The aim of this paper is to design a novel structure of a frequency-reconfigurable microstrip array antenna by using a combination of aperture-coupled and the stacked patch technology. The four sets of two different aperture slot shapes (I-shaped and H-shaped) are printed on the ground and are functional to transfer the wave and the signal to the selected radiating layers. Both aperture slot positions are based on the bottom patches (layer 2) and top patches (layer 1), respectively. To achieve the frequency reconfigurability, four PIN diode switches are integrated on the feed line layer positioned between both aperture slots on the ground. The activation of the selected patches will determine the current operating frequency of the proposed antenna. A 2.6 GHz or 3.5 GHz frequency is achieved by switching all the PIN diode switches to ON or OFF mode synchronously. The advantage of the proposed antenna is that it can minimize the usage of the antenna’s surface area, with different size of the patch having different operating frequencies, sorted in different layer. The measured results of the return losses, radiation patterns, and the practical indoor propagation measurement achieved good agreement with the simulated results.
1. Introduction
Reconfigurable antenna has a significant potential in the modern wireless communication. This is as a result of the reduction in antenna size and cost and convenience for certain applications to operate with a single antenna compared to multiple antennas. Moreover, these reconfigurable antennas have interesting characteristics as they can provide various features in different operating frequencies [1–3], polarizations [4, 5], and radiation patterns [6, 7] by changing the current distribution over the volume of the antennas. Therefore, the switching circuit of the PIN diode switch, microelectromechanical switches (MEMs), varactor diodes, or other RF switches is embedded on the antennas to achieve reconfigurability. Thus, in this work, the PIN diode is chosen due to the optimum choices: low insertion loss, fast response, low control voltage, and reliability. There are a lot of approaches in the microstrip antenna design to achieve frequency reconfigurability. In [8], the authors firstly present the designs of four subpatches with five frequency bands. Next, by integrating four varactor diodes on each subpatch, the frequency band can be independently controlled to achieve frequency reconfigurability. The compact size of 60 × 60 × 40.8 mm antenna provides dual frequency band around 2.55 GHz and 5.25 GHz with diverse patterns [9]. Another paper [10] shows that, by adjusting the PIN diodes switch on the radiating elements, the proposed antenna can be operated in PIFA for GSM900 (ON mode) or cover the frequencies for GSM1800, GSM1900, and UMTS bands during the OFF mode. The design of annular slot antenna is studied in [1] and the authors introduce an antenna that has two frequency reconfigurabilities, either at 2.4 GHz or at 5.2 GHz. A reconfigurable stacked microstrip antenna has been introduced in [11] and the antenna can operate at two different frequencies: upper frequency (fu) and lower frequency (fl) with various bandwidths, patterns, and polarization values. However, research works have been done on the design of frequency-reconfigurable antenna by using stacked substrate. This could be due to the complexity in designing the structure.
Therefore, the aim of this paper is to design a frequency-reconfigurable microstrip antenna by using a combination of a stacked patch array and an aperture-coupled feeding technique. Moreover, a new coupling method in an aperture-coupled technique is implemented to achieve the frequency reconfigurability. By using the same antenna, two different operating frequencies, either 2.6 GHz (LTE application on band 7) or 3.5 GHz (WiMAX), are achieved by configuring the PIN diodes switches on the feed line.
2. Antenna Configuration and Design Procedure
Figure 1(a) shows the geometry of the proposed antenna in 3D view. The antenna is composed of three substrate layers (RT-Rogers 5880) with dielectric constant, εr=2.2, tangent loss, δ=0.0009, and the thickness, h=0.787 mm each. The air gap structure with thickness h=3 mm is added between the substrate layer 3 and substrate layer 2 to enhance the gain performance. Besides that, the aperture-coupled technique is used to reduce the spurious radiation pattern from the feed line and the radiating layers. The radiating elements of 2 × 2 structures have been etched on top of substrate layer 1 and substrate layer 2, known as top patches and bottom patches, respectively. Basically, the dimensions of the top patches and bottom patches are based on 3.5 GHz and 2.6 GHz frequency. Next, the ground is located on the front view of the substrate layer 3. It consists of four sets of two different aperture slots, which are I-shaped and H-shaped aperture slots. To give maximum coupling effects, the aperture slot positions are based on the bottom patches (layer 2) and top patches (layer 1), respectively, that is, in between the length of Cbp and Ctp (Figure 1(b)). In this design, the I-shaped aperture slots are used to radiate the waves to activate the bottom patches, while the H-shaped aperture slots are used to activate the top patches. On the back view of the substrate layer 3, the feed line with four PIN diode switches (SW1, SW2, SW3, and SW4) is integrated in between I-shaped and H-shaped aperture slots. These PIN diode switches divided the feed line length into two lengths, Lf1 and Lf2. The geometry of the proposed antenna in 1-plane view is shown in Figure 1(b). The prototype of the proposed antenna is fabricated to validate the antenna’s performance as shown in Figure 2. The explanation of the proposed antenna working principles to achieve the frequency reconfigurability is explained in Section 3 under the current distributions results.
