The Role of Antennas on GNSS Pseudorange and Multipath Errors and Their Impact on DFMC Multipath Models for Avionics

Stefano Caizzone; Mihaela-Simona Circiu; Wahid Elmarissi; Christoph Enneking; Markus Rippl,; Matteo Sgammini

doi:10.33012/navi.532

REFERENCES

↵
1. Amielh, C.,
2. Chabory, A.,
3. Macabiau, C., &
4. Azoulai, L.
(2018). Importance of the antenna model to assess the GNSS multipath in airport environments. 2018 USNC-URSI Radio Science Meeting, Boston, MA. https://doi.org/10.1109/USNC-URSI.2018.8602861
↵
1. Appleget, A., &
2. Bartone, C.
(2019). A consolidated GNSS multipath analysis considering modern GNSS signals, antenna, installation, and boundary conditions. Proc. of the 32nd International Technical Meeting of the Satellite Division of the Institute of Navigation (ION GNSS+ 2019). Miami, FL. https://doi.org/10.33012/2019.16924
↵
1. Caizzone, S.,
2. Circiu, M.-S.,
3. Elmarissi, W.,
4. Enneking, C., &
5. Winterstein, A.
(2019a). Airborne antenna and multipath error characterization for DFMC error standardization. Proc. of the 32nd International Technical Metting of the Satellite Division of the Institute of Navigation (ION GNSS+ 2019), Miami, FL. https://doi.org/10.33012/2019.16908
↵
1. Caizzone, S.,
2. Circiu, M.-S.,
3. Elmarissi, W.,
4. Enneking, C.,
5. Felux, M., &
6. Yinusa, K.
(2018). Multipath rejection capability analysis of GNSS antennas. Proc. of the 31st International Technical Meeting of the Satellite Division of the Institute of Navigation (ION GNSS+ 2018), Portland, OR. https://doi.org/10.33012/2018.16109
↵
1. Caizzone, S.,
2. Circiu, M.-S.,
3. Elmarissi, W.,
4. Enneking, C.,
5. Felux, M., &
6. Yinusa, K.
(2019b). Antenna influence on Global Navigation Satellite System pseudorange performance for future aeronautics multifrequency standardization. NAVIGATION, 66(1), 99–116. https://doi.org/10.1002/navi.281
1. Circiu, M.-S.,
2. Felux, M.,
3. Caizzone, S.,
4. Enneking, C.,
5. Fohlmeister, F.,
6. Rippl, M.,
7. Gulie, I.,
8. Ruegg, D.,
9. Griggs, J.,
10. Lazzerini, R.,
11. Hagemann, F.,
12. Tranchet, F.,
13. Bouniol, P., &
14. Sgammini, M.
(2020a). Airborne multipath models for dual-constellation dual-frequency aviation applications. Proc. of the 2020 International Technical Meeting of the Institute of Navigation, San Diego, CA, 162–173. https://doi.org/10.33012/2020.17135
↵
1. Circiu, M.-S.,
2. Caizzone, S.,
3. Felux, M.,
4. Enneking, C.,
5. Fohlmeister, F.,
6. Rippl, M., &
7. Sgammini, M.
(2020b). Airborne multipath and antenna error models from the DUFMAN Project. ICAO Navigation System Panel Meeting, Montreal.
↵
1. Circiu, M.-S.,
2. Caizzone, S.,
3. Felux, M.,
4. Enneking, C.,
5. Rippl, M., &
6. Meurer, M.
(2020c). Development of the dual-frequency dual-constellation airborne multipath models. NAVIGATION, 67(1), 61–81. https://doi.org/10.1002/navi.344
