN 1583-1078

Issue 25, July-December 2014

p. 72-83

Design and analysis of microstrip slot array antenna configuration for

bandwidth enhancement

Duvvuri Sri RAMKIRAN1, Boddapati Taraka Phani MADHAV1, Nimmagadda HARITHA2,

Ravuri Sree RAMYA2, Kalyani M. VINDHYA2, Sai P. ABHISHEK2 1Associate Professor, Dept of ECE, K L University, Guntur DT, AP, India

2Project Students, Dept of ECE, K L University, Guntur DT, AP, India Emails: [email protected], [email protected],

[email protected], [email protected], [email protected]

Abstract

A bandwidth-enhanced Microstrip slotted array antenna is fabricated on an

electrically-thin substrate to provide an economical solution for

communication applications. To improve the impedance bandwidth of a

rectangular micro strip patch without having any impact on its radiation

characteristics, we perform etching of straight slot which is parallel and near

to top side of the patch. For demonstrating the usefulness of the suggested

technique, a planar array of dimension 6X6 with a side-lobe of 25 dB in both

the E and H-planes are studied and fabricated on the FR4 substrate with 0.787

mm thickness. Simulation studies will be carried out on Method of Moments

based EM Tool and analysis of the model is done by changing different

operational parameters like the width of the slot, array element spacing, and

array pattern. The antenna output parameters will be studied by changing

substrate materials, εr ranging from 2 to 4.4 and complete analysis is

presented in a detailed manner.

Keywords

Array antenna; Bandwidth enhancement; Impedance bandwidth; Method of

moments

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Design and analysis of microstrip slot array antenna configuration for bandwidth enhancement

Duvvuri S. RAMKIRAN, Boddapati T. P. MADHAV, Nimmagadda HARITHA, Ravuri S. RAMYA, Kalyani M. VINDHYA, Sai P. ABHISHEK

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Introduction

Microstrip antennas are very useful candidates in communication systems because of

their simple geometry and are relatively inexpensive to design and manufacture [1]. A single

layered FR4 is used as substrate in designing a micro strip antenna array, which is having

dielectric constant of 4.4 and thickness 0.787 mm. We implemented the current models on a

thin substrate. The thick substrate has two disadvantages. One is more energy dissipation by

antenna and other is unwanted surface wave propagation, so which will decrease energy,

efficiency and deteriorate the energy pattern. By increasing thickness of the substrate we can

attain the bandwidth improvement, but there is some limitation on the height of the substrate,

over which the antenna performance will be degraded [2].

Impedance matching will play a vital role in the antenna performance, especially for

the bandwidth improvement. Choosing proper impedance matching network, while

connecting array configuration is very much needed for good radiation mechanism. Because

of the variations, nature of the inherent narrow bandwidth on conventional microstrip patch

antenna is observed. Except for single-feed circularly polarized elements, the resonant

behaviour of the input impedance has an effect on bandwidth limitation and not due to the

radiation pattern or gain variations [3]. To increase the bandwidth by a factor of at least 3.9,

we use an optimally designed impedance-matching network. Therefore, a broadband

impedance matching is proposed to increase the bandwidth [4].

In thick microstrip antennas, probe inductance prevents matching of the patch

impedance to the input connector. The probe inductance can be tuned out with a capacitive

gap. To maintain simplified construction the gap will be etched on the patch surface. The use

of a single probe-compensated feed results in distortion of radiation pattern, high cross

polarization and low efficiency because of higher-order modes and surface-wave generation

[5]. Two-probe feeding is used to overcome these problems and to produce a wide-band

antenna with good radiation pattern control and high efficiency [6].

To double the bandwidth of rectangular micro strip patch antennas, capacitive excited

short circuit parasitic elements are located at their radiating edges. It is shown that the

bandwidth improvement is independent of the coupling capacitance. To produce multiple

resonances we arrange the right angle slot of the long arm parallel to non-radiating edges. The

length of the long arm is more than ninety percent of the patch and short is forty percent.


