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Variation Evaluation of Path Characteristic and Site 

Amplification Factor of Earthquake Ground Motion at 

Four Sites in Central Japan 
 

Takashi Nagao 

Research Center for Urban Safety and Security 
Kobe University 
Kobe City, Japan 

nagao@people.kobe-u.ac.jp  
 

 

Abstract-The considered parameters in seismic design vary, with 

the Earthquake Ground Motion (EGM) having the largest 

variation. Since source characteristic, path characteristic, and 

Site Amplification Factor (SAF) influence the EGM, it is crucial 

to appropriately consider their variations. Source characteristic 
variations are mainly considered in a seismic hazard analysis, 

which is commonly used to evaluate variations in EGM. 

However, it is also important to evaluate variations in path 

characteristic and SAF with only a few studies having 

individually and quantitatively examined the variations of these 

two characteristics. In this study, based on strong-motion 

observation records obtained from four sites in central Japan, the 

three characteristics were extracted from seismograms using the 

concept of spectral inversion. After removing the source 

characteristic, the path characteristic and SAF were separated, 

and the variations in these two characteristics were quantified. 

To separate and obtain each characteristic from the observed 

record, one constraint condition must be imposed, whereas the 

variations in the constraint condition must be ignored. In that 
case, the variations in the constraint condition are included in the 

variations of the separated characteristics. In this study, this 

problem was solved by evaluating the variation in the constraint 

condition, which is the SAF at a hard rock site, by the use of the 
vertical array observation record at the site. 

Keywords-earthquake ground motion; path characteristic; site 

amplification factor; variation   

I. INTRODUCTION  

In seismic design, the cross-section of a structure is 
determined in such a way that the cross-sectional resistance 
exceeds the section force caused by an earthquake. Since the 
parameters to be considered in seismic design vary, the cross-
section of a structure should be set considering the possibility 
that the seismic load acting on the structure exceeds the design 
value. The Earthquake Ground Motion (EGM) has the largest 
variation among the considered parameters in seismic design. 
Therefore, it is critical to accurately evaluate the variation in 
EGM. Seismic hazard analysis [1] is a method for considering 
variations in EGM. In seismic hazard analysis, probabilistic 
EGM is evaluated by considering variations in parameters such 
as seismic magnitude and hypocenter location. 

EGM is determined by three characteristics: source 
characteristic, path characteristic, and Site Amplification Factor 
(SAF). These three characteristics must be considered carefully 
because the EGM varies significantly depending on the 
evaluation method of these characteristics [2]. In seismic 
hazard analysis, source characteristic is the major variation 
evaluation object, and path characteristic and SAF are treated 
deterministically. However, since these two characteristics vary 
in reality, it is necessary to evaluate the variations in path 
characteristic and SAF separately in order to conduct rational 
seismic design. Although there are many research cases on the 
variation in amplification characteristics, the definitions of 
amplification characteristics vary, such as the ratio of spectral 
acceleration to the predicted value by ground motion prediction 
equations [3], the amplification at the object location with 
respect to the reference location [4], the ratio of the vertical 
array strong-motion observation record on the ground surface 
to the borehole [5, 6], and the residual of the observed EGM to 
the probabilistically evaluated EGM [7]. The SAF to be 
considered when the EGM is separated into the three 
characteristics must include not only the amplification by the 
shallow subsurface but also that by the deep subsurface, 
because the amplification factor by a shallow subsurface is 
significantly smaller than the actual SAF [8, 9]. Therefore, the 
variation in SAF for each frequency, including the effect of 
deep subsurface must be evaluated. 

There are cases in which the variations of SAF, including 
the effect of deep subsurface, were studied using the spectral 
ratio of seismograms observed at two sites [10, 11]. However, 
these studies did not separate path characteristic and SAF, and 
because path characteristic was treated deterministically, their 
results included variations of path characteristic and SAF. 
There are no case studies in which the variations in path 
characteristics and SAF were quantified after separation. 
Spectral inversion [12, 13] is a technique for separating each 
characteristic from the observed records. The current study 
separates path characteristic and SAF based on the concept of 
spectral inversion and conducts quantitative evaluation of each 
variation. 

