GEO 1249 ANNALS OF GEOPHYSICS, SUPPLEMENT TO VOL. 47, N. 2/3, 2004 1 Impact of variability of space environment on communications: Working Group 1 overview ANNA BELEHAKI (1) and IWONA STANIS ⁄LAWSKA (2) (1) National Observatory of Athens, Institute for Space Applications and Remote Sensing, P. Penteli, Greece (2) Space Research Centre, Warsaw, Poland The paper presents an overview of the scientific research carried out in the frames of Working Group 1 activities of the COST Action 271. The basic objective of this Working Group was the study of the impact of ionospheric variability on communications. The main achievements and an overall evaluation are reported. 1.1. INTRODUCTION The well-recognized impact of the space environment variability on communications affects many modern life activities and various sectors of economy. Therefore, the systematic develop- ment of both scientific research and applications in this field is a high priority. The WG 1 of COST Action 271 was established to serve this priority. The first Working Group (WG 1) is fo- cused on the impact of variability of space environment on communications, having two main objectives. The first is scientific oriented and concerns on the one hand the collection of histor- ical and new ionospheric and plasmaspheric data for nowcasting and forecasting purposes and on the other hand the development of methods and algorithms to monitor, predict and minimize the effects of ionospheric perturbations and variations on communications. The second concerns the stimulation of cooperation, at European level, in the domain of ionospheric and plasmaspheric prediction and forecasting for terrestrial and Earth-space communications including interactive repercussions on the corresponding standards in this field, taking into account users present and future needs. The need for cooperation in the field of scientific and technical research on this topic in Eu- rope is well established considering the situation worldwide in providing data and services for ionospheric and plasmaspheric nowcasting and forecasting. Several non-European organizations especially in the U.S.A. and Australia provide ionos- pheric data and products significant for scientific and operational applications, mainly based on the global network of ionospheric stations and GPS receivers. The Center for Atmospheric Re- search (University of Massachusetts, Lowell) provides access to ionospheric observations from the worldwide network of digisondes (http://ulcar.uml.edu/stationmap.html) and access to the DIgisonde DataBase (DIDB) through the SAO Explorer software (Reinisch et al., 2003). IPS Ra- dio Services, Australian Forecast Center (http://www.ips.gov.au/) provides HF information for Europe, North America, Australasia, and Asia, ionospheric maps of foF2 and TEC, estimates for 1250 Anna Belehaki and Iwona Stanis ⁄lawska the T index, HAP charts and HF-conditions. NorthWest Research Associates (http://www.nwra- az.com/) provides space weather and ionospheric scintillation services. ISES (http://www.ises- spaceweather.org/) encourages and facilitates near-real-time international monitoring and predic- tion of the space environment by the rapid exchange of data and its application to the proper serv- ices that can reduce the impact of space weather. On the other hand, the collection and distribution of ionospheric data and products in Europe for scientific and commercial use is currently possible mainly through the following Research Centers with open access to the public: Rutherford Appleton Laboratory in United Kingdom (http://www.wdc.rl.ac.uk/cgi-bin/digisondes/cost_database.pl), and Space Research Centre in Poland (RWC Warsaw http://www.cbk.waw.pl/rwc). Another important database with limited his- torical ionospheric observations was developed at ICTPAS, in Italy, under the previous COST Ac- tion 251 (http://cost251.ictp.trieste.it/). A major advantage of Europe with respect to other regions is the satisfactory coverage by ionospheric observatories that provide data for radio-communica- tion purposes. Some of the European observatories provide access to their observations on the In- ternet. A list of the European Ionospheric Observatories and their Internet addresses is presented in table 1.I. Nevertheless, the operations of European observatories are mainly independent creat- ing several barriers for transforming the available information into usable usable data, products and services for nowcasting and forecasting the impact of ionospheric variability on communications. It is therefore obvious that the European research community should exploit the major advantage of the dense network of observations, and the very significant research expertise on this field, aiming to develop products and services which are similar or even more sophisticated from the correspon- ding tools developed by other non-European organizations to serve the needs of terrestrial and earth- space communication. 