The geometry of the proposed antenna in (a) 3D view and (b) 1-plane view.
Photograph of the fabricated antenna: (a) front view antenna on a 120 mm × 120 mm; (b) back view: the feed line integrated with the switching circuit components.
The frequency reconfigurability of the proposed antenna can be obtained effectively from the PIN diode switch configuration. An electronic switching circuit using the Phillipe PIN diode switches model BAP51-02 is used as the RF switches to form the switching circuit. In this design, the Philips PIN diode switch is inserted in between the two transmission lines on the feed line (Lf1 and Lf2 ). The Advanced Design System (ADS) software is used to design, simulate, and validate the performance of this switching circuit. Figure 3(a) shows the equivalent switching circuit to represent four PIN diode switches for the proposed antenna. The circuit consists of the passive components including eight inductors (22 nH), one capacitor (110 pF), and four resistors (150 Ω). Refer to the feed line layout in Figure 3(b). The capacitor is used to prevent the DC signal from flowing to the main feed line or to the SMA connector. However, the capacitor allows the RF current to pass through towards the feed line network, while the eight inductors are used as RF chokes to provide a low impedance for DC. The biasing voltage of 12 V (ON mode) is connected to a 150 Ω resistor to limit the current flow to each PIN diode switch, while, in reverse mode, a 0 V (OFF mode) is supplied. The simulation results using the PIN diode equivalent switching circuits during the ON mode and OFF mode are presented in Figure 4. When the circuit is supplied with 12 V, Port 1 (S11) is in a perfect matching condition and it allows all the signals to pass through to Port 2 (S21), Port 3 (S31), Port 4 (S41), and Port 5 (S51). Thus, when in the ON mode, the S11 is resonant at 2.6 GHz with −26.57 dB while S21, S31, S41, and S51 are constant at −3.5 dB. However, when the switch is in OFF mode, Port 1 will reflect all the signals and no signals are allowed to pass through to other ports. Therefore, in this mode, the S11 is equal to −0.01 dB while the other ports are equal to −53.63 dB at 3.5 GHz. This result proves that the switching circuit can be applied in the proposed antenna.
(a) The basic equivalent switching circuit; (b) back view: the feed line layout integrated with the switching circuit component in ADS software.
Simulated results of S11, S21, S31, S41, and S51 (dB) versus frequency (GHz) for the equivalent switching circuit when all the PIN diode switches are in (a) ON mode and (b) OFF mode.
3. Simulation and Measurements Results3.1. Effects of H-Shaped Aperture Slots (ON Mode)
In the conventional methods, there is only single aperture slot to radiate the waves to the radiating elements (on layer two or more) and couple the energy with the feed line. In this research, an aperture-coupled technique has been modified, where the ground of the proposed antenna consists of two different shapes of aperture slots. The purposes of the aperture slots are used to control the activation of the selected radiating elements at different layers. Therefore, at the first stage of designing the proposed antenna, the ON mode configuration is considered and only one aperture slot (I-shaped) has been implemented on the ground. Then, the simulation analysis has been carried out to study the results of the operating frequency. Figure 5 clearly shows that when the proposed antenna only has one aperture slot (I-shaped), the antenna is resonant at 3.2 GHz. Therefore, another H-shaped aperture slot with a dimension of 32 × 54 mm is added on the ground. As shown in Figure 5, the antenna added with H-shaped aperture slot is resonant exactly at 2.6 GHz for long-term evolution (LTE) application.
Effects of H-shaped aperture slots on S11 in ON mode configuration.
