4. Monitoring Global Activity of Io

4. Monitoring Global Activity of Ionospheric
Irregularities
Using the GPS network and the GPS phase fluctuation index
ROTI, it is possible to monitor global activity of ionospheric
irregularities. One approach that we have tried is to present
ROTI values obtained for the entire GPS network on a global
map for every 15-minute interval. Examples of the ROTI maps
are shown for a geomagnetic storm event, which is indicated in
the magnetic Dst data in Figure 5, and the ROTI maps are
plotted in Figure 6. In these maps, ROTI values are coded with
colors, and projected on the Earth from the ionospheric
intersection points of radio signals at 400 km altitude. Such
maps present occurrence and approximate locations of
ionospheric irregularities, as well as the severity of their
effects on the GPS signals, in a frame of latitude and local time.
It needs to be noted that at low elevation angles, a radio ray
passes large horizontal distances. The projected irregularity
locations under such conditions only give a relative estimation
in the frame of globe.
Figure 6a shows a ROTI map for the period of 0000-0015
UT on January 10, 1997, prior to the storm sudden
commencement (SSC) occurred around 03 UT, indicated in a Dst
enhancement (Figure 5). Irregularities can be seen in some
areas such as those at low latitudes in a South America region
(-21 LT), and at northern high latitudes (- 15 LT) as well as i n
the Antarctic region (~10-13 LT) About one hour after the
SSC, a development of ionospheric irregularities was recorded
PI ET AL.: MONITORING OF GLOBAL IONOSPHERIC IRREGULARITIES
during 0415-0430 UT (Figure 6b), in a northern America high
latitude region (-,, 20-23 LT) where ROTI values are higher than
2. Six hours later, the magnetic storm went into a deep main
phase and Dst reached about -80 (Figure 5). Meanwhile, GPS
phase fluctuations, shown in Figure 6c, became stronger and
irregularity regions expanded in the post-midnight sectors at
northern high latitudes, and in the evening sectors in the
Antarctic region where GPS data are available. These
nighttime and daytime ionospheric irregularities may be
related to the plasma density "blobs" and "patches" associated
with auroral oval expansion, and dynamical as well as plasma
instability processes in the cusp/cleft and polar cap regions
[e.g., Basu et al., 1994; Kersley et al., 1995; Pryse et al.,
1996]. It is also noticed that even though the event occurred in
a year around a solar minimum, ROTI values in some regions
still exceeded a level of 3. It is expected that GPS phase
fluctuations in a high solar activity year can be much stronger
than those shown in Figure 6 [e.g., Aarons et al., 1995]. A full
view of the irregularity evolution for this storm event is
accessible in an electronic movie via World Wide Web, at
http ://sidesho w.j pl. nasa. gov/gpsiono/97j an_i rreg. ht ml.
It should be noted that the present GPS network does not
yet provide a fully global coverage. The monitoring of
temporal changes of irregularities in the LT/Lat frame are thus
limited by sampling a different region. For instance, in Figure
6c, the lack of data during the UT interval makes it impossible
to identify the irregularities in the evening sector in the
northern auroral region.