- Open Access
- Total Downloads : 483
- Authors : Jalal Naghar, Otman Aghzout, Azzeddin Naghar, Essaaidi Mohamed
- Paper ID : IJERTV3IS100993
- Volume & Issue : Volume 03, Issue 10 (October 2014)
- Published (First Online): 03-11-2014
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License: This work is licensed under a Creative Commons Attribution 4.0 International License
Design of Compact Antenna in Package for 2.4 GHz Band Applications
Jalal Naghar
Faculty of Sciences,Abdelmalek Essaadi University,Tétouan ,Morrocco
Otman Aghzout
National School of Applied Sciences,Abdelmalek Essaadi University,Tétouan ,Morrocco
Azzeddin Naghar
Faculty of Sciences,Abdelmalek Essaadi University,Tétouan ,Morrocco
Mohamed Essaaidi
National School of Computer Science and Systems Analysis,Mohamed V-Souissi,Rabat,Morocco
Abstract Antenna-in-package is an interested topic that has been the focus of much research in recent years. To face the development of the communication technology and the significant demands of wireless communication systems, the aim of this work is to develop a compact antenna-in-package printed on an FR4 multilayer structure, based on an ordinary patch antenna with a single layer substrate. The different issues encountered during the size optimization, bandwidth- increasing and the overall system design procedure are described herein. The final designed antenna has a very small size of 6x6x6mm3 on a three layers FR4 substrate with a Cooper thickness of 50m. Performance parameters like bandwidth and reflexion coefficient have been evaluated and compared with the patch antenna with a single layer substrate. With more advantage, the proposed AiP is suitable to cover also several standards of communication as Wi-Fi (IEEE 802.11b), Bluetooth (IEEE 802.15.1), Zigbee (IEEE 802.15.4), WIMAX (IEEE 802.16), ISM band and WLAN
(802.11b,g). The new AiP is simulated using the commercial electromagnetic CST Microwave Studio software. Results show a good performance.
Index TermsMicrostrip antennas, wireless communication systems, Packaging technology, layers.Microstrip antenna, RF systems.
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INTRODUCTION
Rapid progress in wireless communication systems lead to a fast evolution in the antenna design to take up the challenges in size and performance. Each type of antenna is good in its own properties and usage. Nowadays, microstrip antennas have been applied in WiMAX and WLAN according to standard of IEEE 802.11 b/g/a/h and IEEE
802.16 d. Microstrip patch antenna consists of a dielectric substrate, with a ground plane on the other side. Due to its advantages such as low weight, low profile planar configuration, low fabrication costs and capability to integrated with microwave integrated circuits technology, the microstrip patch antenna is very well suited for applications such as wireless communications system, cellular phones, pagers, radar systems, and satellite communications Systems . This results in a demand for similar reductions in antenna size. Therefore, it is challenging to design and miniature microstrip antennas to have better radiating properties with a compact size. The antenna on the substrate with high dielectric constants is
nearly a factor of r. Smaller than the antennas designed on the air substrate, in which is the dielectric constant of the substrate [1]. However, this technique not only raised the cost of the antenna, but also not applicable to integrated communication systems whose substrate dielectric constant is always small. In the literature concerning the miniaturization of the size of patch antennas, authors use several techniques. Some of them consist on insertion of: shorting posts and pin [2], short circuit [3] and cutting slots in radiating patch [4-5]. The optimization is obtained also by partially filled high permittivity substrate [8], using fractal microstrip patch configuration [6] and increasing the electrical length of the antenna by optimizing the shape [7] and ching periodical slow wave structures on the ground plane [8]. Not that, the maximum percentage of size reduction using these techniques is about 65% [9].
