Projects:2017s2-245 Novel Textile Antennas for Wearable Wireless Communications

From Projects
Revision as of 12:28, 4 June 2018 by A1710442 (talk | contribs)
Jump to: navigation, search

Members and Supervisors

Project members

- Hung Quoc DANG

- Baoqi Zhu

Supervisors

- Professor Christophe Fumeaux [1]

- Dr. Shengjian Jammy Chen [2]

Abstract

Wearable antennas have used in a wide range of applications such as: wireless communications, real-time tracking and wireless medical applications. Those antennas have to be integrated into or mounted on clothing and have the stable antenna performances according to the movement of the body. Different particular applications require different antenna performances include: antenna shape, dimension, resonance frequency, gain, direction and radiation efficiency.

This project primarily examines impacts of shorting strategies on the antenna performances. The different shorting strategies are considered in this study include: full shorting wall and two shorting posts which use flexible textile materials to realize. For each shorting methods, we realized three antenna use shorting with silver fabric wall, shorting eyelets and shorting with embroidered wall.

This project also considers impact of different substrate parameter on antenna performances. There feeding techniques include: microstrip line feed, coaxial-line feed and proximity-couple feed, are also examined.

Studies also design the dual-band textile wearable antennas which are able to operate in two ISM bands: (2.4 – 2.5) GHz and (5.725 – 5.875) GHz. All of three antennas satisfy desired requirements.

Introduction

Motivation

Nowadays, Wearable Technology has been widespread used worldwide. Wearable Technology can be found in many fields of life and business. The applications of Wearable Technology are able to be categorized into three different technologies: Advanced wearable products, AI platforms and Big Data.

Wearable antenna has been become one of the most important part in wireless devices. This type of antenna has been using in many fields such as wearable transmitter and receiver, body-sensor, wireless medical applications.


Different particular applications require different antenna performances include: antenna shape, dimension, resonance frequency, gain, direction and radiation efficiency. For antenna designs, shorting is a basic component. By using shorting techniques, we can adjust the antenna performances to adapt to specific requirements.

Currently, there are several popular shorting strategies such as: folded strip, embroidered vias, eyelet and PEC. Nevertheless, the shorting strategies which realized by flexible textile material have not been popular.

This project aims to realize the impact of different shorting strategies which use flexible textile materials on the antenna performances. Base on the knowledge about PIFA antenna and shorting strategies, this project is going to design dual-band textile wearable antennas which can operate in two ISM bands: (2.4 – 2.5) GHz and (5.725 – 5.875) GHz.

Objectives

The overall aim of project is to utilize different shorting strategies which use flexible textile materials for wearable antennas. In order to achieve the overall aims, the project’s process is divided by three specific aims.

The first focus is to understand the impacts of different shorting strategies on the antenna specifications. Those shorting strategies include full shorting wall and two shorting posts.

The second specific aim is to design and realize using full shorting wall. In this project, three types of full shorting wall include: shorting wall with silver fabric, shorting eyelets and shorting with embroidered wall, were realized to achieve particular antenna specifications.

The last but not least, the final optimized antenna designs were fabricated and measured for validation. The measured results show the experimentally differences between those shorting strategies for the antenna performances.

Background

Microstrip antenna

There are a lot of antenna types such as: linear wire antenna, aperture antenna, horn antenna and microwave antenna. Among those antennas, microstrip antenna is the most appropriate for wearable application due to several features [1]:

- Simple to manufacture;

- Low cost;

- Compact, lightweight, low-profile configurations;

- Comfortable to planar or non-planar surfaces;

- Robust when mounted on rigid surfaces;

- Versatile with respect to frequency, polarization, pattern and impedance.

Microstrip antenna [1]

Wearable antenna

Wearable antennas are the special kind of antenna that can be mounted on the clothing and used for communication purposes [7]. Several important factors need to be considered while designing wearable antennas include: appropriate antenna material, fabrication methods and analysis required for a wearable antenna design [7].

There are several conventional wearable antenna designs which include: planar dipoles, monopoles, and microstrip patches [7]. The popular planar microstrip antenna type is Planar Inverted-F Antenna (PIFA). The construction of the PIFA is shown in Fig. 3. In order to control the impedance bandwidth, we can vary the height of PIFA from the ground (less than 10mm). The feed line distance from the shorted edge of the PIFA is used to control the matching of the antenna [11]. PIFA construction is shown as:

PIFA.png

Wearable antennas are designed to work while mounting on clothing. Therefore, there are several specific requirements for this antenna type to work effectively and safely in a body-worn context.

Firstly, wearable antennas have to satisfy SAR standards [7]. This standard has been used to consider the amount of power absorbed by the human body. The SAR limit of IEEE is 1.6W/kg for any 1g of tissue [12].