↵
1. Circiu, M.-S.,
2. Meurer, M.,
3. Felux, M.,
4. Gerbeth, D.,
5. Thölert, S.,
6. Vergara, M.,
7. Enneking, C.,
8. Sgammini, M.,
9. Pullen, S., &
10. Antreich, F.
(2017). Evaluation of GPS L5 and Galileo E1 and E5a performance for future multifrequency and multiconstellation GBAS. NAVIGATION, 64(1), 149–163. https://doi.org/10.1002/navi.181
↵
1. Harris, M.,
2. Miltner, M.,
3. Murphy, T.,
4. Raghuvanshi, A., &
5. van Graas, F.
(2017). Bounding GPS L1 antenna group delay variations for GNSS landing system integrity. Proc. of the 2017 International Technical Meeting of the Institute of Navigation, Monterey, CA, 591–605. https://doi.org/10.33012/2017.14878
↵
1. Murphy, T.,
2. Geren, P., &
3. Pankaskie, T.
(2007). GPS antenna group delay variation induced errors in a GNSS based precision approach and landing system. Proc. of the 20th International Technical Meeting of the Satellite Division of the Institute of Navigation (ION GNSS 2007). Fort Worth, TX, 2974–2989. https://www.ion.org/publications/abstract.cfm?articleID=7648
1. Murphy, T.,
2. Harris, M.,
3. Booth, J.,
4. Geren, P.,
5. Pankaskie, T.,
6. Clark, B.,
7. Burns, J., &
8. Urda, T.
(2005). Results from the program for the investigation of airborne multipath errors. Proc. of the 2005 National Technical Meeting of the Institute of Navigation, San Diego, CA, 153–169. https://www.ion.org/publications/abstract.cfm?articleID=5979
↵
1. Raghuvanshi, A., &
2. van Graas, F.
(2015). Characterization of airborne antenna group delay biases as a function of arrival angle for aircraft precision approach operations. Proc. of the 28th International Technical Meeting of the Satellite Division of the Insitute of Navigation (ION GNSS+ 2015), Tampa, FL, 3681–3686. https://www.ion.org/publications/abstract.cfm?articleID=13009
↵
1. RTCA
. (2018). DO-373: MOPS for GNSS airborne active antenna equipment for the L1/E1 and L5/E5a frequency bands. RTCA. https://standards.globalspec.com/std/13057420/rtca-do-373
↵
1. Salabert, F.
(2015). Operational benefits of multi constellation dual frequency GNSS for aviation. Coordinates, XI(3). https://mycoordinates.org/operational-benefits-of-multi-constellation-dual-frequency-gnss-for-aviation
↵
1. Van Dierendonck, A., &
2. Erlanson, R. J.
(2007). RTCA airborne GPS antenna testing and analysis for a new antenna Minimum Operational Performance Standards (MOPS). Proc. of the 2007 National Technical Meeting of the Insitute of Navigation, San Diego, CA, 692–701. https://www.ion.org/publications/abstract.cfm?articleID=7120
↵
1. Vergara, M.,
2. Sgammini, M.,
3. Thoelert, S.,
4. Enneking, C.,
5. Zhu, Y., &
6. Antreich, F.
(2016). Tracking error modeling in presence of satellite imperfections. NAVIGATION, 63(1), 3–13. https://doi.org/10.1002/navi.129