The size of a conventional microstrip antenna is somewhat large when designed at lower microwave frequency spectrum. Size of antenna is the major factor in the new technology of communications systems, particularly for integration in the RF (SiP) Systems in package. RF system in package (SiP) technology has rapidly developed in wireless application. The RF system successfully integrated the balance/unbalance (balun) transformer, the power amplifier (PA), the antenna switch, the filter, and the low noise amplifier (LNA) into a single package. The various communication products must be reduced in physical size and weight in order to facilitate the growth of these markets and satisfy the end users requirement of low cost and multi- function system solutions. Packaging technology is becoming more and more popular for producing complex multilayer modules and antennas because of its flexibility in realizing a variable number of laminated layers. With development of Systems-in-Package with integration technology, size reduction of antennas is becoming an important design consideration for practical applications. As the demands of the integration increase, it is inevitable to integrate the antenna into the same RF package to achieve total RF system in single package. Thus, the antenna in package (AiP) technology becomes a hot topic.
For this reasons, Antennas in package are investigated vastly due to their properties, such as small size, high-speed, highly functional, low profile, low cost, conformability and ease of integration with active devices [11]. In this work, a
new compact antenna for 2.4 GHz wireless communication systems is proposed for the packaging technology. The size of the antenna is of (6x6x4.8) mm3, printed on multilayered structure. The detailed process of the antenna optimization has been based on following techniques. In the first step, the study has been focused on the determination of the geometrical parameters of the conventional patch antenna, and then the optimization process has also been considered to allow the antenna to operate in the WIFI frequency band at 2.4 GHz. In the second step, the main objective has been focused to design a novel antenna-in-package with a reduced size operating in the same frequency band that the conventional patch antenna designed in the first step. The specifications and implementation of this antenna are discussed in detail. The choice of feed line and all components location has been deeply studied. Parametrical study in CST Microwave Studio simulator has been taken into account to optimize the antenna properties. Finally the new compact and the conventional antenna are compared in terms of radiation characteristics. Results demonstrate in addition to being small in size, the novel antenna provides a large operating bandwidth covering the 2.4 GHz band.
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CONVENTIONAL 2.4 GHZ PATCH ANTENNA The conventional microstrip antenna designed to
operate at 2.4 GHz is presented in Fig. 1, the dimensional parameters for the radiating element are respectively the width W=30 mm and the length L=38 mm, with the dielectric permittivity r= 4 and thickness of 1.5 mm. The feed line dimensions are Lf=15 mm and Wf =3 mm respectively. The effective permittivity of the microstrip structure eff at the required resonant frequency can be designed as follows [10], using the formulas given in.
With Z0 = 50 is the impedance of the microstrip line.
After a detailed study of critical parameters on the antenna radiation, in Fig. 2 we can observe clearly that the reflection coefficient is centered perfectly at 2.4 GHz. We note, that good radiation properties for the antenna under study are obtained, Furthermore, future antenna requirement in modern communication networks must have antenna size reduction to be conformed to the shape of the supporting miniaturized stuctures. All these vital requirements impose significant challenges on the current technology and illustrate the need for new designs and advanced techniques to optimize the size obtaining good performance of the antennas in term of radiations properties. For this raison the antenna in package (AiP) technology becomes a hot topic.
Fig. 1. Geometry of the conventional patch antenna
1 1
c
W
2 fr
[ r ] 2 2(1)
r 1 r 1 (1 12h )1
eff
2 2 W
g 0 c
(2)
Leff
L 2L 2 2
2 f
(3)
eff r eff
eff 0.3 (W h)0.264
L 0.412h( eff 0.258 ) (W h)0.8
(4)
The length of the patch is L=Leff -2L, where c and fr are respectively the speed of light in vacuum and the resonance frequency. Based on the previous equations, the width and the length of the feed line are done by.
Fig. 2. Return Loss for of the conventional 2.4 GHz patch antenna.
The next section presents a detailed study of the proposed antenna structure for 2.4 GHz standards. The design and
g
L f 4
c
4 fr eff
(5)
specifications will be discussed and optimized.
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PROPOSED 2.4 GHZ ANTENNA-IN-PACKAGE
W 120 h
f Z0 eff
120 h 2 f L Z0c r f
(6)
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Antenna in Package
In wireless communication systems, the compact multifunctional package is driven by the advances of the
technologies and the great requirement from users. Antenna-in-Package (AiP) Design offers an elegant antenna solution radio frequency system. To suit AiP of highly integrated wireless transceivers, a number of antennas have been developed [11-15] in the past few years.
