Layout 6


Ionospheric perturbations associated with two huge earthquakes in Japan,
using principal component analysis for multiple subionospheric VLF/LF
propagation paths

Yuya Ono1,2, Yuichi Ida1,2, Yasushi Kasahara1,2, Yasuhide Hobara1,2,3, Masashi Hayakawa2,4,5, 
Alexander Rozhnoi6, Maria Solovieva6, Oleg A. Molchanov6, Kenji Ohta7

1 University of  Electro-Communications, Graduate School of  Informatics and Engineering, Tokyo, Japan
2 University of  Electro-Communications, Research Station on Seismo Electromagnetics, Tokyo, Japan
3 University of  Electro-Communications, Center for Space Science and Radio Engineering, Tokyo, Japan
4 University of  Electro-Communications, Advanced Wireless Communications Research Center, Tokyo, Japan
5 University of  Electro-Communications Incubation Center, Hayakawa Institute of  Seismo-Electromagnetics, Co. Ltd., Tokyo, Japan
6 Institute of  Physics of  the Earth, Russian Academy of  Science, Moscow, Russia
7 Chubu University, Kasugai Aichi, Japan

ANNALS OF GEOPHYSICS, 55, 1, 2012; doi: 10.4401/ag-5329

ABSTRACT

The presence of  ionospheric perturbations in possible association with two
huge earthquakes (Noto-hanto peninsula and Niigata-chuetu-oki
earthquakes) in 2007 was studied on the basis of  a conventional statistical
study for a particular propagation path from the JJI transmitter in
Miyazaki, Kyushu, to Moshiri in Hokkaido. This is based on automatic
routine-based signal processing, in which the trend as the average night-
time amplitude is significantly decreased, with almost simultaneous
significant enhancement in the night-time fluctuation as the night-time
integration of  negative fluctuation from the average. It is, however, shown
that this routine-based signal analysis sometime suffers from artificial (or
man-made) effects. Thus, in this study, we propose an additional use of
principal component analysis (PCA) for simultaneous observation of  a few
VLF/LF propagation paths. With the application of  this PCA method to
multi-path data, the artificial effects can be reasonably removed, and also
only the geophysical effects associated with earthquakes are detected, by
focusing mainly on the third principal component. The satisfactory
separation of  the principal components is made possible by pre-analysis of
the VLF data (extraction from the raw data of  the average over a whole
year). This PCA method enables us to identify the seismogenic effects in
association with earthquakes with smaller magnitudes, down to M 5.5 or
M 5.0.

1. Introduction
There has been an accumulation of a lot of

electromagnetic phenomena that might be associated with
earthquakes [e.g., Molchanov and Hayakawa 2008,

Hayakawa 2009a]. These seismogenic effects can be classified
as from the lithosphere [e.g., Fraser-Smith 2009, Freund
2009], in the atmosphere [Biagi 2009, Hayakawa 2009b] or in
the ionosphere [Hayakawa 2009c, Liu 2009, Parrot 2009]. In
particular, there appears to be a consensus that the
ionosphere is perturbed prior to large earthquakes, both in
the lowest D/E region and in the upper F region [e.g., Liu et
al. 2006].

We have been recording the network observations of
subionospheric very low frequency (VLF)/low frequency
(LF) propagation in and around Japan [see Hayakawa et al.
2004, Molchanov and Hayakawa 2008, Hayakawa 2009c]. A
substantial number of studies have been carried out on the
presence of seismo-ionospheric perturbations and their
temporal and spatial characteristics on the basis of case
studies, and also of statistical studies. Case studies start from
the 1995 Kobe earthquake [Hayakawa et al. 1996, Molchanov
and Hayakawa 1998], and many case studies were
summarized by Hayakawa [2009c]. In terms of statistical
studies, there have been a few reports [Rozhnoi et al. 2004,
Maekawa et al. 2006, Kasahara et al. 2008]. Recently,
Hayakawa et al. [2010a,b] published two studies that
indicated that there are significant statistical correlations of
these ionospheric perturbations with earthquakes with
magnitudes >6.0 and with shallow depths (d <40 km).