3.2. Effects of the PIN Diode Switches Position (OFF Mode)
According to the ON mode results, now the proposed antenna has two aperture slots on the ground, I-shaped and H-shaped aperture slots. Next, to achieve another operating frequency at 3.5 GHz, four PIN diode switches are integrated on the feed line networks. The PIN diode switches are located in between I-shaped and H-shaped aperture slots referring to the ground, labelled as SWp. As illustrated in Figure 6, the PIN diode switch is varied along the SWp, from 2 mm to 12 mm. It can be observed that the position of the PIN diode switch causes all the frequencies to be resonant at higher frequencies, that is, more than 3.0 GHz. Therefore, the simulation result of SWp=8 mm is chosen as it is exactly resonant at 3.5 GHz with good impedance matching of −48.5 dB. This proves that once the PIN diode switch is in OFF mode, only the bottom patch radiating element is activated, while the top patch acts as the parasitic element and ensures the antenna will be operated at the higher frequency.
Effects of SWp on S11 in OFF mode configuration.
3.3. Impedance Bandwidth and Return Losses
To validate the antenna’s performance, the impedance bandwidth (S11<-10dB) and the experimental return losses between simulation and measurement have been analyzed. The CST Microwave Studio software is used to test the proposed antenna for both ON mode and OFF mode. Figure 7(a) shows that the proposed antenna is capable of operating at 2.6 GHz with the bandwidth of 69.5 MHz and 83.0 MHz for the simulation and measurement results. As for return loss results, the measured results show a shift to 2.55 GHz with −21.76 dB, compared to the simulated results. The measured results in Figure 7(b) show that the antenna is obtained at the frequency of 3.49 GHz when all the PIN diode switches are in OFF mode. The results of impedance bandwidth are equal to 76.5 MHz and 79.3 MHz, respectively, between simulation and measurement. Meanwhile, the return losses show better agreement between simulation and measurement. Both results prove that the antenna has good performance both in ON and OFF modes.
Return losses of the proposed antenna: (a) ON mode and (b) OFF mode.
3.4. Current Distributions
The current distribution of the proposed antenna is controlled by the PIN diode switch configuration mode. In this research, only two cases are considered, that is, when all the PIN diode switches are in ON mode and when all the PIN diode switches are in OFF mode. These PIN diode switches are located on the feed line, between Lf1 and Lf2 as shown in Figure 1(b). Figure 8 shows the simulated current distributions at each layer in different switching modes. In the ON mode, the feed line lengths of Lf1 and Lf2 are connected to each other, thus generating the major signal to activate all the I-shaped and H-shaped aperture slots in the ground, as shown in Figure 8(a). Next, the current from I-shaped aperture slots will radiate and pass through to the bottom patches on layer 2, while the current from H-shaped aperture slots will radiate to the top patches on layer 1. As explained, we can see that the current distributions radiate equally around top and bottom patches. At this stage, both top and bottom patches will be combined, thus resulting in larger patches. As a result, the antenna is resonant at low frequency of 2.6 GHz. In contrast, when all PIN diode switches are in OFF mode, the feed line lengths of Lf1 and Lf2 are disconnected from each other. Therefore, the signal from Lf1 will radiate to I-shaped aperture slots while the signal from Lf2 does not radiate to the H-shaped aperture slots. However, as shown in Figure 8(b), we can see that there is still some current around the H-shaped aperture-coupled antenna. As a result, the current from the I-shaped aperture slots strongly radiates to the bottom patches. Meanwhile, the current around the top patches acts as a parasitic element. The activation of the bottom patches allows the antenna to operate at a high resonant frequency of 3.5 GHz with higher gain compared to ON mode. Based on this concept, the frequency reconfigurability can be obtained by controlling the coupling on the ground.
Simulated current distributions at each layer during (a) ON mode and (b) OFF mode.
3.5. E-Plane and H-Plane Radiation Patterns
As illustrated in Figure 9, the radiation patterns of the proposed antenna are measured and simulated in two planes—either in H-plane (x-z direction) with phi = 0° or in E-plane (y-z direction) with phi = 90°. Figure 9(a) shows the simulated and measured the radiation patterns in ON mode at 2.6 GHz, while Figure 9(b) in OFF mode. Based on both results, there is a good agreement between the simulation and measurement results. However, some minor discrepancies that occurred during the measured results are due to a few factors such as the effects of the switching circuit components on the feed line and the complexity during the gluing of all the substrate layers to get the perfect alignment in each layer. These radiation patterns describe that the proposed antenna is directed to 32° with 76.5 MHz bandwidth in ON mode, while, in OFF mode, the proposed antenna is directed to 28° with 69.5 MHz. Besides that, the HPBW in ON mode is 37.3° and in OFF mode is 35.0°. Moreover, the gain is equal to 9.415 dBi and 10.49 dBi during the ON or OFF mode, respectively (Figure 10).
