A NEW MODEL OF THE INTERNATIONAL REFERENCE

IONOSPHERE IRI FOR TELECOMMUNICATION AND

NAVIGATION SYSTEMS

Olga Maltseva, Natalia Mozhaeva, Gennadyi Zhbankov

Institute of Physics Southern Federal University, Stachki, 194, Rostov-on-Don, Russia

mal@ip.rsu.ru, mozh_75@mail.ru, zhbankov_ga@rambler.ru

Keywords: GPS. Total electron content. Ionospheric model. Radio wave propagation. Geomagnetic disturbances.

Abstract: Telecommunication, navigation, positioning systems require knowledge of ionospheric Ne(h)-profiles up to

high-altitude orbits of satellites. The only way to construct such profiles is associated with the use of the

ionospheric total electron content TEC. New option IRI-Plas of the IRI2010 model allows us to construct

Ne(h)-profiles by adjustment of the model to the current maximum values of the parameters of the

ionospheric F2 layer (foF2, hmF2) and the TEC. This paper contains a comprehensive comparison of these

profiles with the data of various experiments (ISR, CHAMP, DMSP). Results show the high efficiency of

this adjustment. The proposed method of further adjustment of the IRI-Plas model to the plasma frequency

at altitudes of CHAMP and DMSP satellites allows us to produce behaviors of Ne(h)-profiles during the

disturbances, as well as to refine the values of TEC, which determine the accuracy of positioning.

1 INTRODUCTION

The operation of the various satellite

communication, navigation, global positioning

systems (GPS) depends on the state of the

ionosphere and needs to know the electron

distribution in height (Ne(h)-profiles) in near space.

Methods for direct measurement of the Ne(h) at

these altitudes are not exist, however, there are a

number of theoretical and empirical models of

Ne(h)-profiles. In many applications of radio and

satellite communications, the empirical model of the

ionosphere IRI (Bilitza, 2001; 2006) is most widely

used, but it determines the Ne(h)-profile to a height

of 2000 km. Ability to determine the profiles at high

altitudes is associated with the total electron content

(TEC) of the ionosphere. This parameter is defined

as the number of electrons in the atmospheric

column, measured by the navigation satellites (GPS,

etc.) and directly related to the Ne(h)-profiles of the

ionosphere. Despite the difficulties in determining

the TEC (slips of signal phase, an idealization of the

model of the ionosphere on the conversion of slant

TEC into the vertical VTEC, the dependence on the

type of receiver, etc.), it is widely used in various

applications. However, the IRI model gives a large

discrepancy when compared with the experimental

TEC because of the profile shape of the topside

ionosphere (e.g., Stankov et al., 2003; Uemoto et al.

2007; Bilitza, 2009; Maltseva et al., 2011), so that

the model has been modified several times in this

century (IRI2001 (Bilitza, 2001), IRI2007 (Bilitza

and Reinish, 2006; 2008)) and modification

continues. In 2010, a new version IRI2010 (Bilitza

et al., 2010) of the IRI model was proposed, which

included a model of T. Gulyaeva. Although this

model has been developed for a long time, for

example (Gulyaeva et al., 2002; Gulyaeva, 2003), it

is formally incorporated as IRI-Plas just now. The

main advantages of this model are accounting a

plasmaspheric part of the magnetosphere, and the

ability to be adapted to the experimental parameters

of the ionosphere (the critical frequency foF2, the

maximum height hmF2, TEC). This should allow us

to determine the shape of Ne(h)-profiles. The

purpose of this paper are: 1) validation of the IRI-

Plas model according to various experiments

(incoherent sounding radars ISR, satellite CHAMP

(hsat~400 km) and DMSP measurements (hsat~800

km), 2) validation of the IRI-Plas model according

to the particular ionospheric station of Sofia, 3)

determination of the behavior of Ne(h) profiles

during the disturbed conditions, 4)

refinement of the

values of TEC by means of further adaptation of the

model to the plasma frequency at altitudes of

satellites CHAMP and DMSP. These results may

129

Olga M., Natalia M. and Zhbankov G.