Even under these conditions, there is the need to
increase the numbers of case studies of seismo-ionospheric
perturbations for the huge earthquakes that have occurred

Special Issue: EARTHQUAKE PRECURSORS

139

Article history
Received July 29, 2011; accepted September 30, 2011.
Subject classification:
Ionospheric perturbations, Earthquakes, Subionospheric VLF/LF propagation, Principal component analysis.



in Japan. During 2007, there were two huge earthquakes in
Japan with magnitudes >6: the Noto-hanto peninsula and
Niigata-chuetsu-oki earthquakes. By making full use of our
VLF/LF network data, we provide here a case study of the
seismo-ionospheric perturbations for these two earthquakes.

We initially indicate the results based on conventional
statistical analysis for a specific propagation path that is
closest to these two earthquakes. Then, to confirm the
presence of these seismogenic ionospheric perturbations, we
suggest the additional important analysis method of
principal component analysis (PCA). Ten years ago, we
proposed the use of PCA of multi-stationed ultra-low
frequency (ULF) data to identify the presence of seismo-ULF
electromagnetic emissions [Gotoh et al. 2002], and here this
method is applied to subionospheric VLF/LF data from
different propagation paths. 

2. Target earthquakes and VLF/LF network observations
We consider the complete year of data for 2007, as this

period included two major earthquakes that were strong
even for Japan: the Noto-hanto peninsula earthquake (March
25, 2007; M 6.8, d = 8 km) and the Niigata-chuetsu-oki

earthquake (July 16, 2007; M 6.6, d = 12 km). Figure 1
illustrates the propagation paths from the VLF transmitter
with a call sign of JJI (Kyushu, Miyazaki, 22.2 kHz) to the
three receiving stations, MSR (Moshiri, Hokkaido), KCK
(Kamchatka, Russia) and TYM (Tateyama, Chiba). One
additional propagation path is plotted from another Japanese
LF transmitter, with a call sign of JJY (Fukushima, 40 kHz),
to MSR. Their corresponding wave-sensitive areas defined by
the 5th Fresnel zone are also indicated in Figure 1. For these
propagation paths, we took earthquakes with magnitudes >5
from the US Geological Survey earthquake catalog, as also
indicated in Figure 1, that might have effects on the VLF/LF
propagation. Each circle in Figure 1 corresponds to an
earthquake, with the earthquake epicenter at its center, and
with the circle size (radius) proportional to the magnitude
of the earthquake. The color of the circle indicates the
earthquake depth, as indicated in Figure 1, and the numbers
with the circles indicate the dates when the earthquakes
occurred.

3. Conventional statistical data analysis
Conventional (routine based) signal processing was

applied to the propagation path from JJI to MSR over the one
year of data for 2007, using the night-time fluctuation
method [as in Hayakawa et al. 2010a]. This path was the
most suitable for the study of these two earthquakes. Using
this method, we estimated the average night-time amplitude,
called the trend, the dispersion, as the night-time amplitude
fluctuation, and the night-time fluctuation; the details of
those parameters were described by Kasahara et al. [2008]
and Hayakawa et al. [2010a]. All of these parameters were
normalized with their corresponding standard deviations (v)
over 30 days before any current day. Figure 2 shows the result
of an automatic (or routine based) analysis over the year
2007, for the JJI-MSR path. The top panel of Figure 2 shows
the temporal evolution of the trend, the second panel shows
the dispersion, and the third panel shows the night-time
fluctuation. The bottom panel of Figure 2 shows the plot of
RKp (the geomagnetic activity). As has already been shown
statistically [Hayakawa et al. 2010a], the most important
parameter, the trend, was seen to decrease several days
before an earthquake, while the other two parameters, as
dispersion and night-time fluctuation, respectively, tended to
be simultaneously enhanced prior to an earthquake. Let us
look at the result in Figure 2. A significant decrease in the
trend is seen at least before the two huge earthquakes of
interest. Over the week before the Noto-hanto peninsula
earthquake, we note a significant decrease in the trend, and
correspondingly, the other two parameters are seen to be
enhanced. This was apparently a precursor to this
earthquake. 

