Development of conductive textile antenna with bandwidth enhancement for wearable applications / Norsyahirah Izzati Zaidi
Electro-textile, known as e-textile is a conducting fabric that enables digital computing or electronic devices to be integrated into them to form wearable systems. Thus, e-textile antenna is designed to support many wearable applications, including tracking, navigation, mobile computing, public saf...
Saved in:
| Main Author: | |
|---|---|
| Format: | Thesis |
| Language: | English |
| Published: |
2021
|
| Subjects: | |
| Online Access: | https://ir.uitm.edu.my/id/eprint/61066/1/61066.pdf |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| id |
my-uitm-ir.61066 |
|---|---|
| record_format |
uketd_dc |
| spelling |
my-uitm-ir.610662022-06-07T07:50:44Z Development of conductive textile antenna with bandwidth enhancement for wearable applications / Norsyahirah Izzati Zaidi 2021-06 Zaidi, Norsyahirah Izzati Antennas Electro-textile, known as e-textile is a conducting fabric that enables digital computing or electronic devices to be integrated into them to form wearable systems. Thus, e-textile antenna is designed to support many wearable applications, including tracking, navigation, mobile computing, public safety, entertainment, and wireless communication. The conventional textile-based antenna uses copper tape and copper foil as the radiating element. However, the usage of copper tape and copper foil leads to sustainability issues as these materials can be easily detached after being worn and washed several times. In terms of accuracy, previously, the conventional conductive textile antenna suffered some design issues where the measurement data were not in good agreement with the expected result. This scenario happened due to the inaccurate modelling during simulation where a solid copper sheet with different electrical properties was used to represent e-textile layer. Besides, for some conductive textiles, the electrical properties are also influenced by the interweaving ratio of the weaving pattern. Other than that, mechanical deformations such as bending due to human’s small movements can also affect the antenna resonant frequency, as it will be detuned when the antenna is bent. Therefore, a self-manufactured conductive textile with a more structurally practical structure for antenna design is proposed in this research work. To improve the design accuracy, the structure of e-textile was developed using TexGen software during antenna simulation stage. A performance analysis of the e-textile based on different weaving patterns such as plain, satin and twill was also conducted. Other than that, optimization is performed to produce an optimum 1.575 GHz GPS antenna that can operate under deformed condition. In this research, two conductive textiles; copper covered yarn and copper core sheathed yarn were constructed using hollow-spindle-spinning technique. The developed fabric structures were designed through physical model using TexGen and also based on accurate electrical properties using I-V probe method. Various designs of textile antennas were simulated and measured under E-plane and H-plane bent conditions to validate the reliability of the antenna under deformed condition. An antenna with a defected ground structure (DGS) is developed to solve the bending problem. Through the analysis, copper covered is the best conductive yarn with the copper-to-polyester composition ratio of 82.90% to 16.36%. Meanwhile, satin is the best weaving pattern for conductive textiles with a conductivity of 9.26 x104 S/m. Based on the study, the bending on E-plane shows significant frequency detuning as compared to H-plane. The implementation of DGS has increased the antenna bandwidth from 74 MHz to 226 MHz. Therefore, by having a wider bandwidth, the antenna can operate at the desired frequency even during bending. The antenna performance was verified through the simulation and measurement results. In conclusion, this project has minimized the frequency detuning effect during bending through DGS implementation, which is a common issue in all textile antennas. Plus, the development of the new conductive textile provides an integrated solution for the antenna and fabric as one module. An alternative way to simulate an accurate fabric structure of the textile antenna is also shown in this project. 2021-06 Thesis https://ir.uitm.edu.my/id/eprint/61066/ https://ir.uitm.edu.my/id/eprint/61066/1/61066.pdf text en public phd doctoral Universiti Teknologi MARA College of Engineering Abd Rahman, Nurul Huda (Ir. Dr.) |
| institution |
Universiti Teknologi MARA |
| collection |
UiTM Institutional Repository |
| language |
English |
| advisor |
Abd Rahman, Nurul Huda (Ir. Dr.) |
| topic |
Antennas |
| spellingShingle |