A NEW MODEL OF THE INTERNATIONAL REFERENCE IONOSPHERE IRI FOR TELECOMMUNICATION AND NAVIGATION SYSTEMS.

DOI: 10.5220/0005415001290138

In Proceedings of the First International Conference on Telecommunications and Remote Sensing (ICTRS 2012), pages 129-138

ISBN: 978-989-8565-28-0

have important implications for telecommunication,

navigation, positioning systems.

2 ON THE IRI MODEL

As noted in (Bilitza, 2006), “The International

Reference Ionosphere (IRI) project was initiated by

the Committee on Space Research (COSPAR) and

by the International Union of Radio Science (URSI)

in the late sixties with the goal of establishing an

international standard for the specification of

ionospheric parameters based on all worldwide

available data from ground-based as well as satellite

observations. COSPAR and URSI specifically asked

for an empirical data-based model to avoid the

uncertainties of the evolving theoretical

understanding of ionospheric processes. COSPAR’s

main interest is in a general description of the

ionosphere as part of the terrestrial environment for

the evaluation of environmental effects on spacecraft

and experiments in space. URSI’s prime interest is

in the electron density part of IRI for defining the

background ionosphere for radiowave propagation

studies and applications. To accomplish these goals

a joint COSPAR-URSI Working Group was

established and tasked with the development of the

model.” IRI describes monthly averages of the

electron density, electron temperature, ion

composition (O+, H+, N+, He+, O2 +, NO+,

Cluster+), ion temperature, and ion drift in the

ionospheric altitude range (60 km to 1000 km).

Some of the primary applications are listed in Table

1 in (Bilitza, 2006) together with typical usage

examples. The model is recommended as the

ionospheric standard. The model is located on the

site: http:// modelweb.gsfc.nasa.gov/ionos/iri.html.

The maximum parameters (foF2, hmF2) are

provided by the ITU-R (former CCIR) or URSI

maps. Drivers of the model are parameters

characterizing solar and geomagnetic activity

(RZ12, IG12, ap and others). Input parameters are

day, month, year, coordinates of the point among

others. TEC is calculated by the formula

TEC=∫Nedh. The calculation ceiling of previous

versions was 2000 km. The IRI-Plas model extended

to the plasmasphere. Output parameters important

for our purposes are the critical frequency foF2, the

maximum height hmF2, TEC, Ne(h)-profiles. All

versions provide adaptation of the model to current

values of foF2, hmF2 and include the STORM-

factor adapting the model to disturbed conditions

(

Araujo-Pradere et al. 2004).

3 VALIDATION OF THE IRI-

PLAS MODEL ACCORDING

TO DIFFERENT

EXPERIMENTS

Experimental values of the parameters foF2 and

hmF2 are taken from the SPIDR database. TEC

values are computed from IONEX files of the global

maps delivered online by four organizations: JPL

(Mannucci et al., 1998), CODE (Schaer et al., 1995),

UPC (Hernandez-Pajares et al., 1999), ESA (Sardon

et al., 1994; Jakowski et al., 1996). Ne(h)-profiles of

incoherent sounding radars for six stations are taken

from (Zhang et al., 2007). These profiles show the

Ne to a height of 500 km. In all cases, the

coincidence of the model and experimental profiles

was good. Quantitative results are presented in Table

1 in the form of the experimental and calculated

values of the plasma frequency fne at an altitude of

500 km for the three European radars. These radars

are Svaldbard (78.1°N, 16°E), StSantin (44.6°N,

2.2°E), Tromso (69.6°N, 19.2°E). The first column

gives the shortening name of the station and the day

of measurement (1 = 03/31/1999, 2 = 29/07/1999, 3

=11/26/2002). Data of (Zhang et al., 2007) refer to

LT = 12, but calculations were done for UT

corresponding to each radar. The following columns

represent the results of different calculations, which

should be compared with values in the last column

(ISR) containing experimental ones. The results

show that the model and experimental profiles match

very well, but we can not specify a map, which

would be consistent with all experiments, so it is

advisable to choose a map that gives the closest

value of fne.