Radiation patterns of the proposed antenna in polar plot and 3D view during (a) ON mode and (b) OFF mode.
Simulated gains during (a) ON mode at 2.6 GHz and (b) OFF mode at 3.5 GHz.
4. Practical Indoor Antenna Measurement
The proposed antenna, known as an antenna under test (AUT), acts as a transmitter (Tx) antenna to test the capability of the antenna to transmit the signal to the receiver (Rx) and to verify the distance based on the power transmit (Pt) signal. Therefore, the power received (Pr) signal measurement is carried out at the Rx side when the distances between the Tx and Rx vary from 1 m to 7 m. In this work, the measurement was conducted in two conditions, which are in an empty room (8.95 m × 6.17 m) and within two small rooms (between meeting room and supervisor’s room) with the same power transmit (Pt). All the rooms were located in the Antenna Research Group lab (Figure 11). Firstly, the practical indoor propagation was carried out in an empty room with the minimum Pt of 0 dBm supplied to the AUT so the whole area of the empty room was covered. However, at the distance of 7 m, no power received (Pr) signal was detected on the Rx side. This finding proves that, with the minimum of Pt at 0 dBm, the AUT has the capability to transmit the signal to the Rx side with maximum distance of 6 m in an empty room. During the indoor measurements, the actual frequencies from the return loss experimental results, namely, 2.55 GHz (ON mode) and 3.49 GHz (OFF mode), were used to inject the signal at the RF signal generator. The AUT measurement was carried out at the 28° and 32° during the ON or OFF mode, respectively.
The plan of the empty room and within two small rooms in the Antenna Research Group lab, where the PL and Pr were carried out.
The indoor practical antenna measurement setup is shown in Figure 12. Both AUT and Rx positions at a height of 1 m must be placed face-to-face and aligned towards each other to obtain a line-of-sight (LOS) condition. At the Tx side, the signal generator with Wiltron 6647B model (10 MHz to 20 GHz) was used to inject the RF signal to the AUT, while the equipment at the Rx side was a receiving antenna (Horn antenna with ED200C model) connected to the spectrum analyzer (Advantest U3751).
The practical antenna measurement setup.
Theoretically, the path loss (PL) versus the distance between the Tx and Rx is described in the ground reflection (two-ray) propagation model [12], as formula shown in (1). Consider
(1)PL=32.44+[20logd]+[20logf]-GT-GR+[Totherlosses],
where d is the distance (km), f is the frequency (MHz), GT is the transmitter (AUT) gain (dBi), GR is the receiver gain (dBi), and TOtherlosses includes the floor, wall, and glass coefficient, which are defined as Tfloor=13 dB, Twall=2.2 dB, and Tglass=0.25 dB, respectively [12]. The GT gain value refers to the AUT during the simulation and the GR gain value refers to the Horn antenna (Rx) with 10 dBi gain. In this work, during the measurement in the empty room, only the floor loss (13 dB) was considered, while, within the two rooms, the floor loss included the floor, two walls, and two glasses, thus making up other losses equal to 17.9 dB. Next, the Pr is determined following (2) and the theoretical results will be compared with the measurement results in an empty room or two small rooms as follows:
(2)PL=10log[PtPr].
Figures 13(a) and 13(b) show the power received signal comparison between theoretical and measurement results, in an empty room and within two small rooms, during ON and OFF modes. The Pr values between the theoretical and measured results either in an empty room or within two rooms are rather similar. As shown in both figures, when the distance between Tx and Rx increases, the Pr signal decreases. The figures also show that when the same powers are used to transmit a signal between rooms, the received signal is lower compared to the received signal in an empty room. These results clearly show that when there is an obstacle, the signal transmission performance will be reduced. From the experimental results of this work, it is proven that the antenna can perform as a transmitter as the signal can be transmitted to the receiver side, either with or without obstacle. The AUT can cover a minimum distance of 6 m with minimum Pt equal to 0 dBm or 0.001 Watt. However, if the Pt is supplied with more than a 0 dBm power signal, the AUT has a capability to transmit the signal further.
