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Space Research Center PAS, Warsaw, Poland
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- PublicationOpen AccessAutoscala: an aid for different ionosondes(2010-06)
; ; ; ; ;Pezzopane, M.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione Roma2, Roma, Italia ;Scotto, C.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione Roma2, Roma, Italia ;Tomasik, L. ;Krasheninnikov, I.; ; ;Autoscala is a software to automatically scale ionospheric characteristics from an ionogram. Initially it was only applied to the ionograms recorded by the AIS-INGV ionosondes installed at Rome (41.8N, 12.5E), Gibilmanna (37.9N, 14.0E), Italy, and Tucumán (26.9S, 294.6E), Argentina, that are not able to record the polarization of the received echo. Recently Autoscala was also applied to the ionograms recorded by the AIS-Parus ionosonde installed at Moscow (55.5N, 37.3E), Russia, that is not able to tag the received echo in terms of polarization, and by the VISRC2 ionosonde installed at Warsaw (52.2N, 21.1E), Poland, that is instead able to perform the polarization tagging of the ordinary and extraordinary echoes. This work shows different examples of processing performed on ionograms recorded by all these three different types of ionosondes.372 634 - PublicationRestrictedMonitoring, tracking and forecasting ionospheric perturbations using GNSS techniques(2012-12-20)
; ; ; ; ; ; ; ; ; ;Jakowski, N.; German Aerospace Center, Institute of Communications and Navigation, Neustrelitz, Germany ;Béniguel, Y.; IEEA, Paris, Courbevoie, France ;De Franceschi, G.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione Roma2, Roma, Italia ;Pajares, M. H.; Universitat Politecnica de Catalunya, Res. group of Astronomy and Geomatics, Barcelona, Spain ;Jacobsen, K. S.; Norwegian Mapping Authority, Geodetic Institute, Hønefoss, Norway ;Stanislawska, I.; Space Research Center PAS, Warsaw, Poland ;Tomasik, L.; Space Research Center PAS, Warsaw, Poland ;Warnant, R.; University of Liege, Unit of Geomatics – Geodesy and GNSS, Belgium ;Wautelet, G.; University of Liege, Unit of Geomatics – Geodesy and GNSS, Belgium; ; ; ; ; ; ; ; The paper reviews the current state of GNSS-based detection, monitoring and forecasting of ionospheric perturbations in Europe in relation to the COST action ES0803 ‘‘Developing Space Weather Products and Services in Europe’’. Space weather research and related ionospheric studies require broad international collaboration in sharing databases, developing analysis software and models and providing services. Reviewed is the European GNSS data basis including ionospheric services providing derived data products such as the Total Electron Content (TEC) and radio scintillation indices. Fundamental ionospheric perturbation phenomena covering quite different scales in time and space are discussed in the light of recent achievements in GNSS-based ionospheric monitoring. Thus, large-scale perturbation processes characterized by moving ionization fronts, wave-like travelling ionospheric disturbances and finally small-scale irregularities causing radio scintillations are considered. Whereas ground and space-based GNSS monitoring techniques are well developed, forecasting of ionospheric perturbations needs much more work to become attractive for users who might be interested in condensed information on the perturbation degree of the ionosphere by robust indices. Finally, we have briefly presented a few samples illustrating the space weather impact on GNSS applications thus encouraging the scientific community to enhance space weather research in upcoming years.431 65 - PublicationOpen AccessCOST 296 scientific results designed for operational use(2009-08)
; ; ; ; ; ; ; ; ; ; ; ;Stanislawska, I.; Space Research Centre PAS, Warsaw, Poland ;Belehaki, A.; National Observatory of Athens, Athens, Greece ;Jakowski, N.; DLR, Institute of Communications and Navigation, Neustrelitz, Germany ;Zolesi, B.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione Roma2, Roma, Italia ;Gulyaeva, T. L.; IZMIRAN, Troitsk, Moscow Region, Russia ;Cander, L. R.; Rutherford Appleton Laboratory, Chilton, UK ;Reinisch, B. W.; Center for Atmospheric Research, UMass Lowell, USA ;Pezzopane, M.