Table 1: Comparison of the IRI-Plas model results with

ISR data of three radars

IRI foF2 TEC JPL ESA ISR

Sv(1) 3.57 2.37 3.37 3.35 3.33 3.19

Sv(2) 2.86 2.64 3.77 3.75 2.53 3.79

Sv(3) 2.84 1.57 1.62 2.22 2.15 2.01

St(1) 5.52 3.46 3.10 4.19 2.43 4.01

St(2) 3.57 2.70 3.09 3.85 3.42 4.01

St(3) 4.49 3.16 2.33 3.66 3.04 3.38

Tr(1) 4.00 2.37 2.24 2.74 0.71 3.66

Tr(2) 2.86 3.05 3.79 3.94 3.52 3.79

Tr(3) 3.50 2.47 1.59 2.41 2.37 3.38

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130

4 VALIDATION OF THE IRI-

PLAS MODEL ACCORDING

TO DATA OF THE SOFIA

STATION

Data of the Sofia station were selected to

demonstrate results of validation of the IRI-Plas

model and to show its new possibilities. Validation

is carried out for four cases: (1) the original model

IRI, (2) the IRI model, adapted to the experimental

value of foF2, (3) the IRI model, adapted to the

experimental value of the TEC, (4) the IRI model,

adapted to the experimental values of foF2 and TEC,

to show the difference between the results for these

methods. Option 1 is used when there is no current

information and determines the average ionospheric

state. It is a

standard for comparison with other

options. Option 2 uses the current value of foF2 and

completely defines the bottom part of the profile.

Option 3 is widely used in connection with the TEC

measurements with navigation satellites. The

advantage of this option before the second one is in

a continuous global monitoring. Adapting the model

to the current values of the TEC allows us to obtain

new (reconstructed) values of foF2. Option 4, as

stated in the introduction, is one of the main

differences between the new IRI model and previous

versions. It allows to determine the Ne(h)-profile at

the location of ionosondes. Validation of these

options is to compare the plasma frequency at

altitudes of satellites calculated for the model with

the experimental values of fne. A comparison was

carried out for two satellites CHAMP (hsat ~ 400

km) and DMSP (hsat ~ 840 km). Data of foF2 are

taken from SPIDR, values of TEC – from global

maps of JPL, CODE, UPC, ESA. Results are

presented for April 2001 including two strong

disturbances (1-2 April with minimum Dst=-228nT

and 11-12 April with minimum Dst=-273 nT) and

two weak disturbances (18 and 22-23 April) with

minimum Dst~-100nT. Table 2 shows the results of

comparisons of Ne(h)-profiles with satellite

CHAMP data. Table includes day, time of

observation, and the values of plasma frequencies

for the respective versions and the CHAMP satellite.

Figures in round brackets indicate numbers of

options. The last column shows fne of the CHAMP

satellite. Heights of the satellite were in range 410-

460 km.

The best fit of model and the experimental

values is provided by the fourth version. Examples

of the profiles are shown in Fig. 1a, b. Fig. 1a

presents night profiles (UT=1), Fig. 1b presents

daytime profiles (UT=13). Examples for night

profiles are given for cases of foF2(obs)>foF2(IRI)

(the left panel) and foF2(obs)<foF2(IRI) (the right

panel).

Figures in round brackets after the name of the

satellite indicate a time of observation if this time

does not coincide with data of TEC. Values of the

model and satellite plasma frequencies coincide for

the forth version.

Table 2: Comparison of simulation results for different

versions of the IRI model with the data of the CHAMP

satellite

day UT

IRI

(1)

foF2

(2)

TEC

(3)