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There are many methods to improve Uni-polar bandwidth. The impedance bandwidth can be

raised by producing TM at the basic TM10 mode. Moreover, these slots will disturb the

fundamental mode current division particularly at high frequency [7].

Novel bandwidth of micro strip antennas can be enhanced by loading a U-shaped slot

and a pair of right angled slots. Dimensions required for the U shaped slot and the right-

angled slots can be determined experimentally. The obtained antenna bandwidth when

compared with an un-slotted rectangular micro strip antenna will be as large as about 2.4. The

other simplest technique to increase the impedance bandwidth in this communication is to use

two parasitic straight slots etched parallel and near to its non-radiating edge [8]. This is simple

because manufacturing intricacy, price and time can be reduced. Depending on the slot

configuration, a 6x6 array is used in antenna for communication. These methods is used in

communication sensors and also in inter vehicle communication system. The benefits are light

gravity, low shape, an easy fabrication and low expenses of large scale manufacturing. Planar

arrays afford more symmetrical patterns with lower side lobes and the ability to scan the main

beam toward any point in space. These arrays are mainly used in the communication systems

to transmit the signals with high gain.

Material and method

All the models are designed and simulated using Method of Moments based

electromagnetic solver IE3D tool. FR4 substrate material with dielectric constant 4.4 with

thickness 1.6 mm is used in these designs. Quarter wave transformers are incorporated in the

array models for impedance matching. Basically starting with single element patch,

subsequent models are designed with 2x2, 4x4 and 6X6 array configurations.

Antenna geometry

The array factor for linear array is:

∑=

++−=M

ma dmjkIU

10m )]coscossinsincoscossin(cos)1(exp[)/(I),( θδφθβφθαφθ (1)

Io represents the magnitude of the excitation current at the centre element of the array so

all other Im currents are normalized to the centre element's current.

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If we have M elements along the x-axis the array factor is given by the following equation

∑=

+−=M

mxxxna kdmjIIU

10 )]cos(sin)1(exp[)/(),( βφθφθ (2)

where Iox is the current of the centre element if an odd number of elements or center

elements, if an even number of elements and we are removing the restriction that the currents

have equal amplitudes. Now, if we have N elements along the y axis with an inter element

spacing of dy and a progressive phase shift βy.

∑=

+−=N

nyyyna kdnjIIU

10 )]cos(sin)1(exp[)/(),( βφθφθ (3)

where Ioy is the current of the centre element if an odd number of elements or centre

elements, if an even number of elements and α=γ=90° and β=0° in equation (1).

For a large array, with its maximum near broad side, the elevation plane half-power beam

width is

]))sincos[cos/(1( 022

0022

002

φφθ −− Θ+Θ=Θ yxh (4)

where Θx0 and Θy0 indicates the half power beam-width of M element and N element

broadside linear array respectively.

Here

U(θ, Ф) = Power density from the planar array, P watt/m2

θ o = Direction of the maximum beam in the elevation plane

Фo = Direction of the maximum beam in the horizontal plane

(θ o, Фo) = direction of the maximum beam scanning in the phase Imn current amplitude in the

mnth element

α = Progressive current phase shift

β = constant phase shift 2 θ / λ

M = Total elements in X-direction

N = Total elements in Y-direction

dx, dy =spacing between adjacent elements in x and y direction

AF(θ,Ф) = Array factor


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Figure 1a. Single element patch model, 1b. 2x2 Array model

Figure 2. (a) 4X4 array model (b) 6x6 array model

A single element patch is designed by using the method of moments based EM tool

IE3D and after that the array models are constructed for 2x2, 4x4 and 6x6. Quarter wave

transformers are used in the design of arrays for impedance matching. To simulate single

element, 2x2 and a 4x4 array model the computational facilities that are available in our

university is sufficient with the RAM availability, but when the number of elements are

increased we need higher computational facilities to get the result in time. In this method, an

equivalent circuit network was built up by combining the equivalent circuit model of the path

and that of the feeding network. Meanwhile, the mutual couplings among patches are also

considered while incorporating their equivalent circuits. Figures 1 and 2 are showing all the 4

models with their dimensional characteristics.

