Projects:2018s1-195 Novel Flexible Materials for Wearable Antennas

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Project Team

Donald Dong Zhang

Dennis David Kimtai

Supervisors

Professor Christophe Fumeaux

Dr Shengjian (Jammy) Chen

Introduction

Natural Rubber, Buffalo Leather and Blue Foam are used as substrates for the realization of wearable antennas integrated into clothing.

Background and Motivation

The reliability of wearable communication systems can benefit from high performance antennas integrated into clothing. Emerging wearable communications systems will increasingly require flexible antennas which can be integrated into clothing and are able to adapt their shape to various movement of the body. This will allow exploiting the area of clothing to create efficient antennas in critical applications such as communications and tracking for defence or safety personnel, or monitoring of patients in a hospital.

Fig 1. Wearable antennas in defence
Fig 2. Wearable antennas in health care

Aims and Objectives

This project considers the use of widely available flexible materials as substrates for the realization of wearable antennas. The project focuses on material characterization and related design aspects. It involves antenna theory and computer-assisted design with state of the art electromagnetic simulations tools.

Material Characterization

The substrates materials should be lightweight, small size, flexible and robust to achieve good communication characteristics without much variation in performance.

Fig 3. Materials properties

Design Aspect

In this project antenna theory and computer simulation software (CST) was used to evaluate the use of different materials for two different types of wearable antennas:

  • Monopole Antenna
  • Planar Inverted-F Antenna (PIFA)

Monopole Antenna

Fig 4. Monopole Antenna using Leather substrate
Fig 5. Monopole Antenna using Rubber substrate
Fig 6. Monopole Antenna using Foam substrate

Planar Inverted-F Antenna (PIFA)

File:PIFA Antenna using Leather substrate.jpg
Fig 7. PIFA Antenna using Leather substrate
Fig 8. PIFA Antenna using Rubber substrate
File:PIFA Antenna using Foam substrate.jpg
Fig 9. PIFA Antenna using Foam substrate

Simulation Results

Reflection Coefficient

Fig 10. Reflection coefficient for Monopole Antenna (Leather Substrate)
Fig 11. Reflection coefficient for Monopole Antenna (Rubber Substrate)
Fig 12. Reflection coefficient for Monopole Antenna (Foam Substrate)


File:Reflection Coefficient for PIFA Antenna using Leather Substrate.jpg
Fig 13. Reflection coefficient for PIFA Antenna (Leather Substrate)
File:Reflection Coefficient for PIFA Antenna using Rubber Substrate.jpg
Fig 14. Reflection coefficient for PIFA Antenna (Rubber Substrate)
File:Reflection Coefficient for PIFA Antenna using Foam Substrate.jpg
Fig 15. Reflection coefficient for PIFA Antenna (Foam Substrate)

Directivity and Efficiency

Fig 16. Directivity and Efficiency for Monopole Antenna (Leather Substrate)
Fig 17. Directivity and Efficiency for Monopole Antenna (Rubber Substrate)
Fig 18. Directivity and Efficiency for Monopole Antenna (Foam Substrate)
File:Directivity and Efficiency for PIFA Antenna using Leather Substrate.jpg.jpg
Fig 19. Directivity and Efficiency for PIFA Antenna (Leather Substrate)
File:Directivity and Efficiency for PIFA Antenna using Rubber Substrate.jpg.jpg
Fig 20. Directivity and Efficiency for PIFA Antenna (Rubber Substrate)
File:Directivity and Efficiency for PIFA Antenna using Foam Substrate.jpg.jpg
Fig 21. Directivity and Efficiency for PIFA Antenna (Foam Substrate)

E field distribution

Fig 22. E field distribution for Monopole Antenna (Leather Substrate)

Fabrication

Monopole Antenna (Foam Substrate)

Fig 23. Monopole Antenna fabricated using Foam Substrate)

PIFA (Rubber Substrate)

Fig 24. PIFA Antenna fabricated using Rubber Substrate)

Achievements

Fabrication results are expected to match the results from simulation.