All

(4)

fne

3 1 5.57 6.45 5.75 6.44 6.50

3 13.1 9.27 10.70 10.14 10.94 11.14

6 12.6 9.33 9.97 9.84 10.15 10.01

11 0.4 5.72 5.07 5.41 5.06 5.04

13 12.6 9.16 11.09 9.96 10.87 11.16

19 23 6.51 5.02 5.07 4.92 4.37

21 23.2 6.52 6.53 6.45 6.46 6.21

23 23.4 6.52 5.80 5.91 5.67 5.35

24 22.7 6.53 6.15 6.30 6.11 6.00

26 22.9 6.53 6.53 6.55 6.55 6.92

29 11.2 8.14 8.88 8.60 8.65 8.74

29 22.5 6.54 5.85 6.04 5.78 5.74

30 10.5 8.10 8.05 8.21 8.20 7.76

Figure 1a: Comparison of model Ne(h)-profiles and the

results for the CHAMP satellite (April 2001) for night

time

A New Model of The International Reference Ionosphere IRI for Telecommunication and Navigation Systems

131

Figure 1b: Comparison of model Ne(h)-profiles and the

results for the CHAMP satellite (April 2001) for day time

The same correspondence can be seen for the

noon time profiles, although the time of the satellite

flight is slightly different from the time of

measurement of ionospheric parameters. Exact

coincidence of these times is rare.

More often are the cases when the satellite

passed over the station at even hours, whereas the

values of TEC were only for the odd hours. Typical

examples of calculations for these cases are shown

in Fig. 2 for daytime and nighttime profiles for the

forth option (full adjustment).

Figure 2: The cases of the satellite flight in the average

hours between the measurements of the TEC

Orbit heights of DMSP satellites exceed 800

km.The results using data of DMSP were obtained

under the same scenario. In this case data of three

satellites were available (F12, F13, F15). Typical

results are shown in the Table 3. They present

plasma frequencies for four options and

experimental values fne.

Table 3: Comparison of simulation results for different

versions of the IRI model with data of DMSP satellites

(hsat~840-860 km)

day UT

IRI

(1)

foF2

(2)

JPL

(3)

All

(4)

fne

1 5.5 2.10 1.22 1.71 2.07 2.15

1 8.7 3.46 2.73 2.88 3.40 2.71

1 15.3 3.32 3.17 3.67 3.76 3.36

1 17.4 3.10 2.95 3.61 3.67 3.02

2 5.3 2.13 2.13 2.77 2.77 2.38

2 7.5 2.76 3.00 3.74 3.62 2.94

2 17.2 3.11 3.41 3.77 3.61 2.75

3 7.3 2.77 3.28 4.06 3.79 2.89

3 8.2 3.47 4.03 4.68 4.35 3.41

3 16.5 3.15 3.69 4.20 3.92 3.33

4 4.9 2.15 2.73 3.44 3.22 2.76

4 7 2.77 3.17 3.97 3.77 3.04

4 19.4 2.96 3.38 3.89 3.70 3.44

5 19.2 2.97 2.87 3.31 3.35 2.81

11 19.4 3.04 3.60 3.60 3.27 3.52

12 4.8 2.23 1.39 1.38 1.95 1.73

12 7 2.82 1.69 1.93 2.64 2.19

12 19.2 3.05 2.75 2.45 2.68 1.60

13 4.6 2.24 2.08 2.19 2.29 1.80

The distinction

of this case is the fact that the best

agreement between the calculated and experimental

values of fne is obtained for the original model or

adaption of the model to current foF2. Using the

experimental values of TEC leads to

overvalued

values of fne. A too high value for the map of JPL

should be considered as a possible cause. This can

be confirmed by the results for other maps presented

in Fig. 3. Experimental plasma frequencies fne are

shown by full points, the other values are

corresponding to various maps.

It is seen that often experimental frequencies do

not reach range of map values. Nevertheless, the

agreement between the calculated and experimental

values of fne exists. Typical examples of Ne(h)-

profiles are shown in Fig. 4 as close to the moment

of the flight time and for the middle of two hour

period.

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Figure 3: Comparison of experimental plasma frequencies

fne and frequencies provided by maps of JPL, CODE,

UPC, ESA

Figure 4: Comparison of model Ne(h)-profiles and the

results of the DMSP satellite (April 2001)

5 EXAMPLES OF THE

BEHAVIOR OF Ne(h)-

PROFILES AT THE SOFIA

STATION DURING

DISTURBANCES

The results of the previous section show that the

profiles are rather well adapted to meet the satellite

measurements. This allows us to study and simulate

the height distribution of the ionospheric ionization.