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Results and discussion

An antenna should be perfect radiator, rather than perfect absorber. The amount of

radiated power returned back through the port can be calculated for finding return loss at that

resonating frequency. For the resonant frequencies the return loss should be less than -10dB

i.e. S11<-10 dB. Figure 4 shows the return loss curve for all the 4 models and it is observed

that for a 6x6 array model an impedance bandwidth of 16% is attained.

Figure 4. Return loss Vs frequency

VSWR is a function of reflection coefficient, which describes the power reflected

from the antenna. Figure 5 shows the VSWR curve for 4 models and it is observed that all the

models are maintaining 2:1 ratio of VSWR at the resonating frequency.

Figure 5. VSWR Vs frequency


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Antenna impedance is presented as the ratio of voltage to the current at the antenna’s

terminals. Figure 6 shows the impedance characteristics of the model and it is noted that

almost 50ohms is obtained at the desired frequency.

Figure 6. Z-Parameters for all the models

Antenna gain describes how much power is transmitted in the direction of peak

radiation to that of an isotropic source. By increasing the order of elements it is noted that the

gain of 3, 8, 12 and14dB obtained from the models. A 6x6 array is giving maximum gain of

14dB at the resonant frequency and it can be observed from Figure 7.

Figure 7. Gain Vs frequency

The radiation performance of the entire array is evaluated by the array factor technique

and the array factor is calculated from the scattering parameters of our equivalent circuit

network. Calculated results are presented in Figure 8 for a single element, 2x2, 4x4 and 6x6.

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Figure 8. Radiation characteristics of the models

Table 1 showing all the antenna parameters like resonant frequency, directivity,

radiation efficiency, gain and 3dB beam width. The efficiency of the antenna is more for 6X6

array model with high gain of more than 12 dB.

Table 1. Antenna parameters for single, 2x2, 4x4 and 6x6 models S.NO Parameter Single element 2 x 2 4 x 4 6 x 6 1 Frequency

(GHz) 1.836 1.84 1.828 1.842

2 Incident Power 0.01 W 0.01 W 0.01 W 0.01 W 3 Radiated

Power 0.00688558 W 0.00597487 W 0.0025073 W 0.00210908W

4 Directivity 6.20227 dBi 12.1549 dBi 17.811 dBi 17.968 dBi 5 Radiation

Efficiency 71.3948% 69.9562% 71.6808% 71.676%

6 Antenna Efficiency

68.8558% 69.7487% 65.073% 71.09%

7 Gain 4.58167 dBi 9.9182 dBi 11.80 dBi 12.02 dBi 8 3db Beam

Width (84.6649, 170.267) deg.

(46.2137, 50.2583) deg.

(22.9598,24.1022)deg. (15.033, 30.8845) deg.

Figure 9 shows the current distribution over the surface of the antenna with its

intensity readings. On the surface of the antenna the orientation of current elements at a

particular frequency is presented with colour scaling. With respect to the current scaling we

can identify the mode of propagation in the current models.


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Figure 9. Current distribution at resonant frequency

The basic 6x6 array model is modified by placing slots on top edge as shown in the

Figure 10(a) and slot at the centre point on the patch as shown in Figure10(b).

Figure 10. (a) 6x6 array open slot, (b) closed slot model

By placing these slots we observed the change in resonant frequencies of the antenna.

For an open slot model shown in Figure 11 antenna is resonating at 1.6,1.68 and 1.98Ghz with

return loss of -20,-32 and -14dB respectively. From the VSWR curve of Figure 12, 2:1 ratio is

attained at the desired bands for both the models. Gain of 9dB for an open slot model 10dB

for a closed slot model is observed from Figure 13.