1.2. OUR SCIENTIFIC RESULTS – OVERVIEW The challenges that COST 271 faced were wide and ambitious: monitoring of Earth environ- ment, assimilation of disparate data, development of end-user information, demonstration of its ap- plication to the experimental and operational service systems. Moreover, studies to influence the technical development and the implementation of new communication services, particularly for GNSS, as well as regional radio service systems were provided. The progress reached in the frames of WG 1 could be grouped as follows: 1) state-of-the-art study; 2) feasibility study; 3) databases and validation of prompt ionospheric parameters; 4) operational services; 5) modeling techniques leading to new operational services; 6) studies that improve our understanding of the upper at- Table 1.I. European Ionospheric Observatories. Rome (Italy) http://dps-roma.ingrm.it/ Chilton (U.K.) http://www.wdc.rl.ac.uk/ionosondes/view_latest.html Juliusruh (Germany) http://www.ionosonde.iap-kborn.de/ionogram.htm Tromsø (Norway) http://www.eiscat.rl.ac.uk/~ian/ionos_now.html Norilsk, Irkutsk, Yakutsk, Zhigansk (Russia) http://ds.iszf.irk.ru/ Dourbes (Belgium) http://digisonde.oma.be/ Kiruna, Uppsala, Lycksele (Sweden) http://www.irf.se/~ionogram/ Roquetes/Tortosa (Spain) http://www.obsebre.es/w3/ionosfer.php Athens (Greece) http://www.iono.noa.gr El Arenosillo (Spain) http://www.inta.es/iono/ Pruhonice (Czech Republic) http://147.231.47.3 Tromsø (Norway) http://www.eiscat.no/updating_dynasonde.html 1251 Impact of variability of space environment on communications: Working Group 1 overview mosphere structure and dynamics; and 7) advances in mathematical and physical tools development. The flowchart of WG 1 activities is given in fig. 1.1. In the following sections we will highlight the most important achievements. 1.2.1. State-of-the-art study The main objective of this COST Action is to study the effects of the upper atmosphere on ter- restrial and Earth-space communications. It was therefore, normally, the first step of our activi- ties, to list present and future anticipated terrestrial and Earth-space radio systems that their op- eration can be affected by ionospheric space weather disturbances (Tulunay and Bradley, 2004). In this respect the radio systems have been taken as including all those associated with commu- nications, navigation and surveillance. This distinction is particularly important because some phenomena, such as for example those concerned with varying signal group delays, influence the performance of navigation and surveillance systems, but are of lesser significance to systems con- cerned only with the transmission of intelligence. To assess the reliability and compatibility of a radio system, i.e. whether it will achieve its intended purpose for the necessary time in the pres- ence of the natural noise background, and whether it is compatible with co-channel and adjacent channel transmissions, appropriate propagation models are needed. These in turn depend on the relevant ionospheric models, which may be formulated in terms of either long-term predictions for system planning, or near-real-time forecasts for operational assessments. 1.2.2. Feasibility study A feasibility study regarding the development of new models to nowcast and forecast the im- pact of variability of space environment on communications was performed by Tulunay and Bradley (2004) and Bremer et al. (2004). The first target was to identify phenomena that can lead to im- pairments of radio systems and need to be modeled. A summary of individual impairments that can arise under some circumstances is given. A radio wave is specified in terms of five parame- ters: its amplitude, phase, direction of propagation, polarization and frequency. The principal ef- Fig. 1.1. Flow chart of Working Group 1 activities. 1252 Anna Belehaki and Iwona Stanis ⁄lawska fects of the ionosphere in modifying these parameters are considered. As a second task, the space weather key parameters creating impact adversely and significantly on propagation conditions have been identified. Different phenomena that arise under separate conditions with different time scales affect the ionosphere. Such phenomena are the solar flares, X-ray enhancements, coronal mass ejections and magnetic effects, and solar radio burst emissions. A detailed examination of the im- pact of these phenomena on radio propagation is given by Tulunay and Bradley (2004). A third task of the feasibility study focused on the definition of the potential effect of the long- term trends on prediction models (Bremer et al., 2004). Using observations of about 50 different ionosonde stations with more than 30 years data series of foF2 and hmF2, trends have been derived with the solar sunspot number R12 as index of the solar activity. The final result of this trend analysis is that the differences between the trends derived from the data of the individual stations are relatively large, the calculated global mean values of the foF2 and hmF2 trends, however, are relatively small. Therefore these global trends can be neglected for practical purposes and could not be taken into con- sideration in ionospheric models. As shown with the data of the ionospheric station Tromsø, howev- er, at individual stations the ionospheric tends may be markedly stronger and lead to essential effects in ionospheric radio propagation (Rogers et al., 2002). 