3 Guidelines For Choosing A Passive UHF RFID Antenna

Introduction

Choosing a passive UHF RFID antenna can be a confusing task to those who are new to RFID. Passive RFID antennas typically look physically similar, so it is primarily their technical specifications that set them apart from each other.  When selecting an RFID antenna, the three most important specifications to consider are frequency range, gain/beamwidth, and polarization. We will discuss these factors below to help you better understand UHF RFID passive antennas.

Frequency Range

Each country has regulations that specify the frequency ranges for UHF RFID transmissions within that country. The three most prevalent frequency ranges for UHF RFID antennas are:

  • 902-928 MHz (US/FCC)
  • 865-868 MHz (EU/ETSI)
  • 860-960 MHz (Global)

When choosing an RFID antenna, be sure to select the frequency range that is right for your region. For example, an antenna tuned to the 865-868 MHz range and used in the United States would violate the regulations that govern the use of RFID equipment in the United States.

Gain/Beamwidth

Gain and beamwidth are grouped together because they are both electrical components of an antenna and are distinctly related. The higher the gain, the narrower (or smaller) the beamwidth. Higher gain creates a narrower area of coverage, but the beam will travel a longer distance. Beamwidth and gain are analogous to the beam of a flashlight. Check out the diagram below to see how differences in gain can drastically affect the antenna's beamwidth.

Beamwidth is determined by gain - the higher the gain, the more focused the beam.

The ideal beamwidth and gain will depend on your specific application. If you have many tags a short distance away, then you most likely don’t need a high gain antenna; it would be more advantageous to use a wide beamwidth antenna with relatively low gain as represented by the third image above.

Polarization

Most UHF RFID passive antennas are either linearly or circularly polarized. Linearly polarized antennas send RF waves in a single plane either horizontally or vertically. Circularly polarized antennas send RF waves in a circular motion either clockwise or counterclockwise. When the waves rotate clockwise, the antenna is a left-hand circularly polarized (LHCP) antenna; when the waves rotate counterclockwise, the antenna is a right-hand circularly-polarized antenna (RHCP).

When you have a setup with two separate RFID readers where antennas are facing each other, it's important to know if you have LHCP or RHCP antennas. When antennas face each other and emit waves in the same direction, null zones may occur where the waves overlap. Of note, in a single reader system, this issue won’t occur because the RFID reader only activates one antenna at a time. However, in a system where two antennas face each other and each is connected to a different reader, a combination of LHCP and RHCP creates a more effective read zone than if you use two LHCP or two RHCP antennas.

One exception to the rule above is when using  a bistatic system. If you use a bistatic system in a portal arrangement (antennas facing each other), the antenna that transmits the RF wave will need to be the SAME polarization as the antenna that receives the RF wave. So if a LHCP transmits the wave, the antenna that receives the RF wave will need to be LHCP in order to receive it most efficiently.

If all the tags in your application will be read the same orientation and at the same height, then it may be best to use a linearly polarized antenna. The main advantage to circularly polarized antennas is that they are better for applications where you cannot predict tag placement or orientation.

Conclusion

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