Next, we move on to the second earthquake, that of
Niigata-chuetsu-oki. Again, a noticeable decrease (exceeding 

140

ONO ET AL.

Figure 1. Relative locations of the two Japanese transmitters with call signs
of JJY in Fukushima and JJI in Kyushu, and the VLF/LF observation
stations: MSR (Moshiri), TYM (Tateyama, Chiba), and KCK (Kamchatka,
Russia). The two large earthquakes of Noto-hanto peninsula (March 25,
2007) and Niigata-chuetsu-oki (July 16, 2007) are indicated as the two
largest circles. Other earthquakes are also shown by circles, with the
earthquake epicenter at the circle center, the circle size (radius)
proportional to the magnitude of the earthquake, the circle color
indicating the earthquake depth, and the numerals indicating the date of
occurrence. The ellipses show the wave-sensitive areas for each
propagation path between the transmitters and receivers.



141

–3v) is seen in the trend over about one week prior to this
second earthquake. The dispersion is not enhanced so much,
but the night-time fluctuation is increased. This characteristic
is considered to be a precursor to this second earthquake. One
more thing that should be mentioned is that the geomagnetic
activity was rather quiet during the VLF anomaly. Another
clear anomaly was noted at the end of August, until the
beginning of September, 2007, which was probably related to
a series of rather strong after-shocks that occurred up to the
beginning of September, 2007.

However, some abnormal behaviors were seen during
this year (2007). For example, by looking at the temporal
evolution of the trend in Figure 2 (top panel), there is one
depletion peak (one day) in the middle of February, and
another towards the end of May, with another one-day

depletion peak at the end of December, 2007. These are seen
to exceed –3v in the trend, which is too strongly abnormal
and they look artificial. A normal perturbation that appears
to be associated with an earthquake is known to persist for at
least a few days, or even more. However, of course, a one-day
anomaly is also possible for an earthquake with a smaller
magnitude, so that it appears difficult to distinguish between
a seismogenic effect and an artificial (man-made) effect,
except by using a single propagation path. When only one
propagation path was considered, we compared those
anomalies (probably not associated with earthquakes) with
the other corresponding phenomena (solar-terrestrial and
meteorological effects), to study these peaks extensively.
However, we have the advantage that we have the data for a
few subionospheric VLF/LF propagation paths, and this is

SEISMO-IONOSPHERIC PERTURBATIONS

Figure 2. The temporal evolution for the conventional routine-based analysis for 2007. Top panel, trend; second panel, dispersion; third panel, night-time
fluctuation (parameters normalized with their corresponding standard deviations); bottom panel, temporal evolution of RKp (geomagnetic activity). The
two big earthquakes of interest are indicated at the top of the top panel (EQ, downward arrows). The likely seismogenic effects are marked by red arcs
in the top panel, while some unlikely anomalies are indicated by question marks.



the reason why we propose the use of PCA for the data
analysis of these few subionospheric VLF/LF propagation
paths. The purpose of the use of PCA is to: (1) re-confirm
the existence of seismo-ionospheric perturbations for these
two huge earthquakes; (2) determine whether these one-day
anomalies are really artificial or not; and (3) explore the
possibility of identifying the ionospheric perturbations for
even weaker earthquakes, with magnitudes down to M ~5.

