Compact circularly polarized microstrip antennas for RFID reader applications
Microstrip antennas being low volume and conformable to host surfaces are replacing many conventional antennas. By using the appropriate feeding method and antenna design, the impedance bandwidth can be enhanced and the antenna size reduced to meet the desired device requirements. The main objec...
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| 其他作者: | |
| 格式: | Final Year Project |
| 語言: | English |
| 出版: |
2009
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| 主題: | |
| 在線閱讀: | http://hdl.handle.net/10356/17633 |
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| 總結: | Microstrip antennas being low volume and conformable to host surfaces are
replacing many conventional antennas. By using the appropriate feeding method and
antenna design, the impedance bandwidth can be enhanced and the antenna size
reduced to meet the desired device requirements.
The main objective of the project is to fabricate a compact single feed circularly
polarized (CP) microstrip antenna for RFID reader applications. A few research
topics were undertaken. The first topic looks at the design of a broadband CP stacked
microstrip antenna. Circular polarization is achieved by introducing an asymmetry
and feeding the antenna at an angle of 45º using a coaxial probe. The proposed
antenna was found to have a wide AR bandwidth of about 11.1% and a gain of more
than 5.0 dBic for the broadband CP stacked microstrip antenna. The second topic
looks at perturbations which are used to obtain CP radiation. The designs of three
different compact CP microstrip antennas are discussed. From the study, the Y-slot
configuration was able to achieve a lower resonating frequency compared to other
designs with similar patch size. This translates to a significant reduction in size
compared to the broadband stacked microstrip antenna. However, the drawbacks of
this reduction in size led to reduced gain and a narrower AR bandwidth. The Y-slot
antenna achieved a minimum S11 of -21.8 dB at 935 MHz and an AR bandwidth of
only 1.3%. The gain obtained was more than -10dBic for the frequency range of 850
– 950 MHz. The last topic studies the effect of slits on the size of the antenna and the
resonant frequency. The introduction of the slits provided a length reduction of about
6.9%. The proposed CP microstrip antenna is attractive for RFID reader applications
which require compact size, good AR bandwidth and reasonable gain. All the
antenna designs were built and simulated by the Zealand IE3D software. |
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