Comparison between theoretical and measurement results of the distance between AUT and Rx (unit: m) in an empty room and within two rooms during (a) ON mode and (b) OFF mode.
5. Conclusion
In summary, the proposed antenna with a unique structure of a frequency-reconfigurable microstrip antenna has been presented. The proposed antenna used a combination of an aperture-coupled technique and stacked patch technology. In this design, the 2 × 2 radiating elements of top and bottom patches are etched on a different substrate layer to indicate different operating frequencies. New coupling methods have been implemented in aperture-coupled technique to control the activation of the selected aperture slots on the ground to radiate the waves to the particular patches and eventually to achieve frequency reconfigurability. By controlling all the PIN diode switches on the feed line, the proposed antenna has a capability to operate at two different operating frequencies, either at 2.6 GHz frequency in ON mode or at 3.5 GHz frequency in OFF mode. On top of that, the air gap with low dielectric constants, that is, 1.00, gives an advantage as the waves from the activated aperture slots on the ground are free to travel and radiate to particular radiating patches without passing through the substrate material layers. Moreover, the gain and bandwidth of the proposed antenna are considerably higher compared to using a single layer substrate as found in other antennas. It is confirmed that the antenna achieves a good agreement with the simulation. The results from this research have a great potential in wireless communication and can be used in long-term evolution (LTE) for band 7 and WiMAX applications, especially in Malaysia.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
This work was supported by the Faculty of Electrical Engineering (Antenna Research Group), UiTM, and the Ministry of Higher Education (MOHE), Malaysia. The authors also wish to thank the Research Intensive Grant (RIF) 600-RMI/DANA 5/3/RIF (189/2012) for the financial aid for this project.
CetinerB. A.Roqueta CrusatsG.JofreL.BiyikliN.RF MEMS integrated frequency reconfigurable annular slot antenna20105836266322-s2.0-7774934153410.1109/TAP.2009.2039300RodrigoD.JofreL.Frequency and radiation pattern reconfigurability of a multi-size pixel antenna20126052219222510.1109/TAP.2012.2189739Muhamud-KayatS.AliM. T.Mohd SallehM. K.Mohd RusliM. H.RamliN.AliasH.Truncated rhombus-like slotted antennas with aperture coupling technique20133918119810.2528/PIERL13021705Perruisseau-CarrierJ.Dual-polarized and polarization-flexible reflective cells with dynamic phase control2010585149415022-s2.0-7795198332310.1109/TAP.2010.2044333FerreroF.LuxeyC.StarajR.JacquemodG.YedlinM.FuscoV.A novel quad-polarization agile patch antenna2009575156215672-s2.0-6734927397610.1109/TAP.2009.2016790RodrigoD.RomeuJ.CapdevilaS.JofreL.A figure-of-merit for pattern reconfigurable antennas20136131448145310.1109/TAP.2012.2228619BaiY.-Y.XiaoS.TangM.-C.DingZ.-F.WangB.-Z.Wide-angle scanning phased array with pattern reconfigurable elements20115911407140762-s2.0-8045514539910.1109/TAP.2011.2164176AbuTarboushH. F.NilavalanR.CheungS. W.NasrK. M.Compact printed multiband antenna with independent setting suitable for fixed and reconfigurable wireless communication systems20126083867387410.1109/TAP.2012.2201108WuC.-H.MaT.-G.Self-oscillating semi-ring active integrated antenna with frequency reconfigurability and voltage-controllability20136173880388510.1109/TAP.2013.2256095ParkY. K.SungY.A reconfigurable antenna for quad-band mobile handset applications20126063003300610.1109/TAP.2012.2194672AliM.SayemA. T. M.KundaV. K.A reconfigurable stacked microstrip patch antenna for satellite and terrestrial links20075624264352-s2.0-3414709532110.1109/TVT.2007.891412JaisM. I.JamlosM. F. B.JusohM.SabapathyT.KamarudinM. R.AhmadR. B.AzremiA. A. A.-H.Bin AzmiE. I.SohP. J.VandenboschG. A. E.IshakN. L. K.A novel 2.45 GHz switchable beam textile antenna (Sbta) for outdoor wireless body area network (WBAN) applications201313861362710.2528/PIER13022610