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Figure 11. (a) Return loss Vs frequency of closed slot and open slot models (b) VSWR Vs

frequency of closed slot and open slot models

Figure 12. Frequency Vs gain of 6X6 closed (measured) and open slot (simulated) array

models

Figure 13. Radiation pattern Azimuth cut in 2D and polar planes at 2.1 GHz


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Figure 14. Radiation pattern Azimuth cut in 2D and polar planes at 1.9 GHz

All the antenna parameters for the 6x6 open and closed slots are tabulated in Table 2.

Table 2. Antenna parameters S NO Parameters 6 x 6 closed slot 6 x 6 open slot 1 Frequency 1.832 ghz 1.672ghz 2 Incident power 0.01 W 0.01W 3 Radiated power 0.00171666 W 5.20438e-005 W 4 Directivity 12.9667 dBi 17.2814 dBi 5 Radiation efficiency 17.678% 0.521003% 6 Antenna efficiency 17.1666% 0.520438% 7 Gain 9.3135 dBi 10.5549 dBi 8 3 db beam width (15.3368, 29.442) deg. (16.7832, 31.6625) deg.

The simulation results are giving the performance characteristics of the model in

virtual environment. Once by attaining radiation characteristics of the model based on

element spacing, then we can optimize the model and fabricate the model.

Conclusions

The designed models are showing excellent gain and directivity at the resonating

frequencies with high radiation efficiency. Bandwidth enhancement of more than 2-3% is

attained when compared with basic models. The proposed models are giving excellent

radiation characteristics with minimum return loss at desired frequencies. Some special

observations from the current study are

We observed from the fig 13 and 14, that the inter element spacing between the

elements for an N element array is increased then the beam width will be decreased.

From this study we observed that for the uniformly spaced arrays the maximum space

length is a half-length to avoid grating lobes.

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We also observed that the array element spacing is non uniform then aliasing can be

avoided. Particularly if the spacing is not the multiples of each other.

Acknowledgments:

Authors would like to express their deep gratitude towards the ECE department and the

management of K L University for their support and encouragement during this work.

Authors also like to express their thanks to the department of science and technology through

SR/FST/ETI-316/2012 FIST program.

References

1. Constantine A., Balanis, Antenna theory, analysis and design, John Wiley & Sons,

Inc., Hoboken, New Jersey, 2005.

2. Liang H. and Ke W., 24-GHz Bandwidth-enhanced microstrip array printed on a

single-layer electrically-thin substrate for automotive, applications”, IEEE

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3. Pozar D.M., and Schaubert D.H., Microstrip antennas: the analysis and design of

microstrip antennas and arrays, New York: IEEE Press, 1995.

4. Sze J.-Y. and Wong K.-L., Slotted rectangular microstrip antenna for bandwidth

enhancement,” IEEE Trans. antennas propag., 2000,48(8), p. 1149–1152.

5. IE3D Package14.1 ed. Fremont, CA, Zeland Software, 2009.

6. Mohammad T. I., Mohammed N.S., Norbahiah M., and Baharudin Y., Analysis of

broadband slotted microstrip patch antenna, IEEE Trans, 2008, AP-1-4244-2136.

7. Madhav B.T.P., Pisipati V.G.K.M., H. Khan, Prasad V.G.N.S., K. Kumar P., Bhavani

K.V.L, and Datta Prasad P.V., Microstrip 2x2 square patch array antenna on K15

liquid crystal substrate, International journal of applied engineering research, 2011,

6(9), p. 1099-1104.

8. Wen-Chung L., Chao-Ming W., and Yen-Jui T., Parasitically loaded CPW-Fed

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Design and analysis of microstrip slot array antenna ...193.226.7.140/lejpt/A25/072_083.pdfDesign and analysis of microstrip slot array antenna configuration for bandwidth enhancement