1.2.3. Databases and validation of prompt ionospheric parameters 1.2.3.1. Databases Two very important databases of public access have been developed in the frames of Working Group 1 activities. The ionospheric database developed at Rutherford Appleton Laboratory (http://www.wdc.rl.ac.uk/ cgi-bin/digisondes/cost_database.pl) provides real-time and historical data from 11 European observa- tories: Athens, Chilton, Juliusruh, Rome, Tortosa, El Arenonsillo, Dourbes, Lerwick, Pruhonice, Stan- ley and Tromsø. The database provides all possible ionospheric parameters derived from the ionograms, and electron density profile data in plot and ASCII format (Stamper et al., 2004). This database is con- tinuously updated with real-time data that are transferred automatically after each sounding. The EISCAT database developed in the University of Grenoble (http://www-eiscat.ujf-grenoble.fr) stores ionospheric data. This data stems from measurements performed by the UHF EISCAT radars from 1981 to 1999. The database provides the classical incoherent scatter parameters (Ne, Te, Ti, Vi), the ionospheric electric field and the following reduced ionospheric parameters: the Integrated Total Electron Content (ITEC), the F2-layer maximum altitude and density with the corresponding plasma frequency (hmF2, NmF2 and foF2). 1.2.3.2. Direct validation of prompt ionospheric parameters An attempt has been made to validate the Ionospheric Total Electron Content (ITEC) based on statistical results from the analysis of long time serried of data. The ITEC is a relatively new pa- rameter (Reinisch and Huang, 2001) computed routinely from the European real-time digisondes and its validation was important to be able to use this parameter for operational applications. Sys- tematic comparison between ITEC and GPS derived TEC values, estimated for the same geo- graphic location (Athens) using 12 consecutive months of measurements, demonstrated that their residual differences have the same qualitative characteristics as the plasmaspheric electron content, as deduced from the diurnal and seasonal behavior and the variation during geomagnetic storms (Belehaki et al., 2003). It therefore resulted that the ITEC parameter is a realistic measure of the electron content up to 1000 km. 1253 Impact of variability of space environment on communications: Working Group 1 overview As a next step, a statistical investigation of the relationship between the ITEC and the total electron content, both calculated from the same set of electron density profiles that had been obtained from 4000 Malvern Incoherent Scatter Radar (ISR) profiles (Belehaki and Kersley, 2003), showed that especially during nighttime intervals the correlation between the two quantities is very high. This work is in progress to disclose to the derivation of the quantitatively relation of the two parameters. 1.2.3.3. Indirect validation of prompt ionospheric parameters A significant advantage of ionospheric sounding techniques during the last decade is the possi- bility to derive in real-time from the ionograms all important ionospheric parameters. The software algorithms built in the real-time ionospheric stations have become more and more intelligent and as a result the automatic derivation of prompt ionospheric parameters is very reliable. The development of nowcasting and forecasting models of the Earth’s upper atmosphere able to provide results that can be used for operational applications is based to a great extent on the availability of such real-time da- ta. In the frames of WG 1 activities two efforts have been made aiming to demonstrate the improve- ment in the models’ performance when updated with real-time parameters and therefore demonstrat- ing indirectly the validity of these autoscaled ionospheric parameters. This work is focused on two areas: improving standard ionospheric maps of the foF2 parameter (Zolesi et al., 2004) and improv- ing the IRI-2000 electron density profiles (Burešová et al., 2003). From another point of view, a comparison was made between the EISCAT ISR and ionosonde data (Lilensten et al., 2003) in an attempt to intercalibrate all instruments able to provide real- time data for space weather applications. A comparison of ionospheric measurements (foF2 pa- rameter) between EISCAT and two ionosondes located at the same place showed that the calibra- tion of the EISCAT Incoherent Scatter radar through ionosonde data is not a simple task and can lead to erroneous values when compared to GPS. Therefore a useful approach could be to cali- brate IS radars with the plasma line and to inter-calibrate ionosondes with the radars over a large set of cases. 