In Fig. 3 an example of antenna-in-package (AiP) is presented, via holes are used to connect the antenna with the ground. The location of the ground has an influence on the performance of the AiP. Generaly, the AiP is composed by multi-layers substrates and mlti-conductor. In this paper, similar miniaturized AiP will be proposed for the frequency band of 2.4 GHz applications.
Fig. 3. Geometry of Antenna in Package
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Geometry of the Basic Antenna-in-Package of 2.4 GHz
In the past few years, several authors have been worked on antenna in-package and different structures for highly integrated wireless systems have been developed [11-12], In this way, our objective in this paper is to design a novel very small antenna for 2GHz applications with the same improvement response characteristics as shown in Fig.1, to be adaptable to the new packaging systems. Fig.4 presents an optimized design of the antenna in package proposed in this paper.
Fig..4. Geometry of the proposed multi-layer antenna
To achieve the new antenna design for the required band, a step by step study of all critical antenna parameters has been taken into account. The proposed antenna-in-package is implemented in FR4 substrate having a relative permittivity of 4.4 and thickness of 1.5mm. The ground
plane dimensions are Wg×Lg=6 mm×6mm. The antenna is feeding by a proximity feed line with width of Wg=1mm and length of Lf= 5 mm. The feed line and the radiating
patch are made of copper with a thickness of Hc=0.05mm. The hole antenna dimensions are WsxLs= 6mmx6mm. Note that, the novel proposed AiP is designed for wireless communication systems of 2.4GHz, including WiFi, Bluetooth, Zigbee, WiMAX, etc. The antenna presented is based in multi-layers techniques on the FR4 substrate. Introducing slots in radiating patch with different geometry allow big performance and important improvement in size dimensions. Fig.4 presents a detailed initial design of 2.4GHz proposed antenna-in-Package.
The rest of parameters of the designed antenna are: Ls11=3.6mm,Ws11=3.6mm,L s12=3mm, Ws12=3mm,
Lp1=5mm, Wp1=5mm,Lp2=5mm,Wp2=5mm and tree layers of antenna having fixed values of Ws x Ls x Hs = 6mm x 6mm x 1.5mm. By comparing the structure of Fig.4 with the conventional antenna of Fig.1, we conclude that, 80% reduction in size enhancement is obtained. In the next step, more detailed parametric study will be introduced to optimize more and more the operability of the proposed antenna, in term of bandwidth and Return Loss.
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Parameters study of the 2.4 GHz Antenna-in-Package
After a deep study, the optimized geometry parameters of the antenna are fixed in the following values: Ws=Ls= Wg=6mm, Hs1=Hs2=Hs3=1.5 mm, Hc=0.05mm, Lp1=Wp1= Lp2=Wp2=5 mm. Note that, for all substrate
layers the materiel used is FR4.
As can be shown below, a critical study of the antenna parameters can demonstrate clearly, the effect of these geometrical parameters on the desired responses.
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Effect of the Ground Plane
The metallic ground is considered among the parameters that have a big influence on the response of radiation. In Fig. 5. we plot the return loss response for different dimensions of the metallic ground plane. Effectively, we conclude that the dimension of the ground plane have an important effect on the radiation, resonance frequency and bandwidth. The optimized value of this parameter is
Lg=6mm. The same issues and other parametric study will be discussed in detail in the next subsections.
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Effect of the feed line length Lf
The effect of the feed line length on the Antenna-in- package radiation properties is presented in this section. The width of the feed line is Wf=1mm. The return loss of
the proposed new antenna-in-package for different values
of Lf is presented in Fig.6. We can observe that, Lf parameter affect the bandwidth and the resonance frequency of antenna, the important radiation is presented
using the Lf =5.8mm. It is clear that the length of the feed line is responsible for the shifting of the frequency band. Consequently, the antenna under study could be used for several recent technologies operated in 2.4 GHz: Bluetooth and WLAN, scientific and medical (ISM) band (frequency range 2.42.5 GHz), unlicensed national information infrastructure (U-NII) band used in WLAN, Bluetooth and Wi-Fi operation.
