Our multi-constellation receiver using EGNOS and Galileo

GISUY is a multi-constellation receiver, developed by Bluecover,  featuring a Global Navigation Satellite System (GNSS) chipset, capable of processing the positioning of multiple satellite systems accessible via USB and Bluetooth interfaces. The receiver is being tested since 2017 with various chipsets in different regions. Although the results highly depend on the testing environment, the best chipset performances were achieved with Telit GNSS products.  This chipset was recently tested with EGNOS and Galileo configurations, with the purpose to constitute viable redundant solution to monitor GNSS signals at airports. The tests of these two setup configurations were compared with the Standard Positioning Service (SPS) configuration (using GPS and GLONASS constellations) and also between each other. All tests were performed in similar conditions, namely by making acquisitions in open sky during fixed periods of 10 minutes and using the same active ceramic antenna (in some of cases sharing the same antenna).   The results of the tests and conclusions are presented hereafter .

EGNOS

EGNOS is the European Satellite based Augmentation System (SBAS) that supplements the GPS, GLONASS and Galileo constellations by reporting on the reliability and accuracy of their positioning data and sending out corrections. The system is composed by a network of ground stations and geostationary satellites, capable of providing corrections to achieve a horizontal position accuracy better than 7 metres. One main use of the system is in aviation.

The system started operations in July 2005 and by the time this assessment was performed, there were  the following 4 satellites in operations:

  • PRN120 NMEA 33
  • PRN123 NMEA 36
  • PRN136 NMEA 49 (testing)
  • PRN126 NMEA 39 (testing)
The 4 tests performed with a SBAS configuration, using both active and testing EGNOS satellites, were fully successful as presented in the table:

Date Time (UTC) Location Recordings Type EGNOS Satellites Avg Used Satellites Min Hor deviation (m) Avg Hor deviation (m) Max Hor deviation (m)
29/07/2018 21:09:51 Ramada Car Park (9th p) SBAS (test mode) 120 (33), 136(49) 15.3 0.47 0.6 0.69
26/07/2018 22:20:08 Ramada Car Park (9th p) SBAS (test mode) 136 (49) 15.43 0.41 0.76 1.26
26/07/2018 13:36:05 Campo Grande (2nd bench) SBAS (test mode) 120 (33), 136(49) 14.74 0.23 0.67 1.00
03/10/2018 17:08:00 Ramada Car Park (9th p) SBAS (test mode) 120 (33), 136(49) 15.42 0.15 2.21 3.54

The following findings were achieved:

  • The GISUY  receiver captured two EGNOS satellites (120# and 136#) from the current four satellites broadcasting messages,
  • the average horizontal deviation was 1.06m (that points to good accuracy),
  • in average there are less active satellites as result of the corrections,
  • EGNOS SBAS configuration was always better than the Non-SBAS configuration (SPS GPS-GLONASS) in all side-by-side tests performed.

Galileo

Galileo is the European GNSS, developed by the European Union, aiming to provide an independent high-precision positioning system from GPS, GLONASS and BeiDou systems. The use of basic Galileo services is free and open to everyone, while  higher-precision capabilities will be available for paying users. Galileo is intended to provide horizontal and vertical position measurements within 1-metre precision, and better positioning services at higher latitudes.

Galileo started offering Early Operational Capability (EOC) on December 2016, providing initial services with a weak signal. In July 2018, just before our GISUY tests, 4 new satellites were launched achieving a total of 26 satellites in space (including 17 in operations):

  • 17 operational satellites: E1…E5, E7…E9, E11, E12, E19, E24…E27, E30, E31;
  • 5 under commissioning: E21, E36, E13, E15, E33;
  • 4 unavailable/testing satellites: E20, E22 / E18, E14.

The complete 30-satellite Galileo system (24 operational and 6 active spares) is expected by 2020.

The 4 tests performed with this configuration demonstrated that GALILEO has already a good coverage, as presented in the table below:

Date Time (UTC) Location Recordings Type GALILEO & GPS Satellites Avg Active Satellites Min hor deviation (m) Avg hor deviation (m) Max hor deviation (m)
12/08/2018 22:05:08 Ramada Car Park (9th p) Galileo 8 GAL: 212, 207, 206, 229, 228, 209, 211, 230
10 GPS
14.53 1.16 1.48 4.86
01/10/2018 14:48:12 Campo Grande (1st bench) Galileo 3 GAL: 209,207,213;
9 GPS
11.05 0.17 1.19 1.93
02/10/2018 12:07:48 Ramada Car Park (9th p)  Galileo 3 GAL: 209,207,213;
9 GPS
14.46 0.14 0.92 2.97
03/10/2018 16:54:48 Ramada Car Park (9th p) Galileo 6 GAL: 223,231,211,216,234,230
9 GPS
13.35 2.23 2.66 3.19

The following findings were achieved:

  • The four tests performed with GISUY captured a total of 13 different Galileo satellites out of 17 satellites in operations,
  • there was one scenario with a maximum of 8 Galileo active satellites that is similar to the number of GPS satellites captured,
  • the average horizontal deviation was 1.56m that is considered good.

 

Conclusion

The testing performed with GISUY in Portugal with the configurations SPS GPS-GLONASS, EGNOS and SPS GPS-GALILEO achieved similar accuracies at open sky, with average horizontal deviations always below 2 m.

GISUY v3 configurations Recordings Avg Used Satellites Min horizontal deviation (m) Avg horizontal deviation (m) Max horizontal deviation (m)
SPS GPS-GLONASS 6 16.78 0.78 1.08 1.32
SBAS EGNOS (testing mode) 4 15.22 0.32 1.06 1.30
SPS GALILEO-GPS 4 13.35 0.93 1.56 3.24

The SBAS EGNOS has in average a better accuracy than Standard Positioning Service (Non-SBAS), and the SPS GPS-GLONASS is currently better than SPS GPS-GALILEO but the system may evolve.

As a conclusion, the GISUY configuration for monitoring GNSS signals (refer to SWAIR project) can use any of the these three configurations. The SBAS EGNOS shall be the default one in airports supporting GNSS vertical guidance (LPV) approaches, while SPS GPS-GLONASS on other  airports with GNSS-based approaches. The SPS GPS-GALILEO is promising configuration for future evolution.

When using  GISUY for surveying purposes, the Standard Positioning Service (SPS) and SBAS configuration are the most promising configurations. The SPS GPS-GLONASS may capture more signals in urban areas and dense forest and thus can be the default configuration while in open sky SBAS could be more performer.

Acknowledgements: these tests and activities was performed by Bluecover with the support of SWAIR project  in collaboration with Present Technologies and CITEUC.

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