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[1] ↵
Amielh, C.,
Chabory, A.,
Macabiau, C., &
Azoulai, L.
(2018). Importance of the antenna model to assess the GNSS multipath in airport environments. 2018 USNC-URSI Radio Science Meeting, Boston, MA. https://doi.org/10.1109/USNC-URSI.2018.8602861

[2] Amielh, C.,

[3] Chabory, A.,

[4] Macabiau, C., &

[5] Azoulai, L.

[6] ↵
Appleget, A., &
Bartone, C.
(2019). A consolidated GNSS multipath analysis considering modern GNSS signals, antenna, installation, and boundary conditions. Proc. of the 32nd International Technical Meeting of the Satellite Division of the Institute of Navigation (ION GNSS+ 2019). Miami, FL. https://doi.org/10.33012/2019.16924

[7] Appleget, A., &

[8] Bartone, C.

[9] ↵
Caizzone, S.,
Circiu, M.-S.,
Elmarissi, W.,
Enneking, C., &
Winterstein, A.
(2019a). Airborne antenna and multipath error characterization for DFMC error standardization. Proc. of the 32nd International Technical Metting of the Satellite Division of the Institute of Navigation (ION GNSS+ 2019), Miami, FL. https://doi.org/10.33012/2019.16908

[10] Caizzone, S.,

[11] Circiu, M.-S.,

[12] Elmarissi, W.,

[13] Enneking, C., &

[14] Winterstein, A.

[15] ↵
Caizzone, S.,
Circiu, M.-S.,
Elmarissi, W.,
Enneking, C.,
Felux, M., &
Yinusa, K.
(2018). Multipath rejection capability analysis of GNSS antennas. Proc. of the 31st International Technical Meeting of the Satellite Division of the Institute of Navigation (ION GNSS+ 2018), Portland, OR. https://doi.org/10.33012/2018.16109

[16] Caizzone, S.,

[17] Circiu, M.-S.,

[18] Elmarissi, W.,

[19] Enneking, C.,

[20] Felux, M., &

[21] Yinusa, K.

[22] ↵
Caizzone, S.,
Circiu, M.-S.,
Elmarissi, W.,
Enneking, C.,
Felux, M., &
Yinusa, K.
(2019b). Antenna influence on Global Navigation Satellite System pseudorange performance for future aeronautics multifrequency standardization. NAVIGATION, 66(1), 99–116. https://doi.org/10.1002/navi.281

[23] Caizzone, S.,

[24] Circiu, M.-S.,

[25] Elmarissi, W.,

[26] Enneking, C.,

[27] Felux, M., &

[28] Yinusa, K.

[29] Circiu, M.-S.,
Felux, M.,
Caizzone, S.,
Enneking, C.,
Fohlmeister, F.,
Rippl, M.,
Gulie, I.,
Ruegg, D.,
Griggs, J.,
Lazzerini, R.,
Hagemann, F.,
Tranchet, F.,
Bouniol, P., &
Sgammini, M.
(2020a). Airborne multipath models for dual-constellation dual-frequency aviation applications. Proc. of the 2020 International Technical Meeting of the Institute of Navigation, San Diego, CA, 162–173. https://doi.org/10.33012/2020.17135

[30] Circiu, M.-S.,

[31] Felux, M.,

[32] Caizzone, S.,

[33] Enneking, C.,

[34] Fohlmeister, F.,

[35] Rippl, M.,

[36] Gulie, I.,

[37] Ruegg, D.,

[38] Griggs, J.,

[39] Lazzerini, R.,

[40] Hagemann, F.,

[41] Tranchet, F.,

[42] Bouniol, P., &

[43] Sgammini, M.

[44] ↵
Circiu, M.-S.,
Caizzone, S.,
Felux, M.,
Enneking, C.,
Fohlmeister, F.,
Rippl, M., &
Sgammini, M.
(2020b). Airborne multipath and antenna error models from the DUFMAN Project. ICAO Navigation System Panel Meeting, Montreal.

[45] Circiu, M.-S.,

[46] Caizzone, S.,

[47] Felux, M.,

[48] Enneking, C.,

[49] Fohlmeister, F.,

[50] Rippl, M., &

[51] Sgammini, M.

[52] ↵
Circiu, M.-S.,
Caizzone, S.,
Felux, M.,
Enneking, C.,
Rippl, M., &
Meurer, M.
(2020c). Development of the dual-frequency dual-constellation airborne multipath models. NAVIGATION, 67(1), 61–81. https://doi.org/10.1002/navi.344

[53] Circiu, M.-S.,

[54] Caizzone, S.,

[55] Felux, M.,

[56] Enneking, C.,

[57] Rippl, M., &

[58] Meurer, M.

[59] ↵
Circiu, M.-S.,
Meurer, M.,
Felux, M.,
Gerbeth, D.,
Thölert, S.,
Vergara, M.,
Enneking, C.,
Sgammini, M.,
Pullen, S., &
Antreich, F.
(2017). Evaluation of GPS L5 and Galileo E1 and E5a performance for future multifrequency and multiconstellation GBAS. NAVIGATION, 64(1), 149–163. https://doi.org/10.1002/navi.181

[60] Circiu, M.-S.,

[61] Meurer, M.,

[62] Felux, M.,

[63] Gerbeth, D.,

[64] Thölert, S.,

[65] Vergara, M.,

[66] Enneking, C.,

[67] Sgammini, M.,

[68] Pullen, S., &

[69] Antreich, F.