The choice of Ne(h)-profiles in the previous section

was dictated by time of flight of the satellite. For a

variety of tasks long periods of observation are

important especially for disturbed conditions when

the profiles can be strongly modified. Examples of

the behavior of Ne(h)-profiles for the longitudinal

(left panels) and latitudinal (right panels) chains

connected with the Sofia station are shown in Fig.

5.The upper two sets of graphs display night profiles

(UT = 1), the bottom two groups – daytime profiles

(UT=11). The upper graphs of each group show the

profiles during quiet conditions, the lower profiles -

in the disturbed ones. In the night of 12 April, quiet

conditions on the longitudinal chain (Sodankyla,

Leningrad, Moscow, Sofia) are presented by Ne(h)-

profiles of the IRI model. We can see the

coincidence of the values of three northern stations

and high values for Sofia because it is the most

southerly. During the disturbance, which is negative,

the profiles vary strongly, because all the

ionospheric structures are shifted to the south. Thus,

the Moscow station is in the area of the ionospheric

trough, the Leningrad station falls from the

plasmaspheric area into zone of subauroral

amplification. The most strongly reduced is the

concentration at the Sofia station reaching values

less even than the values in the subauroral

Sodankylä station. This leads to huge gradients of

the electron concentration that must be considered in

the propagation of radio waves. On the latitudinal

chain (Sofia, Rome, Ebre), profiles of the Sofia

station have the lowest ionization, indicating a

positive gradient towards lower latitudes under quiet

conditions. During the negative disturbance, a

decrease in the concentration at all the stations can

reduce gradients. During the day, the concentration

distribution in the quiet time should be clearly

decreased with increasing latitude. An example of

the lower grafts shows that a positive (in this case)

perturbation has the greatest effect on the

concentration of the Sofia station. Example of

daytime profiles for a quiet state and during the

April 3 disturbance is shown in the lower right-hand

chart. It is seen that if a negative disturbance during

the night enveloped almost the entire European

region, the daytime disturbance may influence by

different manner at various stations.

Since the bottom and topside parts of the profile

may respond differently to disturbance, such profiles

can provide a quantitative assessment of effects of

disturbances.

A New Model of The International Reference Ionosphere IRI for Telecommunication and Navigation Systems

133

Figure 5: Sequence of Ne(h)-profiles showing their

modification during the disturbances

6 CASES OF LACK OF

MEASUREMENT OF

IONOSPHERIC

PARAMETERS AT THE

STATION

In the absence of measurements of ionospheric

parameters at the station there are at least two

methods to obtain Ne(h)-profiles: (1) the use of the

parameters of the original model, (2) the use of the

median equivalent thickness of the ionosphere

τ(med) in conjunction with the TEC. The first option

coincides with the first option of the section 4 and

provides good results for the conditions close to the

quiet ones, but during the disturbances difference

can be substantial, as illustrated in Fig. 6. Fig. 6

shows the results of calculations for all versions. It is

evident that the difference is significant, not only

near the peak of the layer F2, but at the top of the

profile. The full points indicate the plasma

frequency of DMSP satellites.

Figure 6: Comparison of Ne(h)-profiles in the case of

strong differences in foF2 (IRI) and foF2 (obs), caused by

a disturbance

These two successive profiles show an increase

in the diurnal foF2, but the perturbation has a strong

influence. Therefore, it is preferable to use the

second method. In (Maltseva et al., 2012) is shown

that the use of the median equivalent thickness of the

ionosphere τ(med) in conjunction with the TEC

allows us to fill in gaps in the data by means of

using reconstructed values of foF2. The

effectiveness of this approach is estimated using the

deviations of the calculated and experimental values

of foF2 for periods when there are complete data

sets. For four disturbed periods in April 2001 for the

Sofia station, these deviations are shown in Fig. 7.

