Análisis de calidad de observaciones GNSS de la nueva Red Geodésica de Jalisco de operación continua REGJAL: Prueba Piloto
Palabras clave:
GNSS, multitrayectoria, red geodésica GNSS, análisis de calidad
Resumen
En el presente estudio se analiza la calidad de las observaciones de las estaciones de operación continua GNSS de la nueva Red Geodésica del Estado de Jalisco (REGJAL), gestionada por el Centro de Sismología y Volcanología de Occidente a través del proyecto P24. Se estudian las observaciones generadas por 4 estaciones permanentes de un total de 63 días, contrastando los resultados con observaciones de 4 estaciones circunvecinas a la zona. Con el software TEQC se analiza la calidad de los datos, centrado en la variación de los valores de promedio móvil RMS de combinaciones lineales de trayectos múltiples (MP1 y MP2), además de la efectividad de las observaciones y los saltos de ciclo generados.
Citas
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Ao, M., Zhu, J., & Hu, Y. (2015). Comparative experiments on soil moisture monitoring with GPS SNR observations. Geomatics Inf Sci Wuhan Univ. Estey, L. H., & C. M. Meertens. (1999). TEQC: the multipurpose toolkit for GPS/GLONASS data. GPS Solutions, V3, 1: 42-49.
Herrada, A., Miranda, S., Fuentes, C., Torres Lobato, O., Pintos, H., & Smalley, R. (2010). MONITOREO DE LA CALIDAD DE DATOS GPS CONTINUO: LA ESTACIÓN UNSJ (SAN JUAN, ARGENTINA). GEOACTA(35), 55-62.
Herrera-Olmo, A., & De Lancy Pérez, M. C. (2014). Implementación de los efectos atmosféricos y de multipath en el desarrollo de un simulador de datos GNSS. Física de la Tierra, 26, 135-161. doi: http://dx.doi.org/10.5209/rev_FITE.2014.v26.46977
Hilla, S., & Cline, M. (2004). Evaluating pseudorange multipath effects at stations in the National CORS Network. GPS Solutions, 7(4): 253-267. doi:10.1007/s10291-003-0073-3
IGS. (2018). Current IGS Site Guidelines. Obtenido de https://kb.igs.org/hc/en-us/articles/202011433-Current-IGS-Site-Guidelines
León Soto, G., F. Ni., J., P. Grand, s., Sandoval, E., W. Valenzuela, R., Guzman speziale, M., . . . Domínguez Reyes, T. (2009). Mantle ow fl in the Rivera–Cocos subduction zone. Geophysical Journal International, 179, 1004-1012. doi:10.1111/j.1365-246X.2009.04352.x
Lin, K., Deng, Z., & Yin, L. (2018). Effective Multipath Mitigation Methods for RTK in Urban Environments. En J. Sun, C. Yang, & S.
Guo, China Satellite Navigation Conference (CSNC) 2018 Proceedings (Vol. 3, págs. 565-576). Springer. doi:https://doi.org/10.1007/978-981-13-0029-5_49
Liu, K., Zhang, S., Wang, Q., Zhang, Q., Zhang, J., & Nan, Y. (2017). GPS Signal to Noise Ratio Analysis and Using for Real-Time Tide Monitoring. En J. Sun, J. Liu, Y. Yang, S. Fan, & W. Yu, China Satellite Navigation Conference (CSNC) 2017 Proceedings (Vol. 1, págs. 151-161). Springer. doi:10.1007/978-981-10-4588-2_13
Ma, C., Tang, X., Liu, Y., Xiao, Z., & Sun, G. (2018). A Method of Carrier Phase Multipath Mitigation Based on Punctual Code Correlation Reference Waveform. En J. Sun, C. Yang, & S. Guo, China Satellite Navigation Conference (CSNC) 2018 Proceedings (Vol. 3, págs. 477-487). Springer. doi:https://doi.org/10.1007/978-981-13-0029-5_42
Nie, X., Xie, J., Liu, T., Huangfu, S., Xie, S., Jin, T., & Ciu, X. (2018). An Investigation on Influence of Navigation Satellites Solar Panels on the RNSS Signal Propagation and Ranging Error. En J. Sun, C. Yang, & S. Gou, China Satellite Navigation Conference (CSNC) 2018 Proceedings (Vol. 3, págs. 117-126). Springer. doi:https://doi.org/10.1007/978-981-13-0029-5_11
Núñez-Cornú, F., Córdoba Barbara, D., Dañobeitia, J., Bandy, W., Ortiz, M., & Bartolome, R. (2016). Geophysical studies across Rivera Plate and Jalisco Block, MEXICO: TsuJal project. Seismological Research Letters., 87(1), 59-72. doi:10.1785/0220150144
Park, K., Nerem, R., Schenewerk, M., & Davis, J. (2004). Site-specific multipath characteristics of global IGS and CORS GPS sites. Journal of Geodesy, 77, 799–803. doi:https://doi.org/10.1007/s00190-003-0359-9
Pirsiavash, A., Broumandan, A., & Lachapelle, G. (2017). Characterization of Signal Quality Monitoring Techniques for Multipath Detection in GNSS Applications. Sensors, 17(1579), 1-24. doi:10.3390/s17071579 Seeber, G. (2003). Satellite Geodesy (2nd ed.). Hannover: Walter de Gruyter.