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Effect of the feed line width Wf
In this section, we present the effect study of feed line dimension on the antenna responses. For this purpose, the value of Lf is 5.8mm and the results are plotted in Fig .7. As can be shown, the Wf value of 1.2mm offers a good
response with return loss of about -50 dB. Finally, we
conclude, that the length and the width of the feed line are critical parameters that that have a big effect on the radiation properties of the antenna. Therefore, they are essential parameters that can be optimized to deal with an efficient the antenna proposed
Fig..5. Return loss of the proposed antenna with for different ground plane length Lg
Fig..6. Return loss of the proposed antenna with for several values of feed line length Lf
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Effect of the slot in the middle patch
As mentioned previously, our principal purpose is focused on the development of a new Antenna-in-Package structure with a tree layers dielectric substrate. In this section, we prove that the implementation of an aperture in the middle patch affects the radiated element (Upper patch) presented in Fig.8.
Fig.9. shows the simulated return loss of the proposed antenna-in-package using different values of the diameter of the slot in the middle patch. After a detailed study, we consider that, the localization of the slot in the middle patch is one of the parameters that have a big influence on the antenna responses. Therefore, the radiation of this antenna is highly influenced by the diameter of the slot for the middle patch. We conclude that the dimension of the slot for the middle patch have a big effect on the resonance frequency and radiation properties. Consequently, this parameter is important for optimizing the proposed antenna.
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Effect of the radiated patch geometry
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In tis section, we will present some modifications for the upper layer of the designed antenna. Particularly, our
Fig. 7. Return loss of the proposed antenna with for several values of feed line width Wf.
Fig.8. Configuration of the middle layer.
Fig..9. Return loss of the proposed antenna for several values of Dslot1
investigation has been focused on the effect of the radiating element geometry on the behavior of the results. In our case, the radiating element is U-shaped, for a good simulation of the response of our antenna was proposed to study the variation of the open U in X-direction (Wslot1) and the Y-direction (Lslot2).
The value of Wslot1 is fixed on 3mm; the return loss of the proposed antenna-in-package for different values of Lslot2 is presented in Fig. 11. It can be shown that the length of the slot in radiating element has an important effect on the radiation efficiency, and affect also the bandwidth and the resonance frequency. In the same way, different values of Dslot2 are presented in Fig.12 using Lslot2=3mm.
Fig..10. Configuration of the radiating patch
Fig..11. Return loss of the proposed antenna with for different values of Lslot2
Fig..12. Return loss of the proposed antenna with for several values of Wslot2
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OPTIMIZED ESIGN OF THE PROPSED ANTENNA Table 1 shows the final design parameters of the
proposed antenna. They are obtained using the parameters
optimization described previously. Fig.13 presents, the return loss of the optimized antenna in package developed in this paper compared to the conventional antenna of Fig.
1. Its clearly observed that a very small size is achieved with better response in term of return loss and bandwidth.
TABLE I. FINAL PARAMETER VALUES OF THE PROPOSED ANTENNA
Parameters
Values
Lg
4.7mm
Ws,Ls,Wg
6mm
Hs1,Hs2,Hs3
Hc
1.5mm 0.05mm
Wf
1mm
Lf
5.1mm
Wslot1
3.6mm
Lslot1
Wslot2 Lslot2
3.6mm
3mm 3mm
Wp1,Wp2,Lp1,Lp2
3mm
Fig..13. Return loss of the proposed antenna compared to the conventional antenna
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CONCLUSION
In this paper a very small antenna in package for the
2.4 GHz frequency band technologies is presented. Multi- layer substrate using FR4 and slots are introduced. The effect of critical parameters on the antenna response is detailed in order to achieve the desired antenna responses. In comparison with the classical patch antenna for 2.4GHz, our resulting antenna offers an improvement of bandwidth with better return loss and decreasing in size of order of 80% compared with the conventional antenna. Based on the configuration of the proposed antenna and it performances in term of return loss bandwidth and miniaturized size, it can be considered as a good candidate for systems in packages.