4. PCA and preparation of  the data for PCA 
We present some fundamental descriptions of PCA,

which involves a mathematical procedure that transforms a
number of possibly correlated variables into a number of
uncorrelated variables, called the principal components;
these are related to the original variables by an orthogonal
transformation. This transformation is defined in such a way
that the first principal component has as high a variance as
possible (that is, accounts for as much of the variability in
the data as possible), and each succeeding component in turn
has the highest variance possible under the constraint that it
be orthogonal to the proceedings.

PCA is intended to identify different noise sources from
multiple data. Gotoh et al. [2002] made the first attempt to
investigate seismogenic ULF emissions by applying PCA to
the multi-stationed ULF data observed at three stations on
the Izu peninsula, in the case of the Izu Islands earthquake
swarm. They then found that the third principal component
was highly likely to be seismogenic.

We have to prepare the subionospheric VLF/LF data
observed for three propagation paths. The propagation paths
we chose were:

1) The JJY transmitter (Fukushima) – MSR (Moshiri,
Hokkaido);

2) The JJI transmitter (Miyazaki) – MSR;
3) The JJI transmitter – KCK (Kamchatka, Russia).
This was because we are interested in the two major

earthquakes that occurred in the year of 2007 on the side of
the Japan Sea.

4.1 Selection of  analysis time interval
The above three propagation paths were chosen based

on the relative locations of the transmitters and receivers
with respect to our huge earthquakes, so that the local night-
time was different from one path to another. In particular,
the local night was a few hours different for the two paths of
JJI-MSR and JJI-KCK. Then, we chose the time interval of
UT = 12-16 h (4 h) as the common night-time for all of the
above three propagations, with exclusion of the terminator
times, as studied by Hayakawa et al. [1996]. The sampling
rate of our VLF/LF receiving system was 120 s, so that we
can use 120 data points (N = 120) for one day for one
propagation path. As the total, we have 360 data points per
day for all three of the propagation paths.

4.2. Selection of  the analysis method 
There were some differences in the propagation

characteristics for these three propagation paths. So we tried
the following three possible pre-analysis methods before the
application of PCA, in order to have appropriate and
acceptable results. 

a) The use of the raw data. PCA was applied to the raw
data sampled every 120 s during the same local night-time
(UT = 12-16 h) observed for the three propagation paths.

b) Extraction from the raw data of the night-time
average amplitudes through the whole period. Initially we
estimated the average night-time (same UT as before)
amplitude over the whole period (one year) for a particular
path, and we took the difference between the current data
and the average above. The same procedure was used for the
other two paths, and then we applied PCA to these data.

c) The difference between the current raw data and the
average on each current day. Unlike the above procedure, we
take the averages during the local night (UT = 12-16h) on
each day, and we take the differences between the raw data
and this average. The same procedure was applied to the
other two paths, and then PCA was applied to these data.

4.3. Comparison of  PCA results for the three different methods
We analyzed the data for the two years of 2006 and

2007. Although the main target was 2007, we also
investigated another year, as 2006, because there were not so
many large earthquakes in 2006, and so it was suitable to
study which pre-analysis treatment in Subsection 4.2 was best
for the further PCA analysis. 

The PCA results are illustrated in Figures 3, 4 and 5, for
the VLF/LF data in Subsection 4.2 (i.e., for the pre-analysis
methods a, b and c, respectively). In these figures, the
eigenvalues of the first, second and third principal
components (m1, m2 and m3) are plotted for the whole year of
2006. The earthquake information is given at the top of each
top panel of Figures 3, 4 and 5, as a downward arrow that
indicates the earthquake magnitude, with all of the
earthquakes with magnitudes <6.0.

Figure 3 is the PCA result for the data as (a) in
Subsection 4.2 (i.e., use of the raw data). This PCA was
intended to separate a few possible effects, such as
geomagnetic variations, seasonal variations, and earthquake
effects, among others. Figure 3 indicates that only the first
principal component is well separated; although we noted
the significant similarities in the temporal evolutions of the
second and third principal components, we utterly failed to
extract the second and third components. So, this pre-
analysis treatment (a) is not so good for PCA analysis.