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Figure 7: Deviations of the model and reconstructed

values of foF2 from the experimental ones

It is seen that the greatest deviations of model foF2

values from the experimental ones account for the

days of disturbances. Using τ(med) in conjunction

with the TEC can increase compliance by many

times. This section contains attempts to do the next

step: to use τ(med) of one (reference) stations for the

determination of foF2 of another station from its

values of TEC. We validate this procedure with the

help of satellite data. The results are shown in the

example of May 2005, which was also marked by

four disturbances with minimal index Dst:-127nT

(8.05), -263nT (15.05), -103nT (20.5), -138nT

(30.5). For the Sofia station, ionospheric observation

data are absent in the SPIDR database since 2005.

Rostov was chosen as the reference station to

determine the values of foF2 for the Sofia station.

Values of τ(med) of the Rostov station and TEC

values of the Sofia station are used. To be sure in

correctness of using τ(med) of the Rostov station we

compared τ(med) of these stations for some previous

years. Fig. 8 displays experimental and model values

of median equivalent thickness τ of the ionosphere

for stations of Sofia and Rostov in May of those

years for which measurements were available

simultaneously at both stations in the SPIDR. Model

values (sign IRI) shown by the triangles and

asterisks coincide. Namely these values are used in

traditional methods of determining foF2 from TEC

(McNamara, 1985; Houminer and Soicher, 1996,

Gulyaeva, 2003). They ensure deviations between

experimental and model values of foF2 shown in

Fig. 7 by circles. The more important fact is the

closeness of the experimental values of τ(med) for

both stations. Using these values ensures deviations

shown in Fig. 7 by points.

Figure 8: Comparison of equivalent thicknesses τ for Sofia

station

Table 4: Comparison of simulation results for different

versions of the IRI model with the data of CHAMP

satellite in May 2005 (hsat~860 km)

day UT IRI foF2 TEC All fne

1 9 5.73 5.69 5.95 5.93 5.41

2 21.3 4.82 3.67 4.76 3.70 3.91

3 8.4 4.99 5.33 5.48 5.65 5.45

4 20.7 5.69 5.31 5.66 5.34 3.99

6 8.3 4.97 5.33 5.47 5.65 4.59

12 8 4.91 5.34 5.44 5.66 4.55

12 19.9 5.87 5.97 5.99 6.07 6.02

18 19.6 5.96 5.08 5.77 5.15 4.87

21 19.5 5.97 5.38 5.93 5.48 5.27

23 7.1 4.88 4.97 5.26 5.30 3.81

24 19.3 5.99 5.83 6.09 5.95 5.78

28 6.3 4.65 5.59 5.34 5.93 5.46

28 18.5 6.07 6.45 6.41 6.72 6.55

29 18.6 6.06 6.38 6.39 6.65 7.05

30 5.7 4.65 4.48 4.89 4.81 4.07

The profiles obtained using the reconstructed values

of foF2 are compared with data of CHAMP and

A New Model of The International Reference Ionosphere IRI for Telecommunication and Navigation Systems

135

DMSP satellites. The results are shown in Tables 4-5

separately for each satellite. In this case, there were

more flights with similar times for both satellites, so

in the Table 5 we focus on the close passages.

Table 5: Comparison of simulation results for different

versions of the IRI model with data of DMSP satellites in

May 2005 (hsat~840 km).

day UT IRI foF2 TEC All fne

1 7.2 1.89 1.99 2.33 2.29 1.81

3 8.4 1.88 1.99 2.33 2.28 1.61

4 19.6 1.91 1.79 1.81 1.90 1.12

6 6.2 1.85 1.97 2.30 2.26 1.48

18 19.4 1.93 1.66 1.61 1.84 1.18

23 5.3 1.77 1.82 2.14 2.12 1.46

29 18.2 1.92 2.02 2.52 2.46 1.58

30 5.3 1.77 1.71 1.96 1.99 1.48

The results are very similar to the results for April

2001, indicating the effectiveness of this approach.

The proximity of the flight time allowed us to

compare Ne(h)-profiles adapted to the values of

plasma frequencies for both satellites. Examples of

such profiles are shown in Fig. 9.

Figure 9: Examples of Ne(h)-profiles adapted to the data

of both satellites

An important result is the fact that adaptation to

data of various satellites leads to almost the same

profile. This suggests that the behavior of the

profiles will reflect the real situation. An example of

the behavior of profiles during two disturbances in

May 2005 is shown in Fig. 10.