1.2.4. Operational nowcasting and forecasting services The main category of deliverables provided by WG 1 concerns the development of operational nowcasting and forecasting services. A very important system has been set-up to operate on-line as a result of the collaboration between the Rutherford Appleton Laboratory and the National Ob- servatory of Athens (http://ionosphere.rcru.rl.ac.uk/). Real-time measurements of the critical fre- quency of F2-layer, foF2, and the propagation factor for a 3000 km range, M(3000)F2 from four European Digisondes operating in Athens, Rome, Chilton and Juliusruh and the Bz-component of the interplanetary magnetic field, Bz-IMF, from NASA Advanced Composition Explorer (ACE) spacecraft mission are combined for the development of a real-time dynamic system, oriented to monitor the ionospheric propagation conditions over Europe (Cander et al., 2004). The system en- ables extreme conditions to be quantified so that particularly for telecommunications planning likely variability bounds can be defined. The presented facility is available for both operational purposes and scientific studies and it will be upgraded to accept data from real-time digisondes op- erated in other areas of the planet according to the users’ requirements. Our community can also significantly benefit from the ionospheric nowcasting and forecasting in- formation provided by the Regional Warning Center of Warsaw in Poland (Stanis ⁄lawska and Zbyszyński, 2001) and the Space Weather Web operated by Rutherford Appleton Laboratory (Cander and Ciraolo, 2002; Cander, 2003; Cander et al., 2003). The services provided by the two research centers are listed in table 1.II. 1254 Anna Belehaki and Iwona Stanis ⁄lawska 1.2.5. Modeling techniques leading to new operational services Various natural and artificial indicators can perturb Earth’s environment and affect the radio-com- munication quality. Therefore, a deeper understanding of the complex, nonlinear physical processes would be very helpful for communication purposes. For instance, the identification of the mutual re- lations between the quantified ionospheric variability and communication circumstances is expected to enable the construction of relevant models for prediction and forecasting. Gathering recent find- ings and providing follow on studies on the coupling of different atmospheric layers, aiming to im- prove our understanding, is an important target of the WG 1 activities. The changes in the ionosphere and plasmasphere during space weather events, such as geomag- netic and ionospheric storms are very intense. Therefore a sophisticated approach taking into account the global solar wind – magnetosphere – ionosphere interaction is adapted. The investigations un- dertaken in the frames of COST 271 Action covered a wide spectrum of studies that improve and en- large our knowledge of the ionospheric behavior, which is a requirement for the reliable operation of telecommunication systems. The development and evolution of new techniques and models into operational tools was one of the most important challenges of WG 1 activities. We could distinguish the modeling techniques in- to two main groups: a) Regional ionospheric mapping (Burešová et al., 2003; Pietrella et al., 2003; Stanis ⁄lawska et al., 2004; Zolesi et al., 2004). b) Modeling and forecasting of ionospheric characteristics (Y.K. Tulunay et al., 2001; De Franceschi et al., 2002; E. Tulunay et al., 2002; Kutiev and Muhtarov, 2003; Stankov et al., 2003; Antonov et al., 2004). The main characteristics of these models are summarized in table 1.III. 1.2.6. Studies that improve our understanding of the upper atmosphere structure and dynamics Two very important studies have been carried out in the frames of the Working Group 1 activities aiming to study in depth the physics of the upper atmosphere structure and dynamics under the in- fluence of solar and geomagnetic disturbances as well as under anthropogenic activities. Table 1.II. Operational services for nowcasting and forecasting the state of the ionosphere over Europe. Research center Operational services Regional Warning Center of Warsaw – Up to 24 h foF2 forecasts at selected locations. (http://www.cbk.waw.pl/rwc) – Up to 24 h regional maps of the ionosphere. Space Weather Web operated by Rutherford – Real-time plots of foF2 and MUF(3000)F2 Appleton Laboratory at selected locations. (http://ionosphere.rcru.rl.ac.uk) – Archive of foF2 and MUF(3000)F2. – European TEC maps for the previous day. – Daily station TEC profiles for the previous day. – European TEC maps archive. – Archive of daily profiles of TEC for all European stations. – Ionospheric forecast maps of foF2, MUF(3000)F2 and NeQuick derived TEC provided up to 24 h ahead using STIF. – Archive of foF2, MUF and NeQuick derived TEC forecasts. 