Souto, M. (2014). Análisis de calidad y preprocesamiento de datos GNSS de la estación permanente UCOR (Córdoba, Argentina).Revista de La Facultad de Ciencias Exactas, Físicas y Naturales, 1(1), 91-95.
Swathi, N., Dutt, V., & Sasibhushana, G. (2016). An Adaptive Filter Approach for GPS Multipath Error Estimation and Mitigation. En R. Satapathy, N. Rao, S. Kumar, C. Raj, V. Rao, & G. Sarma, Microelectronics, Electromagnetics and Telecommunications (Vol. 372, págs. 539-546). Springer, New Delhi. doi:https://doiorg.ezproxy.uacj.mx/10.1007/978-81-322-2728-1_50
Üstün, A., & Yalvaç, S. (2018). Multipath interference cancelation in GPS time series under changing physical conditions by means of adaptive filtering. Earth Science Informatics, 11, 359–371. doi:https://doiorg.ezproxy.uacj.mx/10.1007/s12145-017-0331-5
Vázquez, B. G., & Grejner-Brzeziska, D. A. (2012). A case of study for pseudorange multipath estimation and analysis: TAMDEF GPS network. Geofísica internacional, 51(1), 63-72.
Vázquez, B. G., Bennett, R., & Spinler, J. (2013). Assessment of pseudorange multipath at continuous GPS stations in Mexico. Positioning, 4(03), 253-265. doi:10.4236/pos.2013.43025
Wang, C., Gao, Y., Cui, X., & Lu, M. (2018). Implementation of a Dual Estimate Tracking Based Multipath Mitigation Method on a Software Receiver. En J. Sun, C. Yang, & S. Guo, China Satellite Navigation Conference (CSNC) 2018 Proceedings (Vol. 3, págs. 329-339). Springer. doi:https://doi.org/10.1007/978-981-13-0029-5_29
Wang, S., Jia, X., Ji, G., Ai, Q., Guan, M., & Peng, T. (2017). Multipath Effect Analysis of Beidou Satellite Pseudorange and Its Corrections. China Satellite Navigation Conference (CSNC) 2017 Proceedings, 1, 547-559. doi:https://doiorg.ezproxy.uacj.mx/10.1007/978-981-10-4588-2_47
Wang, X., Zhang, Q., & Zhang, S. (2018). Sea level estimation from SNR data of geodetic receivers using wavelet analysis. GPS Solutions, 23(6), 1-14. doi:https://doi.org/10.1007/s10291-018-0798-7
Yeh, T., Y. A. Liou, C. S. Wang, & C. S. Chen. (2008). Identifying the degraded environment and bad receivers setting by using GPS data quality indices. Metrologia, 45:562-570
Ao, M., Zhu, J., & Hu, Y. (2015). Comparative experiments on soil moisture monitoring with GPS SNR observations. Geomatics Inf Sci Wuhan Univ. Estey, L. H., & C. M. Meertens. (1999). TEQC: the multipurpose toolkit for GPS/GLONASS data. GPS Solutions, V3, 1: 42-49.
Herrada, A., Miranda, S., Fuentes, C., Torres Lobato, O., Pintos, H., & Smalley, R. (2010). MONITOREO DE LA CALIDAD DE DATOS GPS CONTINUO: LA ESTACIÓN UNSJ (SAN JUAN, ARGENTINA). GEOACTA(35), 55-62.
Herrera-Olmo, A., & De Lancy Pérez, M. C. (2014). Implementación de los efectos atmosféricos y de multipath en el desarrollo de un simulador de datos GNSS. Física de la Tierra, 26, 135-161. doi: http://dx.doi.org/10.5209/rev_FITE.2014.v26.46977
Hilla, S., & Cline, M. (2004). Evaluating pseudorange multipath effects at stations in the National CORS Network. GPS Solutions, 7(4): 253-267. doi:10.1007/s10291-003-0073-3
IGS. (2018). Current IGS Site Guidelines. Obtenido de https://kb.igs.org/hc/en-us/articles/202011433-Current-IGS-Site-Guidelines
León Soto, G., F. Ni., J., P. Grand, s., Sandoval, E., W. Valenzuela, R., Guzman speziale, M., . . . Domínguez Reyes, T. (2009). Mantle ow fl in the Rivera–Cocos subduction zone. Geophysical Journal International, 179, 1004-1012. doi:10.1111/j.1365-246X.2009.04352.x
Lin, K., Deng, Z., & Yin, L. (2018). Effective Multipath Mitigation Methods for RTK in Urban Environments. En J. Sun, C. Yang, & S.
