The Galileo and next-generation GPS signal plans have been devised to provide enhanced positioning accuracy in a wide range of challenging user scenarios, including the presence of multi-path, by means of the AltBOC and MBOC (Multiplexed Binary Offset Carrier) coding schemes.

For the most accurate services (Galileo E1/E5, GPS L1/L5 and corresponding BeiDou services) this results in signal spectra which have two main lobes spaced apart from a suppressed carrier centre-frequency.  In order to fully exploit this capability, an antenna must maintain a constant group-delay over a relatively wide fractional bandwidth.

However, it is technically difficult to configure a self-resonant circularly polarised antenna with such a wide fractional bandwidth. Current antenna solutions attempt to achieve this by employing a simple single-pole frequency-response in which the signal lobes are located at the extreme band edges – a less than satisfactory approach that invariably fails to fully exploit and benefit from the BOC coding scheme.

Helix Technologies is developing a consumer/automotive grade high-performance E1/E5 L1/L5 antenna with a two-pole circular-polarised frequency response that is optimised to match the Galileo and next generation GPS signal spectra whilst maintaining excellent circular polarisation properties.

Features of the antenna include:

  • Matched frequency responses to the multi-lobed Galileo and next-generation GPS spectra shapes – which are composed of a combination of wide-band and narrow-band signal services.
  • Equal group delay across modes to achieve consistent data clock-phase across the cluster of 3 modes forming the matched filter frequency response.

In addition, our dielectrically loaded antennas provide other inherent compelling technical advantages that include:

  • Unsurpassed gain/efficiency per unit of radiating volume.
  • Improved accuracy and reliability of GNSS systems in urban environments with significant multi-path.
  • Un-rivalled beam-width (omni-directionality).
  • Robust operation when orientated in non-optimal direction (not perfectly upright).
  • Effective operation even when tightly embedded within integrated devices.
  • Operation in slim-line packages where there is no room for a ground-plane.
  • Preserves radiation efficiency near absorbing objects (for example the human body).

For more information on our Galileo E1/E5 and next-generation GPS L1/L5 Wideband Antennas please get in Contact with us.

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