1255 Impact of variability of space environment on communications: Working Group 1 overview T ab le 1. II I. S um m ar y of t he m od el ’s c ha ra ct er is ti cs . M od el In pu t T ec hn iq ue O ut pu t R ef er en ce T ul un ay e t a l. (2 00 1) . F or ec as ts o f fo F 2 in m id la ti tu de t ro ug h. D at a dr iv en n eu ra l ne tw or k M E T U -N N m od el a pp li ed i n fo F 2 pr ed ic ti on s. K p in de x, lo ca l ti m e, ge og ra ph ic a nd i nv ar ia nt la ti tu de s an d fo F 2 va lu es . F or ec as ti ng f o F 2 in t he m id la ti tu de t ro ug h. S ta nk ov e t a l. (2 00 3) . E le ct ro n de ns it y pr of il es a t m id dl e la ti tu de s. C on st ru ct io n of t he b ot to m si de an d to ps id e el ec tr on p ro fi le , as su m in g E xp on en ti al ,E ps te in or C ha pm an t yp e of v er ti ca l de ns it y di st ri bu ti on . G ro un d- ba se d m ea su re m en ts o f th e to ta l el ec tr on c on te nt , io no sp he ri c ve rt ic al s ou nd in gs , an d em pi ri ca l va lu es o f th e up pe r tr an si ti on l ev el . R ea l- ti m e co ns tr uc ti on o f el ec tr on d en si ty p ro fi le s. T ul un ay e t a l. (2 00 2) . R ad ia l di st an ce o f th e E ar th ’s m ag ne to pa us e. N eu ra l ne tw or k sy st em pr op er ly c on st ru ct ed a nd tr ai ne d to l ea rn t he s ha pe o f th e m ag ne to pa us e. S ol ar w in d pa ra m et er s (v el oc it y, de ns it y, pr es su re ) an d in te rp la ne ta ry m ag ne ti c fi el d B z. M ag ne to pa us e cr os si ng . D e F ra nc es ch i et a l. (2 00 2) . F or ec as te d K p in de x. T im e w ei gh te d ac cu m ul at io n of t he 3 h K p in de x. K p in de x fo r pr ec ed in g ho ur s. F or ec as ti ng g eo m ag ne ti c ac ti vi ty . K ut ie v an d M uh ta ro v (2 00 3) . R el at iv e de vi at io n of t he f o F 2 pa ra m et er a s a fu nc ti on o f lo ca l ti m e an d K p in de x. D et er m in at io n of m od el p ar a- m et er s by f it ti ng t he m od el e x- pr es si on t o th e da ta i n ea ch b in . D at a fr om 5 5 io no so nd es , 11 ye ar s of o bs er va ti on s. G lo ba l em pi ri ca l m od el o f fo F 2 pa ra m et er . A nt on ov e t a l. (2 00 4) . F or ec as te d K p in de x. E st im at io n of a m od if ie d B z fu nc ti on w hi ch e xh ib it s a de la ye d re ac ti on t o B z ch an ge s. In te rp la ne ta ry m ag ne ti c fi el d B z, so la r w in d sp ee d an d pr es su re . K p in de x. S ta ni s⁄ l aw sk a et a l. (2 00 4) . T hr ee d im en si on al e le ct ro n co nc en tr at io n pr of il e in st an ta ne ou s m ap s. C on st ru ct io n of m ap s fr om sp at ia ll y di st ri bu te d m ea su re d da ta u si ng k ri gi ng a nd f it ti ng in te rp ol at io n te ch ni qu es . N eQ uI T U R m od el , el ec tr on de ns it y pr of il e m ea su re m en ts . U pd at in g th e N eQ uI T U R m od el to p ro du ce e le ct ro n co nc en tr at io n m ap s. B ur eš ov á et a l. (2 00 3) . D ef ic ie nc ie s of I R I- 20 00 w it h an d w it ho ut s to rm o pt io n. C om bi na ti on o f IR I- 20 00 N (h ) pr of il es w it h re al -t im e N (h ) pr of il es f ro m C O S T 2 71 s pa ce w ea th er d at ab as e. IR I- 20 00 , re al -t im e m ea su re m en ts o f io no so nd es . R ea l- ti m e up da ti ng o f IR I el ec tr on d en si ty p ro fi le s. P ie tr el la e t a l. (2 00 3) . R eg io na l m ap s of f o F 2. S pa ce w ei gh te d co rr ec ti on o f th e ba si c gr id v al ue s. T he S pa ce W ei gh te d Io no sp he ri c L oc al M od el (S W IL M ), pr om pt f o F 2 m ea su re m en ts . T he I S W IL M m od el f or in st an ta ne ou s m ap pi ng o f th e cr it ic al f re qu en cy o f th e F 2- la ye r in t he E ur op ea n re gi on . Z ol es i et a l. (2 00 4) . R eg io na l io no sp he ri c m ap pi ng . E st im at io n of t he e ff ec ti ve su ns po t nu m be r. S IR M , au to m at ic s ca le d fo F 2 va lu es f ro m E ur op ea n di gi so nd es . R ea l- ti m e up da ti ng o f th e S im pl if ie d Io no sp he ri c R eg io na l M od el ( S IR M ) fo r op er at io na l ap pl ic at io ns . 1256 Anna Belehaki and Iwona Stanis ⁄lawska A real tool for investigation of the thermospheric-ionospheric interaction under various geophys- ical conditions has been proposed by Michailov and Lilensten (2004). Ionospheric observations were widely used in the past to obtain thermospheric parameters such as winds, vertical plasma drifts in the equatorial F2-layer, and neutral composition winds. Incoherent Scatter Radar observations turned out to be the most appropriate for such analysis as they provide the most reliable and consistent set of ionospheric plasma parameters in E-, F1- and F2-regions. Much valuable and interesting infor- mation on thermospheric winds, temperature and neutral composition has been obtained from ISR data analysis. The main approaches are based on the use of energy equation for O+ ions to find atom- ic oxygen concentration and neutral temperature at the F2-region heights and on the momentum equation for O+ ions to retrieve meridional winds. In the frames of the work carried out as part of WG 1 activities, at a preliminary stage, worldwide ionospheric reference