In addition, due to working in body-worn context, wearable antennas must work effectively in different bending conditions. This requirement is especially important when the antenna is mounted on arm of leg which are rounded parts of the body [7].

Furthermore, the on-body measurements have to be considered while designing wearable antenna [7]. Depend on the particular purpose of antenna, it can be applied on different part on body such as: arm, leg, chest and back. Therefore, it is important to measure the antenna performances at particular body part.

Impacts of different shorting strategies on antenna performances

As mentioned above, the primary purpose of shorting strategies is to miniaturize the patch by creating something similar to electric wall. By using shorting strategies, the antenna dimension is reduced significantly.

While shorting wall is placed, the patch and ground are connected. The patch current goes straight to ground instead of be forced to be zero (without shorting wall). At this time, we only need to use the lower half of the cavity to radiate the same resonance frequency with the full patch antenna, the upper half mode is shorted. The fringing fields are shorted at the shorting wall position. At this time, only the fields near the feeding path are used for radiation. Although this method led to the reduction of antenna gain, all other basic antenna performances are similar to the full patch. The difference in Electric field distribution between the full patch antenna and the antenna using shorting wall is shown as:

Shorting.png


                                                                      Original E field.gif                      
                                                                      Impact of wall 1 E field.gif
                                                                  Original e field abs.gif              
                                                                  Impact of wall 1 e field abs.gif

New Wearable textile antennas

The processes used to create full shorting wall and two shorting posts antenna are shown as:

Full wall.png
Two posts.png

Three types of textile wearable antennas are realized in this section. Those antennas have to satisfy several specific desired requirements as:

- Operating in the 2.4 GHz and 5.8 GHz ISM bands. In particular, with respect to 50 Ω resistance, the 10dB return loss bandwidths are: (2.4 - 2.5) GHz and (5.725 - 5.875) GHz;

- Antenna radiation efficiencies are better than 80%;

- For wearable purpose, the vital requirements for antenna is small size, flexible and lightweight;

- Antenna performances have to be stable under several particular working conditions include: body movement, different bending conditions.

The conducting silver-fabric with 0.01 Ω/sq of resistance has been selected for the realization of the patch, feed line and ground plane. This material fulfills the requirements for wearable antenna without the compromising the performances of the antenna [4].

The lightweight, water resistance and flexible PF4-foam will be used for substrate. Based on the experiment in section 5.3.1, by using PF4-foam, the requirements of resonance frequency, antenna gain and efficiency are satisfied. Two layers of substrate are required for proximity-couple feed technique. Each substrate has 1.6mm of thickness, therefore, the total thickness is 3.2 mm.

In order to realize the shorting eyelets, we used copper which satisfies conductive, lightweight and easy fabrication requirements. Copper is also soft enough to easily put on the antenna.

Antenna designs

Antenna with shorting silver fabric wall

Antenna with full shorting silver fabric wall configurations are shown as:

                                 Full wall 11.png                          Full wall 22.png

Antenna with two shorting silver fabric strips configurations are shown as:

                                 Two wall 11.png                           Two wall 2.png

Antenna with shorting eyelets

Antenna with full shorting eyelets configurations are shown as:

                                 Full eyelets 1.png                          Full eyelets 2.png

Antenna with two shorting eyelets configurations are shown as:

                                 Two eyelet 1.png                           Two eyelet 2.png

Antenna with embroidered wall

Antenna with full embroidered wall configurations are shown as:

                                 Embroidered wall 1.png                          Embroidered wall 2.png

Antenna with two embroidered posts configurations are shown as:

                                 Two em 1.png                           Two em 2.png

Antenna fabrication

All antennas were fabricated in the following steps:

- Follow the dimension as simulation, the silver fabric was cut to 3 pieces for top patch, ground plane and feed line. The 1.6mm PF4-foam also was cut to 2 pieces for 2 substrate layers;

- The ground plane and feed line were attached to the lower substrate using fabric glue. SMA connector was connected to the feed line by conductive epoxy;

- The top patch and upper substrate will be processed later corresponding to different shorting strategies.