[70] ↵
Harris, M.,
Miltner, M.,
Murphy, T.,
Raghuvanshi, A., &
van Graas, F.
(2017). Bounding GPS L1 antenna group delay variations for GNSS landing system integrity. Proc. of the 2017 International Technical Meeting of the Institute of Navigation, Monterey, CA, 591–605. https://doi.org/10.33012/2017.14878

[71] Harris, M.,

[72] Miltner, M.,

[73] Murphy, T.,

[74] Raghuvanshi, A., &

[75] van Graas, F.

[76] ↵
Murphy, T.,
Geren, P., &
Pankaskie, T.
(2007). GPS antenna group delay variation induced errors in a GNSS based precision approach and landing system. Proc. of the 20th International Technical Meeting of the Satellite Division of the Institute of Navigation (ION GNSS 2007). Fort Worth, TX, 2974–2989. https://www.ion.org/publications/abstract.cfm?articleID=7648

[77] Murphy, T.,

[78] Geren, P., &

[79] Pankaskie, T.

[80] Murphy, T.,
Harris, M.,
Booth, J.,
Geren, P.,
Pankaskie, T.,
Clark, B.,
Burns, J., &
Urda, T.
(2005). Results from the program for the investigation of airborne multipath errors. Proc. of the 2005 National Technical Meeting of the Institute of Navigation, San Diego, CA, 153–169. https://www.ion.org/publications/abstract.cfm?articleID=5979

[81] Murphy, T.,

[82] Harris, M.,

[83] Booth, J.,

[84] Geren, P.,

[85] Pankaskie, T.,

[86] Clark, B.,

[87] Burns, J., &

[88] Urda, T.

[89] ↵
Raghuvanshi, A., &
van Graas, F.
(2015). Characterization of airborne antenna group delay biases as a function of arrival angle for aircraft precision approach operations. Proc. of the 28th International Technical Meeting of the Satellite Division of the Insitute of Navigation (ION GNSS+ 2015), Tampa, FL, 3681–3686. https://www.ion.org/publications/abstract.cfm?articleID=13009

[90] Raghuvanshi, A., &

[91] van Graas, F.

[92] ↵
RTCA
. (2018). DO-373: MOPS for GNSS airborne active antenna equipment for the L1/E1 and L5/E5a frequency bands. RTCA. https://standards.globalspec.com/std/13057420/rtca-do-373

[93] RTCA

[94] ↵
Salabert, F.
(2015). Operational benefits of multi constellation dual frequency GNSS for aviation. Coordinates, XI(3). https://mycoordinates.org/operational-benefits-of-multi-constellation-dual-frequency-gnss-for-aviation

[95] Salabert, F.

[96] ↵
Van Dierendonck, A., &
Erlanson, R. J.
(2007). RTCA airborne GPS antenna testing and analysis for a new antenna Minimum Operational Performance Standards (MOPS). Proc. of the 2007 National Technical Meeting of the Insitute of Navigation, San Diego, CA, 692–701. https://www.ion.org/publications/abstract.cfm?articleID=7120

[97] Van Dierendonck, A., &

[98] Erlanson, R. J.

[99] ↵
Vergara, M.,
Sgammini, M.,
Thoelert, S.,
Enneking, C.,
Zhu, Y., &
Antreich, F.
(2016). Tracking error modeling in presence of satellite imperfections. NAVIGATION, 63(1), 3–13. https://doi.org/10.1002/navi.129

[100] Vergara, M.,

[101] Sgammini, M.,

[102] Thoelert, S.,

[103] Enneking, C.,

[104] Zhu, Y., &

[105] Antreich, F.

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The Role of Antennas on GNSS Pseudorange and Multipath Errors and Their Impact on DFMC Multipath Models for Avionics

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