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione Roma2, Roma, Italia ;Tsagouri, I.; National Observatory of Athens, Athens, Greece ;Tomasik, L.; Space Research Centre PAS, Warsaw, Poland ;Galkin, I.; Center for Atmospheric Research, UMass Lowell, USA; ; ; ; ; ; ; ; ; ; The main objective of the COST 296 Action «Mitigation of Ionospheric Effects on Radio Systems» is the establishment/ improvement of ionospheric services by coordinating the development of specific algorithms, models, and tools capable of operating in a near-real-time mode. Key elements of these activities are contributions related to monitoring, modelling, and imaging of customer-relevant ionospheric quantities. COST stimulates, coordinates, and supports Europe’s goals of development and global cooperation by providing high quality information and knowledge of ionospheric and plasmaspheric conditions enabling high quality and reliable operation of radio systems. It also provides a platform for sharing such tools as algorithms or models, and for the joint development of advanced technologies. It takes advantage of many national and European service initiatives, for example DIAS (http://dias.space.noa.gr), SWACI (http://w3swaci.dlr.de), ESWUA (http://www.eswua.ingv.it/ingv), RWC-Warsaw (http://www.cbk.waw.pl/rwc), the COST Prompt Ionospheric Database http://www.wdc.rl.ac.uk/cgibin/ digisondes/cost_database.pl, http://www.izmiran.ru/services, and others. Existing national capabilities are taken into account to develop synergies and avoid duplication. The enhancement of environment monitoring networks and associated instrumentation yields mutual advantages for European and regional services specialized for local user needs. It structurally increases the integration of limited-area services, and generates a platform employing the same approach to each task differing mostly in input and output data. In doing so it also provides a complementary description of the environmental state within issued information, as well as providing a platform for interaction among local end users, who define what kind of information they need, for system providers, who finalize the tools necessary to obtain required information, and for local service providers, who do the actual processing of data, tailoring it to specific users’ needs. Such an initiative creates a unique opportunity for small national services to consolidate their product design so that is no longer limited to their own activity, but can serve the wider European services. The development and improvement of techniques for mitigating ionospheric effects on radio systems by the COST 296 Action prepared those services that implemented the new design techniques for the newly announced EU and ESA policy-Space Situation Awareness (SSA). COST 296 developments applied to nowcasting and forecasting services are an essential input to the Operational SSA Ionosphere.300 282 - PublicationOpen AccessNear-Earth space plasma modelling and forecasting(2009-08)
; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ;Strangeways, H. J.; School of Electronic and Electrical Engineering, University of Leeds, Leeds, UK ;Kutiev, I.; Geophysical Institute, Bulgarian Academy of Sciences (BAS), Sofia, Bulgaria ;Cander, L. R.; Rutherford Appleton Laboratory, Didcot, UK ;Kouris, S.; Electrical and Computer Engineering Department, Aristotle University of Thessaloniki, Greece ;Gherm, V.; Department of Radiophisics, University of St. Petersburg, Russian Federation ;Marin, D.; University of Huelva, Huelva, Spain ;De La Morena, B.; Atmospheric Sounding Station El Arenosillo, INTA, Huelva, Spain ;Pryse, S. E.; Aberystwyth University, Aberystwyth, UK ;Perrone, L.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione Roma2, Roma, Italia ;Pietrella, M.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione Roma2, Roma, Italia ;Stankov, S.; Royal Meteorological Institute, Brussels, Belgium ;Tomasik, L.; Center for Space Research, Warsaw, Poland ;Tulunay, E.; Middle East Technical University (METU), Ankara, Turkey ;Tulunay, Y.; Middle East Technical University (METU), Ankara, Turkey ;Zernov, N.; Department of Radiophisics, University of St. Petersburg, Russian Federation ;Zolesi, B.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione Roma2, Roma, Italia; ; ; ; ; ; ; ; ; ; ; ; ; ; ; In the frame of the European COST 296 project (Mitigation of Ionospheric Effects on Radio Systems, MIERS)in the Working Package 1.3, new ionospheric models, prediction and forecasting methods and programs as well as ionospheric imaging techniques have been developed. They include (i) topside ionosphere and meso-scale irregularity models, (ii) improved forecasting methods for real time forecasting and for prediction of foF2, M(3000)F2, MUF and TECs, including the use of new techniques such as Neurofuzzy, Nearest Neighbour, Cascade Modelling and Genetic Programming and (iii) improved dynamic high latitude ionosphere models through tomographic imaging and model validation. The success of the prediction algorithms and their improvement over existing methods has been demonstrated by comparing predictions with later real data. The collaboration between different European partners (including interchange of data) has played a significant part in the development and validation of these new prediction and forecasting methods, programs and algorithms which can be applied to a variety of practical applications leading to improved mitigation of ionosphereic and space weather effects.302 151