Next, we move to Figure 5 using the data as (c) in
Subsection 4.2. A comparison of the temporal evolution of
the three principal components (m1, m2, m3) suggested that
they show similar temporal variations, which indicates

ONO ET AL.

142



143

apparent correlations among the three components. Due to
this, this method was not effective in separating two
components and is not appropriate for our PCA.

On the other hand, Figure 4 shows the PCA results for
the data (b) in Subsection 4.2 (while considering the
average over the whole period of one year), which

indicates that there appears to be nearly no (or weak)
correlation among the three principal components. So, the
three principal components are likely to be well separated,
such that in the following we adopt this pre-treatment (b)
of Subsection 4.2 for further PCA procedures for our target
year of 2007.

SEISMO-IONOSPHERIC PERTURBATIONS

Figure 3. Temporal evolution of the eigenvalues of the three principal components (m1, m2 and m3, as indicated) for 2006, using method (a) in Subsection
4.2. The information for the earthquakes (see Figure 1) is indicated by the marks (top panel), according to date, magnitude (length) and depth (color).

Figure 4. Temporal evolution of the eigenvalues of the three principal components (m1, m2 and m3, as indicated) for 2006, using method (b) in Subsection
4.2. Details as for Figure 3.



ONO ET AL.

144

Figure 5. Temporal evolution of the eigenvalues of the three principal components (m1, m2 and m3, as indicated) for 2006, using method (c) in Subsection
4.2. Details as for Figure 3.

Figure 6. Temporal evolution of m2/m1 (top), m3/m1 (middle) and RKp (geomagnetic activity; bottom) for 2006. The information for the earthquakes (see
Figure 1) is indicated by the marks (middle panel), according to date, magnitude (length) and depth (color).



145

4.4. Analysis data and analysis results
Now we come back to Figure 4 to discuss this figure

carefully, because the separation of the principle components
is best using the data treatment as (b) in Subsection 4.2. The
ordinate indicates the intensity of each principal component.
From the top, there are the first, second and third principal
components. When we have no plots, it means there are no
data. When we focus on the first principal component (m1), it
tends to increase from spring to summer, decrease from
summer to autumn, increase from autumn to winter, and
decrease from winter to spring. The occurrences of the
earthquakes are indicated along the top of the top panel in
Figure 4. It appears that the first principal component does
not depend on the earthquakes. Then, for the second
principal component, the value of m2 is seen to be enhanced
in February, March, November and December. However, we
cannot judge whether m2 is correlated with any earthquakes
or not. Finally, the third principal component (m3) was
enhanced in November and December, although it cannot
be certain whether m3 in Figure 4 is correlated with

earthquakes, because the earthquakes for this year were too
weak (magnitudes <5.5).

To study the detailed temporal evolution of m2 and m3, in
Figure 6 we used the conventional ratios of m2/m1 (upper
panel), m3/m1 (lower panel) and RKp (bottom). The ratio of
m2/m1 shows enhancements in its value in February-April and
in November-December. By comparing these temporal
variations of �m2/m1 with the corresponding variation of RKp
(geomagnetic activity) in the bottom panel of Figure 6, we can
imagine that the temporal evolution of m2/m1 approximately
reflects the variation in the RKp index (albeit, not so perfectly).
Thus, we can regard the ratio of m2/m1 as an indicator of the
geomagnetic activity. On the other hand, the second ratio, of
m3/m1, in Figure 6 is relatively quiet during the whole of this
year, as compared with the variation of m2/m1. When the
earthquake epicenter was located within the Fresnel zones of
a few propagation paths, we can easily identify the ionospheric
perturbation. When we focus on earthquakes in Figure 1 for
which two paths from the chosen three are within the relevant
Fresnel zones, the ratio of �m3/m1 shows significant

SEISMO-IONOSPHERIC PERTURBATIONS

Figure 7. Temporal evolution of the eigenvalues of the three principal components (m1, m2 and m3, as indicated) and RKp (geomagnetic activity; bottom)
for 2007 (data for November and December 2007 are missing). Details as for Figure 3.



enhancements 2-10 days before an earthquake. This is true for
three earthquakes out of the four. So the ratio of m3/m1 is
considered to reflect the earthquake signature well, even
though there appears to be some effects of m2.

