This paper presents a methodological approach to design a printed Inverted F antenna for the ISM 868 MHz band. For this design, the ground plane dimensions were kept fixed and the meandered radiating arm was modified to obtain the best compromise integration/performances. This approach was then generalized to design meandered printed inverted F antennas.
With the great progress that knows the domain of Human Health Monitoring (HHM), Internet of Things (IoT), and smart homes… more and more miniaturized systems have been developed based on the use of wireless technology for data transmission. The integration of these technologies requires the use of antennas with different frequencies: 868 MHz [
This integration process is often confronted with antennas size and bulk problematic explaining the different research works that aim at the development of miniaturized antennas and communicating systems.
Printed antennas are currently the most used type for the different mobile devices; they have a high degree of integration and manufacturing cost included in the PCB one. Among these antennas we have chosen to study a specific one named printed inverted F antenna (PIFA). For this type, several miniaturization techniques can be used such as meandering the radiation arm [
Printed antennas are generally used with coplanar waveguides to transfer the received or transmitted signals. As its name indicates, a waveguide helps to guide the electromagnetic waves over a certain distance. It is a special form of transmission line that exists in several formats and can be manufactured using the printed circuit technology. A coplanar waveguide consists of a central conductive line surrounded by the ground plane on both sides of the substrate.
The waveguide must present a characteristic impedance of 50 Ω to meet the antenna one. A model that permits to calculate the impedance of the waveguide is presented in [
The target device is a tracking system for the monitoring of elderly suffering from cognitive problems. The ISM antenna is used to ensure communication with an RF beacon implemented in the residence of the monitored person or to transmit data in the case of fugues via Sigfox network [
For our approach, the ground plane dimensions and form were chosen to meet the integration criteria of our research program. It will not be modified during the design and simulation process. A supplementary maximum width of 3.5 mm was fixed to integrate the 868 MHz antenna as presented in
The length of the PIFA antenna allows to set the resonance frequency and the stub dimensions determine the input impedance. For our design, a vertical direction for folding was adopted to minimize the total number of meanders. The total length of the unfolded strands is equal to λ/4 = 8.64 cm. The distance between the first strand and the ground plane was set to 500 µm and the various strands are characterized with a width of 250 µm and spaced by a distance of 50 µm from each other as presented in
Because of the capacitive coupling between the antenna strands, the resonance frequency is higher compared with a quarter wave antenna that has the same total length of the unfolded strands. An initial resonance frequency is obtained using the design presented in
From these results, the length of 8.64 cm is not adequate to obtain the target frequency and can be taken as a starting point for the radiating arm that will then be adjusted to tune the resonance frequency to 868 MHz.
To study the influence of the distance between the strands on the resonance frequency, several simulations were carried out by adjusting this distance from 50 µm to 200 µm while keeping the same total length of the radiating arm (8.64 cm). The different obtained reflection coefficients are presented in
As can be noticed in
After solving the problem of the antenna length, it remains to adjust the stub for a best reflection coefficient. To do this, several simulations were conducted by modifying the distance between the supply port and the shorted point.
For the proposed antenna, the feeding point is fixed and the shorted one can be moved to vary the input impedance. The final design is presented in
The reflection coefficient S11 of the proposed antenna is plotted in
The ISM antenna has a good reflection coefficient of −40 dB with a bandwidth of 6.5 MHz.
After the modeling work based on the use of ADS software, the PIFA was carried out on a FR4 substrate (
As our system is intended to be glued directly on the skin, an additional matching is necessary to take into account the presence of the human body effect. This is can be ensured using a Vector Network Analyzer (VNA) (
The measured reflection coefficient of the proposed antenna is presented in
The design approach presented in this paper can be generalized to design a meandered printed inverted F antenna. After the choosing of the target frequency, the waveguide can be dimensioned to ensure an impedance of 50 Ω. After that, the ground plane form and the area reserved to the integration of the antenna are fixed. The direction of the strands meandering is then chosen and the distance between them is set to the maximal possible value to minimize the capacitive coupling. An initial total length of λ/4 can be chosen for the antenna and then will be adjusted to obtain the target frequency before modifying the stub form to ameliorate the reflection coefficient. These steps are detailed in the flowchart presented in
This paper presents a methodological approach to design a meandered printed inverted F antenna. This method was explained using an ISM 868 MHz printed antenna integrated in a tracking device for elderly suffering from cognitive problems. The design methodology was described based on the use of the RF simulation software ADS to be adapted to any form of meandered PIFA. The RF model reference was cited only for the design of the coplanar waveguide that still unchanged for any antenna type. In our studies, we detailed the various constraints and parameters that must be taken into consideration such as the influence of the capacitive coupling between meanders on the antenna resonance frequency. This approach can be used as a guide and can be generalized for the simulation, design and integration of a meandered PIFA.
This work is part of SACHA project funded by French government and “Région Midi Pyrénées” in France. The partners of the project are Sigfox, Axible, Telecom Design companies, esanté and CHIVA hospital.
Hajjine, B., Escriba, C., Medale, D. and Fourniols, J.-Y. (2016) Algorithm and Design Methodology to Develop a PIFA with Optimized Reflection Coefficient for the ISM 868 MHz Band. Open Journal of Antennas and Propagation, 4, 166-175. http://dx.doi.org/10.4236/ojapr.2016.44013