REFERENCES
-
J. S. Colburn and Y. Rahmat-Samii, Patch antennas on externally perforated high dielectric constant substrates, IEEE Trans. Antennas Propag., vol. 47, no. 12, pp. 17851794, Dec. 1999.
-
K.-L. Wong, Compact and Broadband MicrostripAntennas.New York: Wiley, 2002, pp. 17.I.S. Jacobs and C.P. Bean, Fine particles, thin films and exchange anisotropy, in Magnetism, vol. III, G.T. Rado and H. Suhl, Eds. New York: Academic, 1963, pp. 271-350.
-
S. Pinhas and S. Shtrikman, Comparison between computed and measured bandwidth of quarter-wave microstrip radiators, IEEE Transactions on Antennas and Propagation, 36, pp. 1615-1616, 1988.
-
K. L. Wong and K. P. Yang, Small dual frequency microstrip antenna with a cross slot, Electronics letters, 33, pp. 1916-1917, 1997. Y. Yorozu, M. Hirano, K. Oka, and Y. Tagawa, Electron spectroscopy studies on magneto-optical media and plastic substrate interface, IEEE Transl. J. Magn. Japan, vol. 2, pp. 740-741, August 1987 [Digests 9th Annual Conf. Magnetics Japan, p. 301, 1982].
-
V. R. Gupta and N. Gupta, Characteristics of a Compact Microstrip Antenna, Microwave and Optical Technology Letters, 40, pp. 158- 160,2004.
-
B. Lee and F. J. Harackiewicz, Miniature microstripantennawith a partially filled high -permittivity substrate, IEEE Transactions on Antennas and Propagation, 50, pp. 1160-1162, 2002.
-
N. Herscovici and M. F. Osorio et al., Miniaturization of rectangular microstrip patches using genetic algorithms, IEEE Antennas Wireless Propag.Lett., vol. 1, pp. 9497, 2002.
-
Y. D. Lin and T. Itoh, Frequency-scanning antenna using the crosstieoverlay slow-wave structures as transmission line, IEEE Trans Antennas Propag., vol. AP-39, pp. 377380, 1991.
-
J.-H. Kim, I.-K.Kim, J.-G.Yook, and H.-K. Park, A slow-wave structure with Koch fractal slot loops, Microw. Opt. Technol. Lett., vol. 34, no. 2, pp. 8788, Jan. 2002.
-
K. Hirasawa, Analysis, Design and Measurement of Small and Low-Profile Antennas. Norwood, MA: Artech House, ch. 4, 1991.
-
C.T.P. Song, P.S. Hall, and H. Ghafouri-Shiraz, "Novel RF front end antenna package," in IEE Proceedings of Antennas Propagation, 2003, pp. 290-294.
-
Y.P. Zhang, Integration of microstrip antenna on ceramic ball grid array package, IEE Electronics Letters, vol. 38, pp. 207-208, Feb. 2002.
-
Rina Abdullah, M.T Ali , N.Ismail, S.Omar and N.N.S.N.Dzulkefli Multilayer Parasitic Microstrip Antenna Array for WiMAX Application, IEEE Asia-Pacific Conference on Applied Electromagnetics, 2012, Melaka, Malaysia.
-
Ahmed T. Hussein and Saad Luhaib, Designing E-Shape Microstrip Patch Antenna in Multilayer Structures for WiFi 5GHz Network, 20th Telecommunication Forum Teflor 2012, pp. 366-368.
-
Chia-Lun Tang, Shih-Huang Yeh, and Zi-Hau Lu, Antenna in Package for 2.4 GHz Application, International Symposium on Communications, 2005, Kaohsiung, Taiwan, R.O.C.
-
Li Li, Liping Han, Guorui Han, Xinwei Chen, anfengGeng, and Wenmei Zhang , Design for a dual frequency Antenna-in- Package, vol. 32, no. 4, Aug. 2010, pp. 614-617.