Antennas Zaidi, Norsyahirah Izzati Development of conductive textile antenna with bandwidth enhancement for wearable applications / Norsyahirah Izzati Zaidi |
| description |
Electro-textile, known as e-textile is a conducting fabric that enables digital computing or electronic devices to be integrated into them to form wearable systems. Thus, e-textile antenna is designed to support many wearable applications, including tracking, navigation, mobile computing, public safety, entertainment, and wireless communication. The conventional textile-based antenna uses copper tape and copper foil as the radiating element. However, the usage of copper tape and copper foil leads to sustainability issues as these materials can be easily detached after being worn and washed several times. In terms of accuracy, previously, the conventional conductive textile antenna suffered some design issues where the measurement data were not in good agreement with the expected result. This scenario happened due to the inaccurate modelling during simulation where a solid copper sheet with different electrical properties was used to represent e-textile layer. Besides, for some conductive textiles, the electrical properties are also influenced by the interweaving ratio of the weaving pattern. Other than that, mechanical deformations such as bending due to human’s small movements can also affect the antenna resonant frequency, as it will be detuned when the antenna is bent. Therefore, a self-manufactured conductive textile with a more structurally practical structure for antenna design is proposed in this research work. To improve the design accuracy, the structure of e-textile was developed using TexGen software during antenna simulation stage. A performance analysis of the e-textile based on different weaving patterns such as plain, satin and twill was also conducted. Other than that, optimization is performed to produce an optimum 1.575 GHz GPS antenna that can operate under deformed condition. In this research, two conductive textiles; copper covered yarn and copper core sheathed yarn were constructed using hollow-spindle-spinning technique. The developed fabric structures were designed through physical model using TexGen and also based on accurate electrical properties using I-V probe method. Various designs of textile antennas were simulated and measured under E-plane and H-plane bent conditions to validate the reliability of the antenna under deformed condition. An antenna with a defected ground structure (DGS) is developed to solve the bending problem. Through the analysis, copper covered is the best conductive yarn with the copper-to-polyester composition ratio of 82.90% to 16.36%. Meanwhile, satin is the best weaving pattern for conductive textiles with a conductivity of 9.26 x104 S/m. Based on the study, the bending on E-plane shows significant frequency detuning as compared to H-plane. The implementation of DGS has increased the antenna bandwidth from 74 MHz to 226 MHz. Therefore, by having a wider bandwidth, the antenna can operate at the desired frequency even during bending. The antenna performance was verified through the simulation and measurement results. In conclusion, this project has minimized the frequency detuning effect during bending through DGS implementation, which is a common issue in all textile antennas. Plus, the development of the new conductive textile provides an integrated solution for the antenna and fabric as one module. An alternative way to simulate an accurate fabric structure of the textile antenna is also shown in this project. |
| format |
Thesis |
| qualification_name |
Doctor of Philosophy (PhD.) |
| qualification_level |
Doctorate |
| author |
Zaidi, Norsyahirah Izzati |
| author_facet |
Zaidi, Norsyahirah Izzati |
| author_sort |
Zaidi, Norsyahirah Izzati |
| title |
Development of conductive textile antenna with bandwidth enhancement for wearable applications / Norsyahirah Izzati Zaidi |
| title_short |
Development of conductive textile antenna with bandwidth enhancement for wearable applications / Norsyahirah Izzati Zaidi |
| title_full |
Development of conductive textile antenna with bandwidth enhancement for wearable applications / Norsyahirah Izzati Zaidi |
| title_fullStr |
Development of conductive textile antenna with bandwidth enhancement for wearable applications / Norsyahirah Izzati Zaidi |
| title_full_unstemmed |
Development of conductive textile antenna with bandwidth enhancement for wearable applications / Norsyahirah Izzati Zaidi |
| title_sort |
development of conductive textile antenna with bandwidth enhancement for wearable applications / norsyahirah izzati zaidi |
| granting_institution |
Universiti Teknologi MARA |
| granting_department |
College of Engineering |
| publishDate |
2021 |
| url |
https://ir.uitm.edu.my/id/eprint/61066/1/61066.pdf |
| _version_ |
1783735207084425216 |