data on NmF2 and hmF2 were used to establish a system of aeronomic input parameters. At the next stage, this system of parame- ters was substituted to the ionospheric model to find NmF2 and hmF2, and the results were compared with another set of experimental data, thus confirming the validity of the model, which has been de- veloped. Using routine ISR observations (Ne(h), Te(h), Ti(h), Vi(h) profiles) the method allows to ob- tain a self consistent set of the main aeronomic parameters responsible for the F2-region formation. The list of derived parameters includes: neutral temperature profile Tn(h) depending on the exos- pheric temperature Tex, the temperature at 120 km and the shape parameter which determines the tem- perature profile, concentration of neutral species, vertical plasma drift, which may be converted to the meridional thermospheric winds, total solar EUV flux and ion composition as a result of Ne(h) fit- ting. Therefore the method gives a complete description of the upper atmosphere condition in the vicinity of ISR facility for the periods of observation. The approach turns out to be very useful for physical analysis of the F2-layer disturbance mechanisms giving a complete picture of the phenom- enon in question. A second topic investigated to improve our understanding on the physics of upper atmosphere is the reasons for possible trends in the Earth’s atmosphere and ionosphere. Trend investigations of different ionospheric and atmospheric parameters have become more and more important during recent years as such trends could be caused by anthropogenic activities (Bremer et al., 2004). Mainly in the F2-region different analyses have been carried out. The derived trends are mainly discussed in connection with an increased greenhouse effect or by long-term changes of the geomagnetic activity. In the F1-layer the de- rived mean global trend in foF1 is in good agreement with model prediction of an increasing greenhouse effect. In the E-region the derived trends in foE and h′E are compared with model results of an atmos- pheric greenhouse effect, or explained by geomagnetic effects or other anthropogenic disturbances. The trend results derived from different ionospheric reflection height and absorption measurements in the LF, MF and HF ranges can at least partly be explained by an increased atmospheric greenhouse effect. 1.2.7. Advances in mathematical and physical tools development Development of the new tools, techniques, and algorithms can decrease the unreliability of the pro- posed approach, or, at least, compensate some not fully satisfied effects. Lifetime of the Action pre- vents exploiting new techniques and finalizing them to the end-user’s figure, but the demonstration of their necessity creates well-defined further development for diagnostic and application purposes. Such direction was represented by the development of the updating of the global or limited-area models, as updating the IRI model to produce maps of N(h) over Europe, where the findings on deficiencies of IRI-2000 model with and without the foF2 storm option were shown (Burešová et al., 2003), or up- dating the SWILM model to produce local nowcast maps (Pietrella et al., 2003). Another very interesting technique for short-term prediction of ionospheric parameters was presented by Muhratov et al. (2002). The model consists of one part representing the weighted past time variation of the ionospheric parameter that is to be predicted (Φ = foF2 − foF2med ⁄ foF2med) 1257 Impact of variability of space environment on communications: Working Group 1 overview and a second part representing geomagnetic activity as described by the index Ap. Each part is con- structed according to the autocorrelation function of the relative quantity while the interdepend- ence between the two parts is represented by the cross correlation function. The model is termed Geomagnetically Correlated Autoregression Model (GCAM). Testing the model with data from 2 years of high solar activity and 2 years of low solar activity showed a large decrease in the mean squared error by GCAM in the first 8-10 h of prediction relative to median based prediction. Fi- nally in order to present a better comparison between the GCAM and median based prediction er- rors during disturbed ionospheric conditions, a new error estimate called «prediction efficiency» is used. 1.3. OVERALL EVALUATION OF THE PROGRESS ACHIEVED Working Group 1 has two main objectives, first the development of tools and models for nowcast- ing and forecasting ionospheric variability and secondly the stimulation of cooperation at European lev- el. From the review presented it is clear that all objectives have been fulfilled. Work of excellent quali- ty published in scientific journals with high impact factors is considered a great scientific achievement of WG 1. Operational and experimental services based on the newly developed and/or improved mod- els and algorithms provide substantial improvement in the