Figure 10: The behavior of the Ne(h)-profiles of the Sofia station during two disturbances in May 2005

First International Conference on Telecommunications and Remote Sensing

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Surprising is the identity of changes during these

two disturbances, which may indicate some

regularities. IRI profiles correspond to quiet

conditions. Comparison with these profiles shows

that in the early morning hours (UT = 4) on 15 and

30 May at the bottom, the ionosphere is close to the

quiet state, and in the topside there is an increase of

ionization. On 17 and 31 May, a decrease in the

bottom part is observed along with an increase at the

topside. This demonstrates the different responses of

the upper and lower parts of the ionosphere on the

disturbance. In moments of UT = 10 both

disturbances are manifested in the form of large

increases in the bottom part and the weakening of

the ionization at the topside. On May 30 at UT = 12,

this process is developing at the time, as on 15 May

(chart is not shown), it decays. In UT = 18, both the

profiles return back to its original state.

7 REFINEMENT OF THE TEC

VALUES FROM SATELLITE

EXPERIMENTS

Figure 3 shows that there is some variation in

correspondence related to the difference in TEC.

The difference of the TEC values related to one

point and one moment of time is a known fact. The

reasons for the differences may be very different.

For global maps of JPL (Mannucci et al., 1998),

CODE (Schaer et al., 1995), UPC (Hernandez-

Pajares et al., 1999), ESA (Sardon et al., 1994;

Jakowski et al., 1996), it is the difference in

calculation methods. Various receivers may give

difference of up to 10 TECU (e.g. Choi et al., 2010).

A typical example is Figure 7 of the article (Arikan

et al., 2003), which shows the values of TEC,

obtained by different methods in the Kiruna station

on 25 and 28 April 2001. The values of the global

maps for the Sofia station for these two days are

shown in Fig. 11.

Figure 11: Differences of TEC for the Sofia station

calculated from the various global maps

It is seen that the difference in the Sofia station

for four maps may lie in the range of 10-30 TECU.

In this paper is proposed to specify these values

using the plasma frequency on satellites. Fig. 12

shows the values of TEC for four maps and the

values obtained by adapting the model to fne on

satellites. In the abscissa, day and hour of

calculations are indicated.

Figure 12: Comparison of TEC calculated from the

various global maps with TEC obtained by adaptation to

the satellite fne

It is seen that the values of the JPL map are

overvalued. It is possible that such adaptation can be

used to calibrate the TEC for a given station.

8 CONCLUSIONS

The ionosphere is the key factor for the operation of

satellite systems. It is one of the largest sources of

error in positioning and navigation. The associated

error is proportional to the TEC. That is why a lot of

attention paid to the development of the ionospheric

model. Using the model of Klobuchar (e.g. 1987)

allowed to increase the positioning accuracy in 2

times. The next step was done using the IRI model.

However, the previous versions of this model also

had limitations. This paper highlights the

possibilities of a new model (Gulyaeva et al., 2002;

Gulyaeva, 2003). They confine to the fact that

adaptation of the IRI model to current ionospheric

parameters foF2, hmF2 and TEC allows us to

determine the state of the ionosphere up to altitudes

of high-altitude satellites with greater accuracy than

ever before. The use of plasma frequency fne,

measured at altitudes of satellites, on the one hand,

allows us to validate the model and determine the

behavior of the Ne(h)-profiles, on the other hand,

may provide

refinement of TEC values which

depend on the accuracy of satellite systems from.

According to data of the Sofia station, effectiveness

of the use of the median equivalent thickness of the

A New Model of The International Reference Ionosphere IRI for Telecommunication and Navigation Systems

137

ionosphere τ (med) is confirmed not only to fill gaps

of foF2 at one station, but also to determine the

behavior of foF2 for the other stations in the absence

of its experimental data.

ACKNOWLEDGEMENTS

Authors thank scientists provided data of SPIDR,

global maps of TEC, operation and modification of

the IRI model, Dr A. Karpachev for CHAMP data.

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