Figure 7 is the result of the PCA analysis for 2007
(November and December data are missing), the year of our
main interest. This is based on the data treated as for (b) in
Subsection 4.2, because we have already seen that the
separation into the first to third principal components is best,
as compared using the corresponding results for the previous
year of 2006 for the other two data analyses, as (a) and (c) in
Subsection 4.2. When we look at the temporal evolution of
the first principal component (i.e., the eigenvalue of the first
principal component (m1)) at the top panel of Figure 7, we
see that the value of m1 does not fluctuate very much, and
that it has no relationship to any of the earthquakes. Next,
we look at the temporal evolutions of the eigenvalues m2 and
m3 of the second and third principal components in Figure 7.
The second principal component is enhanced during January
and through March, to vary similarly and to increase before
the two huge earthquakes (Noto-hanto peninsula earthquake

and Niigata-Chuetsu-oki earthquake; i.e., from 1~10 days
before these earthquakes).

To enhance the variations of m2 and m3 more clearly,
Figure 8 illustrates the temporal evolutions of the ratios
m2/m1 (top panel) and �m3/m1 (second panel), and of RKp
(bottom panel). As was already seen for the previous year of
2006 in Figures 5 and 6, the ratio of �m2/m1 for 2007 is
relatively disturbed over the whole year, although the ratio of
m3/m1 is relatively stable. In other words, the variability of
m2/m1 is much larger than that of �m3/m1. A comparison of the
temporal variation of m2/m1 with the RKp index, might
suggest a relatively close resemblance between these two. On
the other hand, the ratio of m2/m1 shows nearly no
correlation with the variation of the RKp index. When we
focus on the Noto-hanto peninsula earthquake (on March 26,
2007), we can see a clear enhancement in the ratio of m3/m1
one to two weeks prior to the earthquake. A similar
enhancement in m3/m1 takes place a few days before the
Niigata-Chuetsu-oki earthquake on July 16, 2007. Similar
tendencies for enhancements in m3/m1 are noted for some
other earthquakes with smaller magnitudes, of the order of

ONO ET AL.

146

Figure 8. Temporal evolution of m2/m1 (top), �m3/m1 (middle) and RKp (geomagnetic activity; bottom) for 2007. Details as for Figure 6.



147

5.0. The larger the earthquake magnitude, the larger the
enhancements in the ratio of m3/m1.

5. Concluding remarks 
To further define the presence of seismo-ionospheric

perturbations on a particular subionospheric VLF/LF
propagation path using our conventional night-time
fluctuation analysis (trend, dispersion, and night-time
fluctuation) [e.g., Muto et al. 2009, Kasahara et al. 2009,
Hayakawa et al. 2010a], we proposed the use of PCA. This
can make use of our advantage of simultaneously having a
few propagation paths, which might be an impetus to
VLF/LF propagation studies. In one sense, we would like to
accumulate more evidence on the existence of seismo-
ionospheric perturbations for huge earthquakes in Japan as
case studies (in the present case, for two earthquakes, the
Noto-hando peninsula earthquake and the Niigata-Chuetsu-
oki earthquake, both in 2007 and with magnitudes >6.0).