Antenna pieces.jpg


Shorting silver fabric wall

In order to make the shorting wall, the top patch was cut by 10mm longer than simulation (35 mm in particular in comparison with 25mm in simulation). The extended patch will be used to make the shorting wall. After that, the extended path of top patch was put through the substrates to make the shorting wall. This path was attached to ground by conductive epoxy. Fabrication process is shown as:


IMG 1155.jpg IMG 1156.jpg IMG 1157.jpg

Shorting eyelets

For shorting eyelets, at first, the top patch was attached on the upper substrate by fabric glue. After that, we use the eyelet punch to make holes for eyelets. We were use the eyelet tool to mount the eyelets to the antenna. The last step is to attach 2 substrates together by fabric glue. Fabrication processes for shorting eyelets are shown as:

IMG 1114.jpg IMG 1118.jpg Eyelet.jpg IMG 1158.jpg

Embroidered wall

In order to fabricate embroidered wall, the top patch was also attached on the upper substrate by fabric glue. Embroidered wall model is created by PED-basic software. To create the embroidered wall, we used embroidery machine. The conductive thread was used for both top and bottom of embroidered wall. The stitch step length was selected as 3 mm and the embroidery machine was set to repeat a total of 5 times to increase the embroidered wall density. Embroidered wall fabrication process is shown as:

IMG 1153.jpg IMG 1152.jpg Embroidered wall.jpg IMG 1160.jpg

Simulation and measurement results

In order to measure the reflection coefficient |S11|, we use Network Analyzer machine. By using the same port to transmit signal to antenna and receive the reflection signal from antenna. The Network Analyzer will compare those signals and give us the result about reflection coefficient |S11|.

The radiation pattern at the center frequency as well as antenna gains and efficiencies corresponding to two frequency bands are validated by 3-D measurement in the anechoic chamber. Antenna was set in the Anechoic Chamber is shown as:

IMG 11511.jpg


Shorting silver fabric wall

Simulated and measured reflection coefficients diagram of antenna using shorting silver fabric wall is shown as:

S11 wall 00.jpg

We can see the good agreement between the simulated and measured values is proved. The antenna with shorting wall completely covers the 2.4 GHz ISM band and 5.8 GHz ISM band with the bandwidths are (2.38 - 2.51 GHz) and (5.69 - 5.88 GHz) respectively.

Measured and simulated realized co- and cross-polarizations for antenna using shorting silver fabric wall at both 2.45 and 5.8 GHz are shown as:

Wall 111.pngWall 222.pngWall 333.pngWall 444.png

Shorting eyelets

Simulated and measured reflection coefficients diagram of antenna using shorting eyelets is shown as:

S11 eye.jpg

We can see the good agreement between the simulated and measured values is proved. The antenna with shorting eyelets completely covers the 2.4 GHz ISM band (2.35 – 2.53 GHz) and 5.8 GHz ISM band (5.71 – 5.92 GHz).

Measured and simulated realized co- and cross-polarizations for antenna using eyelets at both 2.45 and 5.8 GHz are shown as:

Eye 1.pngEye 2.pngEye 3.pngEye 4.png

Embroidered wall

Simulated and measured reflection coefficients diagram of antenna using embroidered wall is shown as:

S11 em.jpg

We can see the good agreement between the simulated and measured values is proved. The antenna with embroidered wall completely covers the 2.4 GHz ISM band (2.36 – 2.51 GHz) and 5.8 GHz ISM band (5.7 – 5.89 GHz).

Measured and simulated realized co- and cross-polarizations for antenna using embroidered wall at both 2.45 and 5.8 GHz are shown as:

Em 1.pngEm 2.pngEm 3.pngEm 4.png

Comparison between different shorting strategies

Compare full shorting wall and two shorting posts:

Compare full two.JPG

Impacts of three different shorting strategies on antenna performances are shown as:

Compare shorting strategies.JPG

We can see that all three antennas using three different shorting strategies completely cover the 2.4 GHz and 5.8GHz ISM bands. For antenna using shorting eyelets, the gain and total efficiency at 2.45 GHz are much lower than the other antennas. The reason for this problem is the nonconductive material is covered around copper eyelets. It will reduce the antenna gain and efficiency at lower frequency. We can increase the gain and efficiency of antenna using shorting eyelets by using different eyelets which do not have the covered nonconductive paint. The shorting strategies in this case do not affect the antenna gain and efficiency at higher frequency much, therefore, the total efficiencies at higher frequency for all antenna are approximately similar.

In term of antenna design process:

- Antennas with shorting eyelet and shorting wall are easier to design than embroidered wall antenna.

- Antenna with embroidered wall need to take a long time to design due to the compression of top/ground plane and substrate around wall position.

In term of antenna manufacture:

- Antenna with shorting eyelet is easier to fabricate than other antennas. With shorting eyelets, the antenna dimension is hard to be changed during fabrication process.

- Antenna with shorting wall: the fabrication process is more complicated than other antennas. The size of patch is easier to be changed during the fabrication process.