Guo, China Satellite Navigation Conference (CSNC) 2018 Proceedings (Vol. 3, págs. 565-576). Springer. doi:https://doi.org/10.1007/978-981-13-0029-5_49
Liu, K., Zhang, S., Wang, Q., Zhang, Q., Zhang, J., & Nan, Y. (2017). GPS Signal to Noise Ratio Analysis and Using for Real-Time Tide Monitoring. En J. Sun, J. Liu, Y. Yang, S. Fan, & W. Yu, China Satellite Navigation Conference (CSNC) 2017 Proceedings (Vol. 1, págs. 151-161). Springer. doi:10.1007/978-981-10-4588-2_13
Ma, C., Tang, X., Liu, Y., Xiao, Z., & Sun, G. (2018). A Method of Carrier Phase Multipath Mitigation Based on Punctual Code Correlation Reference Waveform. En J. Sun, C. Yang, & S. Guo, China Satellite Navigation Conference (CSNC) 2018 Proceedings (Vol. 3, págs. 477-487). Springer. doi:https://doi.org/10.1007/978-981-13-0029-5_42
Nie, X., Xie, J., Liu, T., Huangfu, S., Xie, S., Jin, T., & Ciu, X. (2018). An Investigation on Influence of Navigation Satellites Solar Panels on the RNSS Signal Propagation and Ranging Error. En J. Sun, C. Yang, & S. Gou, China Satellite Navigation Conference (CSNC) 2018 Proceedings (Vol. 3, págs. 117-126). Springer. doi:https://doi.org/10.1007/978-981-13-0029-5_11
Núñez-Cornú, F., Córdoba Barbara, D., Dañobeitia, J., Bandy, W., Ortiz, M., & Bartolome, R. (2016). Geophysical studies across Rivera Plate and Jalisco Block, MEXICO: TsuJal project. Seismological Research Letters., 87(1), 59-72. doi:10.1785/0220150144
Park, K., Nerem, R., Schenewerk, M., & Davis, J. (2004). Site-specific multipath characteristics of global IGS and CORS GPS sites. Journal of Geodesy, 77, 799–803. doi:https://doi.org/10.1007/s00190-003-0359-9
Pirsiavash, A., Broumandan, A., & Lachapelle, G. (2017). Characterization of Signal Quality Monitoring Techniques for Multipath Detection in GNSS Applications. Sensors, 17(1579), 1-24. doi:10.3390/s17071579 Seeber, G. (2003). Satellite Geodesy (2nd ed.). Hannover: Walter de Gruyter.
Souto, M. (2014). Análisis de calidad y preprocesamiento de datos GNSS de la estación permanente UCOR (Córdoba, Argentina).Revista de La Facultad de Ciencias Exactas, Físicas y Naturales, 1(1), 91-95.
Swathi, N., Dutt, V., & Sasibhushana, G. (2016). An Adaptive Filter Approach for GPS Multipath Error Estimation and Mitigation. En R. Satapathy, N. Rao, S. Kumar, C. Raj, V. Rao, & G. Sarma, Microelectronics, Electromagnetics and Telecommunications (Vol. 372, págs. 539-546). Springer, New Delhi. doi:https://doiorg.ezproxy.uacj.mx/10.1007/978-81-322-2728-1_50
Üstün, A., & Yalvaç, S. (2018). Multipath interference cancelation in GPS time series under changing physical conditions by means of adaptive filtering. Earth Science Informatics, 11, 359–371. doi:https://doiorg.ezproxy.uacj.mx/10.1007/s12145-017-0331-5
Vázquez, B. G., & Grejner-Brzeziska, D. A. (2012). A case of study for pseudorange multipath estimation and analysis: TAMDEF GPS network. Geofísica internacional, 51(1), 63-72.
Vázquez, B. G., Bennett, R., & Spinler, J. (2013). Assessment of pseudorange multipath at continuous GPS stations in Mexico. Positioning, 4(03), 253-265. doi:10.4236/pos.2013.43025
Wang, C., Gao, Y., Cui, X., & Lu, M. (2018). Implementation of a Dual Estimate Tracking Based Multipath Mitigation Method on a Software Receiver. En J. Sun, C. Yang, & S. Guo, China Satellite Navigation Conference (CSNC) 2018 Proceedings (Vol. 3, págs. 329-339). Springer. doi:https://doi.org/10.1007/978-981-13-0029-5_29
Wang, S., Jia, X., Ji, G., Ai, Q., Guan, M., & Peng, T. (2017). Multipath Effect Analysis of Beidou Satellite Pseudorange and Its Corrections. China Satellite Navigation Conference (CSNC) 2017 Proceedings, 1, 547-559. doi:https://doiorg.ezproxy.uacj.mx/10.1007/978-981-10-4588-2_47
Wang, X., Zhang, Q., & Zhang, S. (2018). Sea level estimation from SNR data of geodetic receivers using wavelet analysis. GPS Solutions, 23(6), 1-14. doi:https://doi.org/10.1007/s10291-018-0798-7
Yeh, T., Y. A. Liou, C. S. Wang, & C. S. Chen. (2008). Identifying the degraded environment and bad receivers setting by using GPS data quality indices. Metrologia, 45:562-570