To cover the above two huge earthquakes as our target,
we used the data from three VLF/LF propagation paths (JJY-
MSR, JJI-KCK and JJI-MSR). Initially, we compared three
different pre-analysis methods for our VLF/LF data, to
determine which pre-analysis is the best for the independent
separation of the three eigenvalues of the PCA application.
As the result, the extraction of the average amplitudes from
the raw data over the whole year indicated that the three
eigenvalues were well separated. Then, we found that the
ratios of m2/m1 and m3/m1 are more suitable for the physical
discussion. The ratio of �2/�1 reflects the variations in the
geomagnetic activity (RKp index) well, whereas the ratio of
m3/m1 appears to be an indicator of earthquakes. By looking
at the temporal evolution of m3/m1, we can definitely conclude
that there are definite ionospheric perturbations before these
two major earthquakes of our present interest (Noto-hando
peninsula earthquake and Niigata-Chuetsu-oki earthquake),
that had large magnitudes (>6.0) and shallow depths. These
perturbations are confirmed as precursors to these
earthquakes. The values of m3/m1 for these earthquakes are
well pronounced due to their huge magnitudes, and we can
conclude that the use of PCA based on multiple propagation
paths allows us to re-confirm the presence of seismo-
ionospheric disturbances detected by the conventional
statistical approach for a particular path. Also, we can reject
the anomalies seen in the conventional analysis (Figure 2),
which are likely to be artificial. Finally, it becomes possible for
us to identify the ionospheric perturbations in association with
earthquakes with smaller magnitudes, down to M ~5, even
though the peak value of m3/m1 is less enhanced than that for
the huge earthquakes used as our targets.

Acknowledgements. This study was supported in part by National
Information and Communications Technology, Japan, and by FP7 grand
SEMEP, Russia, for which we are grateful.

References
Biagi, P.F. (2009). Pre and post seismic disturbances revea-
led on the geochemical data collected in Kamchatka
(Russia) during the last 30 years, In: Electromagnetic
Phenomena Associated with Earthquakes, edited by M.
Hayakawa, Transworld Research Network, Trivandrum
(India), ch. 4, 97-118.

Fraser-Smith, A.C. (2009). The ultralow-frequency magne-
tic fields associated with and preceding earthquakes, In:
Electromagnetic Phenomena Associated with Ear-
thquakes, edited by M. Hayakawa, Transworld Rese-
arch Network, Trivandrum (India), ch. 1, 1-20.

Freund, F. (2009). Stress-activated positive hole charge car-
riers in rocks and the generation of pre-earthquake si-
gnals, In: Electromagnetic Phenomena Associated with
Earthquakes, edited by M. Hayakawa, Transworld Re-
search Network, Trivandrum (India), ch. 3, 41-96.

Gotoh, K., Y. Akinaga, M. Hayakawa and K. Hattori (2002).
Principal component analysis of ULF geomagnetic data
for Izu islands earthquakes in July 2000, J. Atmos.
Electr., 22, 1-12.

Hayakawa, M. (Ed.) (2009a). Electromagnitic Phenomena
Associated with Earthquakes, Research Signpost/Tran-
sworld Research Network (India),Trivandrum (India),
279 pp.

Hayakawa, M. (2009b). Seismogenic perturbation in the at-
mosphere, In: Electromagnetic Phenomena Associated
with Earthquakes, edited by M. Hayakawa, Transworld
Research Network, Trivandrum (India), ch. 5, 119-136.

Hayakawa, M. (2009c). Lower ionospheric perturbations
associated with earthquakes, as detected by subiono-
spheric VLF/LF radio waves, In: Electromagnetic Phe-
nomena Associated with Earthquakes, edited by M.
Hayakawa, Transworld Research Network, Trivandrum
(India), ch. 6, 137-185.

Hayakawa, M., O.A. Molchanov, T. Ondoh and E. Kawai
(1996). On the precursory signature of Kobe ear-
thquake in subionospheric VLF propagation, J. Comm.
Res. Lab., 43, 169-180.