- Antenna with embroidered wall: the fabrication process takes longest time. We have to design the embroidered wall on PED-Basic software first, and then use Embroidery Machine to embroider the conductive thread onto antenna. Nevertheless, it is hard to control position of embroidered wall. We have to do the embroider process carefully to avoid the conductive thread to be broken.

In term of mechanical properties: antenna with shorting eyelets and embroidered wall are more stable under the physical impacts than the antenna with shorting wall. Antenna with shorting eyelets can be used flexibly than others. We can use the eyelets to mount antenna on clothes and unmount antenna while not necessary.

All antennas completely cover the 2.4 GHz ISM band and 5.8 GHz ISM band which the narrowest bands are (2.38 - 2.51 GHz) and (5.69 - 5.88 GHz) respectively.

The gains and efficiencies of antenna with shorting wall and embroidered wall are similar and higher than antenna with shorting eyelets.

In conclusion, among those shorting strategies considered in this project, shorting eyelets is the best way to design and fabricate wearable antenna.

Conclusion

Project provides the information about wearable antenna and shorting strategies. The primary objective of this project is to consider the impacts of three shorting strategies on antenna performances include: full shorting wall, shorting eyelets and embroidered wall. All shorting strategies were realized by textile materials which are appropriate for wearable antennas.

Project successfully designed and fabricated three antennas using shorting strategies. Compare to several previous antennas, the antenna size is reduced significantly. In addition, all three antennas completely cover the 2.4 GHz ISM band (2.4 - 2.5 GHz) and 5.8 GHz ISM band (5.725 - 5.875 GHz). Those antennas also meet the requirements of low cost, easy to fabricate, flexible and lightweight.

In this project, shorting eyelets is the most appropriate method to design and fabricate wearable antenna.

Overall, the objectives of the project have been reached. The project results are also useful for future research.

Future project direction

Future work of this project is to design wearable antenna which can work in stable operation in practical settings.

The several aspects that affect the performance of wearable antenna include:

- Different type of fabric, textile on the antenna performances;

- The impact of typical body on antenna performance such as: skin, fat or muscle body.

- Ability to keep the antenna characteristics in acceptable range according to various movement of the body;

- Water resistance ability and wash ability;

- Capability to change the resonance frequency.

References

[1] Constantine A.Balanis, “Antenna Theory Analysis and Design”

[2] Sam Agneessens, Hendrik Rogier, “Compact Half Diamond Dual-Band Textile HMSIW On-Body Antenna”

[3] Shengjian Jammy Chen, Thomas Kaufmann, Damith Chinthana Ranasinghe, Christophe Fumeaux, “A Modular Textile Antenna Design using Snap-on Buttons for Wearable Applications”, IEEE Trans. Antennas Propag.

[4] Shengjian Jammy Chen, Thomas Kaufmann, Damith Chinthana Ranasinghe, Christophe Fumeaux, “Shorting strategies for a wearable L-slot planar Inverted-F antenna”, 2014 International Workshop on Antenna Technology: Small Antennas, pp.18-21, March 2014.

[5] Shengjian Jammy Chen, Damith Chinthana Ranasinghe, Cristophe Fumeax, “Snap-On Button as Detachable Shorting Vias for Wearable Textile Antennas”

[6] Thomas Kaufmann, Christophe Fumeaux, “Wearable Textile Half-Mode Substrate-Integrated Cavity Antenna Using Embroidered Vias”, IEEE Antennas and Wireless Propag. Lett., Vol. 12, 2013.

[7] N. H. M. Rais, P. J. Soh, F. Malek, S. Ahmad, N. B. M. Hashim, P. S. Hall, “A Review of Wearable Antenna”, in Proc. LAPC, Nov. 2009, p.p. 225.

[8] Roy B. V. B. Simorangkir, Yang Yang, Ladislau Matekovits, Karu P. Esselle, “Dual-Band Dual-Mode Textile Antenna on PDMS Substrate for Body-Centric Communications”, IEEE Antennas and Wireless Propag. Lett., Vol. 16, 2017.

[9] Hall, P. S., and Hao, Y., “Antennas and Propagation for Body Centric Communications”, European Conference on Antennas and Propagation (EuCAP), Nov. 2006.

[10] M. Tanaka, J. Jae-Hyeuk, “Wearable Microstrip Antenna”, The Antennas and Propagation Society International Symposium, 2003.

[11] P. Salonen, L.Sydanheimo, M. Keskilammi, M. Kivikoski, “A small planar inverted-F antenna for wearable application”, The Wearable Computers, 1999.

[12] IEEE Standards for Safety Levels with Request to Human Exposure to Radiofrequency Electromagnetic Fields, 3kHz to 300GHz, IEEE Std. C95.1. 1999.

[13] CST Microwave Studio – Workflow & Solver Overview