telecommunication performance. As a result of international collaboration between different institutes in the frames of WG 1 activi- ties (Appendix), our colleagues raised funds for specific projects from international organizations. An important output in this direction was our contribution to demonstrate the necessity for Action on Space Weather, since this field is not covered by COST 271, but our community needs this kind of input. The final result was the approval for a new COST Action on «Developing of Scientific Basis for Monitor- ing, Modeling and Prediction Space Weather» (Lilensten et al., 2004). Also several proposals and proj- ects were submitted and funded within EU calls based on consortia formed by COST 271 participating institutes. Finally, the number of bilateral agreements between COST 271 participating partners has suf- ficiently increased for the implementation of the COST 271 research programs as well as new subjects. Overall the activities in the frames of Working Group 1 contributed significantly to EC policies. With respect to research and innovation, WG 1 activities contributed a) to the cooperation of several entities at different levels; b) to an increase in the mobility of individuals and ideas between differ- ent research organizations; and c) to the reinforcement of European competitiveness mainly with the US and Australia. Our activities have successfully contributed to maximize European synergy and added value in re- search cooperation and they have been proved to be a step for further European integration, in par- ticular concerning central and eastern European countries. More advanced work towards the practical implementation of the obtained knowledge is further needed. For future development the major orientations would be in three directions: – The development of models able to operate on line to satisfy the requirements of the scientific community and of the industry oriented users community. – The linkage with other non-European organization in our effort to develop a global system for monitoring and predicting ionospheric and plasmaspheric conditions. – Further increase in scientific and technological capacity of the European community by inte- grating COST 271 results. ACKNOWLEDGEMENTS A.B. would like to thank Ioanna Tsagouri for her substantial contribution in compiling this report. Thanks are also due to Ljiljana Cander for proof reading and helpful comments. 1258 Anna Belehaki and Iwona Stanis ⁄lawska Appendix. Collaborations in the frames of WG 1 activities – IZMIRAN (Russia)-Laboratoire de Planetologie de Grenoble (France). – Faculty of Aeronautics and Astronautics, Instabul Technical University (Turkey)-IZMIRAN (Rus- sia)-Department of Electrical and Electronics Engineering, Middle East Technical University (Turkey)-Information Technologies Research Institute (Turkey). – INGV (Italy)-Aristotle University of Thessaloniki (Greece). – Institute of Atmospheric Physics (Czech Republic)-RAL (U.K.)-INGV (Italy). – Laboratoire de Planetologie de Grenoble (France)-RAL (U.K.)-EISCAT Association (Norway)- Qinetiq (Norway). – Laboratoire de Planetologie de Grenoble (France)-RAL (U.K.). – SRC (Poland)-Observatorio de l’Ebre (Spain). – NOA (Greece)-University of Wales (U.K.). – NOA (Greece)-RAL (U.K.). – RAL (U.K.)-CNR (Italy). – NOA (Greece)-DLR (Germany). – Bulgarian Academy of Sciences (Bulgaria)-DLR (Germany). – INGV (Italy)-NOA (Greece)-RAL (U.K.). – DLR (Germany)-Royal Observatory of Belgium (Belgium). – ITU, METU (Turkey)-SRC (Poland). – SRC (Poland)-Institute of Atmospheric Physics (Czech Republic). – Institute of Atmospheric Physics (Czech Republic)-SRC (Poland)-Observatory de l’ Ebre (Spain)- INTA (Spain)-Geophysical Observatory (Finland). – Leibniz- Institute of Atmospheric Physics (Germany)-Institute of Atmospheric Physics (Czech Republic)-QinetiQ (U.K.)-University of Tromsø (Norway). – INGV (Italy)-IZMIRAN (Russia)-SRC (Poland). – Department of Electrical and Electronics Engineering, Middle East Technical University (Turkey)-Goddard Space Flight Center, NASA (U.S.A.)-Faculty of Aeronautics and Astronautics, Instabul Technical University (Turkey)-Marmara Research Center (Turkey). REFERENCES ANTONOV, B., P. MUHTAROV and I. KUTIEV (2004): Analogue model, relating Kp index to solar wind parameter, J. Atmos. Sol.-Terr. Phys. (in press). BELEHAKI, A. and L. KERSLEY (2003): Statistical validation of the ITEC parameter, in Proceedings of the 3rd COST 271 Workshop, 23-27 September 2003, Spetses, Greece (on line: http://www.cost271.rl.ac.uk/). BELEHAKI, A., N. JAKOWSKI and B.W. REINISCH (2003): Comparison of ionospheric ionization measure- ments over Athens using ground ionosonde and GPS derived TEC values, Radio Sci., 38 (6), 1105, doi:10.1029/2003RS002868. BREMER, J., L. ALFONSI, P. BENCZE, J. LAŠTOVIČKA, A.V. MIKHAILOV and N. ROGERS (2004): Long- term trends in the ionosphere and upper atmosphere parameters, Ann. Geophysics, 47 (suppl. to no. 2/3), 1009-1029 (this volume). BUREŠOVÁ, D., LJ.R. CANDER, A. VERNON and B. ZOLESI (2003): Results of real-time ionospheric N(h) profile updating over Europe using IRI-2000 model, in Proceedings of the 3rd COST 271 Workshop, 23-27 September 2003, Spetses, Greece (on line: http://www.cost271.rl.ac.uk). CANDER, LJ.R. (2003): Toward forecasting and mapping ionospheric space weather under the COST Actions, Adv. Space Res., 31 (4), 957-964. 