Hayakawa, M., O.A. Molchanov and the NASDA/UEC
team (2004). Summary report of NASDA’s earthquake
remote sensing frontier project, Phys. Chem. Earth, 29,
617-625. 

Hayakawa, M., Y. Kasahara, T. Nakamura, F. Muto, T.
Horie, S. Maekawa, Y. Hobara, A.A. Rozhnoi, M. Soli-
vieva and O.A., Molchanov (2010a). A statistical study
on the correlation between lower ionospheric pertur-
bations as seen by subionospheric VLF/LF propagation
and earthquakes, J. Geophys. Res., 115; doi:10. 1029/
2009JA015143.

Hayakawa, M., Y. Kasahara, T. Nakamura, Y. Hobara, A.
Rozhnoi, M. Solovieva and O.A. Molchanov (2010b).
On the correlation between ionospheric perturbations

SEISMO-IONOSPHERIC PERTURBATIONS



as detected by subionospheric VLF/LF signals and ear-
thquakes as characterized by seismic intensity, J. Atmos.
Solar-Terr. Phys., 72, 982-987.

Kasahara, Y., F. Muto, T. Horie, M. Yoshida, M. Hayakawa,
K. Ohta, A. Rozhnoi, M. Solovieva and O.A. Molchanov
(2008). On the statistical correlation between the iono-
spheric perturbations as detected by subionospheric
VLF/LF propagation anomalies and earthquakes, Nat.
Haz. Earth Syst. Sci., 8, 653-656.

Liu, J.Y. (2009). Earthquake precursors observed in the io-
nospheric F-region, In: Electromagnetic Phenomena
Associated with Earthquakes, edited by M. Hayakawa,
Transworld Research Network, Trivandrum (India), ch.
7, 187-204.

Liu, J.Y., Y.I. Chen and Y.J. Chuo (2006). A statistical study
of pre-earthquake ionospheric anomaly, J. Geophys.,
Res., 111; doi: 10.1029/2005JA011333.

Maekawa, S., T. Horie, T. Yamauchi, T. Sawaya, M. Ishi-
kawa, M. Hayakawa and H. Sasaki (2006). A statistical
study on the effect of earthquakes on the ionosphere,
based on the subionospheric LF propagation data in
Japan, Ann. Geophysicae, 24, 2219-2225.

Molchanov, O.A. and M. Hayakawa (2008). Seismo-elec-
tromagnetics and Related Phenomena: History and la-
test results, Terra Sci. Pub. Co., Tokyo., 189 pp.

Molchanov, O.A. and M. Hayakawa (1998). Subionosphe-
ric VLF signal perturbations possibly related to ear-
thquakes, J. Geophys. Res., 103, 17489-17504.

Muto, F., Y. Kasahara, Y. Hobara, M. Hayakawa, A. Ro-
zhnoi, M. Solovieva and O.A. Molchanov (2009). Fur-
ther study on the role of atmospheric gravity waves on
the seismo-ionospheric perturbations as detected by su-
bionospheric VLF/LF propagation, Nat. Haz. Earth
Sys., 9, 1111-1118.

Parrot, M. (2009). Anomalous seismic phenomena view
from spaces, In: Electromagnetic Phenomena Associa-
ted with Earthquakes, edited by M. Hayakawa, Tran-
sworld Research Network, Trivandrum (India), ch. 8,
205-234.

Rozhnoi, R., M.S. Solovieva, O.A. Molchanov and M. Ha-
yakawa (2004). Middle latitude LF (40 kHz) phase va-
riations associated with earthquakes for quiet and
disturbed geomagnetic conditions, Phys. Chem. Earth,
29, 589-598.

*Corresponding author: Masashi Hayakawa
University of Electro-Communications (UEC), Research Station on
Seismo Electromagnetics, Tokyo, Japan;
e-mail: hayakawa@whistler.ee.uec.ac.jp 

© 2012 by the Istituto Nazionale di Geofisica e Vulcanologia. All rights
reserved.

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