1259 Impact of variability of space environment on communications: Working Group 1 overview CANDER, LJ.R. and L. CIRAOLO (2002): First step towards specification of plasmaspheric-ionospher- ic conditions over Europe online, Acta Geod. Geophys. Hung., 37 (2/3), 153-161. CANDER, LJ.R., R.A. BAMFORD and J.G. HICKFORD (2003): Nowcasting and forecasting the foF2, MUF(3000)F2 and TEC based on empirical models and real-time data, in Twelfth International Conference on Antennas and Propagation (ICAP 2003), IEE CP 491, vol. 1, 139-142. CANDER, LJ.R., J. HICKFORD, I. TSAGOURI and A. BELEHAKI (2004): Real-time dynamic system for monitoring the ionospheric propagation conditions over Europe, Electron. Lett., 40 (4), 224-226. DE FRANCESCHI, G., T.L. GULYAEVA and L. PERRONE (2002): Forecasting geomagnetic activity 3 h in advance for ionospheric applications, on CD-Proceedings of the 2nd COST 271 Workshop, 2-4 October 2002, Faro, Portugal. KUTIEV, I. and P. MUHTAROV (2003): Empirical modeling of global fof 2 ionospheric response to ge- omagnetic activity, J. Geophys. Res., 108 (A1), 1021, doi:10.1029/2001JA009134. LILENSTEN, J., LJ.R. CANDER, M. RIETVELD and P.S. CANNON (2003): Comparison of EISCAT and ionosonde data, application to a ground based ionospheric segment of space weather program, in Proceedings of the 3rd COST 271 Workshop, 23-27 September 2003, Spetses, Greece (on line: http://www.cost271.rl.ac.uk). LILENSTEN, J., T. CLARK and A. BELEHAKI (2004): Europe’s first space weather think tank, Space Weather, 2 (4), S04001, 10.1029/2003SW000021. MICHAILOV, A.V. and J. LILENSTEN (2004): A revised method to extract thermospheric parameters from incoherent scatter observations, Ann. Geophysics, 47 (suppl. to no. 2/3), 985-1008 (this volume). MUHTAROV, P., I. KUTIEV and LJ.R. CANDER (2002): Geomagnetically correlated autoregression mod- el for short-term prediction and ionospheric parameters, in Inverse Problems (Institute of Physics Publishing), 18, 49-65, PII:S0266-5611(02)20757-1 PIETRELLA, M., L. PERRONE and G. DE FRANCESCHI (2003): The ISWILM model for instantaneous map- ping of the critical frequency of the F2-layer in the European region, in Proceedings of the 3rd COST 271 Workshop, 23-27 September 2003, Spetses, Greece (on line: http://www.cost271.rl.ac.uk). REINISCH, B.W. and X. HUANG (2001): Deducing topside profiles and total electron content from bot- tomside ionograms, Adv. Space Res., 27 (1), 23-30. REINISCH, B.W., I.A. GALKIN, G. KHMYROV, A. KOZLOV, D.F. KITROSSER and T.W. BULLETT (2003): Automated collection and dissemination of ionospheric data from the digisonde network, in Pro- ceedings of the 3rd COST 271 Workshop, 23-27 September 2003, Spetses, Greece (on line: http://www.cost271.rl.ac.uk). ROGERS, N., P. CANNON and C. HALL (2002): Practical implications of long term trends in the critical frequency and the height of the F2-layer above Tromsø (70°N, 19°E), in Proceedings of the 2nd COST 271 Workshop, 2-4 October 2002, Faro, Portugal. STAMPER, R., LJ.R. CANDER, M. PIETRELLA, I. KUTIEV, Y.K. TULUNAY, I. STANIS ⁄LAWSKA, D. BUREŠOVÁ, A. BELEHAKI, I. TSAGOURI and B. ZOLESI (2004): Nowcasting, forecasting and warning: tools and methods, Ann. Geophysics, 47 (suppl. to no. 2/3), 957-983 (this volume). STANIS ⁄LAWSKA, I. and Z. ZBYSZYŃSKI (2001): Forecasting of the ionospheric quiet and disturbed foF2 values at a single location, Radio Sci., 36 (5), 1065-1071. STANIS ⁄LAWSKA, I., H. ROTHKAEHL and D. BUREŠOVÁ (2004): Limited-area electron concentration height profile instantaneous maps, Adv. Space Res. (in press). STANKOV, S.M., R. WARNANT and J.C. JODOGNE (2003): Improved operational model for real-time re- construction of the electron density profile at a single location, on CD-Proceedings of the 2nd COST 271Workshop, 2-4 October 2002, Faro, Portugal. TULUNAY, E., E.T. SENALP, LJ.R. CANDER, Y.K. TULUNAY and L. CIRAOLO (2002): Forecasting GPS- TEC during high solar activity by neural network technique, on CD-Proceedings of the 2nd COST 271 Workshop, 2-4 October 2002, Faro, Portugal. TULUNAY, Y.K. and P.A. BRADLEY (2004): The impact of space weather on communication, Ann. Geophysics, 47 (suppl. to no. 2), 929-944 (this volume). 1260 Anna Belehaki and Iwona Stanis ⁄lawska TULUNAY, Y.K., E. TULUNAY and E.T. SENALP (2001): An attempt to model the influence of the trough on HF communication using neural network, Radio Sci., 36 (5), 1027-1041. ZOLESI, B., A. BELEHAKI, I. TSAGOURI and LJ.R. CANDER (2004): Real-time updating of the simplified ionospheric regional model for operational applications, Radio Sci., 39 (2), RS2011, 10.1029/ /2003RS002936.