Corresponding author: Takashi Nagao



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II. METHOD 

A. Target Sites and Target Earthquakes 

This study focuses on four sites (GIFH20, GIFH24, 
GIFH28, and NGNH20) in central Japan that are part of the 
KiK-net [14] strong-motion seismograph network as shown in 
Figure 1. KiK-net provides EGMs recorded at the ground 
surface and in the borehole simultaneously, and P-S logging 
reveals the S-wave velocity profile leading to the seismograph 
installation position in the borehole. Strong-motion records and 
ground data were made available to the public by [15]. 
However, seismographs in boreholes are rarely installed at 
seismic bedrock in which S-wave velocity exceeds 3km/s. 
Therefore, the S-wave velocity profile from the ground surface 
to the seismic bedrock was obtained by combining the 
information from KiK-net and J-SHIS [16] as described in [8]. 
The obtained S-wave velocity profiles are shown in Figure 2. 
Among the sites, GIFH28 has the thickest and NGNH20 the 
thinnest sediment site. In GIFH24, the depth at which the S-
wave velocity exceeds 1500m/s is shallower than that in 
NGNH20. The multiple reflection theory calculates transfer 
functions assuming horizontally stratified ground conditions 
(Figure 3). In the frequency range of 0.1–10Hz, which is 
important in seismic engineering, the amplification factor of 
GIFH24 is the smallest with values less than 2 in the frequency 
range lower than 7Hz. Because the soil layer thickness with an 
S-wave velocity of 720m/s is relatively thick (= 25m), the 
amplification factor is as high as 5 at 6Hz in NGNH20. First-
order peaks occur at 2Hz in GIFH20 and 0.6Hz in GIFH28, in 
which the sedimentary layer is the thickest. 

 

 
Fig. 1.  Target sites. 

 
Fig. 2.  S-Wave velocity profiles. 

Table I shows the list of the considered events. The 
epicenters of the target events, as well as the locations of the 
observation sites, are shown in Figure 4. The red circles 
indicate seismograph installation sites, and the blue cross 
marks indicate the epicenters. The epicenters do not exist on 
the west side of the observation sites, but they are distributed 
evenly in the other directions.  

 

 
Fig. 3.  Transfer functions. 

TABLE I.  TARGET EARTHQUAKES 

No Date Time 
Lon 

(deg) 

Lat 

(deg) 

Depth 

(km) 
M Site* 

1 Sep/27/2020 13:13 137.80 35.10 45 5.3 b, c, d 

2 Apr/23/2020 13:44 137.32 35.64 3 5.5 b, d 

3 Feb/13/2018 14:39 137.59 35.87 3 4.1 b, c, d 

4 Dec/6/2017 00:13 137.97 36.38 10 5.3 b, d 

5 Jun/25/2017 07:02 137.59 35.87 7 5.6 b, c, d 

6 Dec/6/2016 09:05 137.34 36.01 5 4.5 b, c, d 

7 May/25/2015 14:28 139.64 36.05 56 5.5 a, b, d 

8 Mar/4/2015 00:04 136.80 35.34 40 4.6 a, b, c 

9 Dec/3/2014 23:19 137.12 35.29 45 4.2 a, b, c, d 

10 Sep/16/2014 12:28 139.86 36.09 47 5.6 a, b, d 

11 Jun/1/2012 17:48 139.88 36.03 44 5.1 a, b, c, d 

12 Apr/25/2012 05:22 140.68 35.72 43 5.5 a, b, d 

13 Jan/28/2012 07:43 138.98 35.49 18 5.4 a, b, c, d 

14 Jun/30/2011 08:21 137.95 36.19 4 5.1 a, b, d 

15 Apr/16/2011 11:19 139.94 36.34 79 5.9 a, b, c, d 

16 Mar/16/2011 03:33 137.30 36.00 0 4.0 a, b, c, d 

* a: GIFH20, b: GIFH24, c: GIFH28, d: NGNH20 

 

 
Fig. 4.  Target Sites and epicenters. 

Because EGM records of small seismic magnitude (M) 
have a low signal-to-noise (S/N) ratio, events of seismic 
magnitude M = 4.0 or larger are considered. Additionally, 
EGM records of M = 6.0 or larger are excluded to avoid the 

effect of the rapture process at the fault plane. With the ω
−2
 

model [17], only EGM records with good S/N ratios in the 
range of 0.3Hz or higher were used. To discuss the 
amplification characteristics of S-waves, 10.24s records were 
extracted for the S-wave arrival. Before calculating the Fourier 
spectra, baseline correction was conducted, and the extracted 

136 137 138 139 140 141
34

35

36

37

Longitude (deg)

L
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records were tapered. Based on the root mean square of the 
Fourier spectra of seismograms recorded horizontally in two 
directions, a Parzen window with a bandwidth of 0.3Hz was 
used to smooth the spectra. 

B. Separation Method of the Three Characteristics 

The three characteristics are separated from the observed 
records according to the concept of spectral inversion. This 
study focuses on seismograms of the same event recorded at 
multiple stations. The Fourier spectra of the observed records 
can be expressed as the product of the source characteristic, 
path characteristic, and SAF as shown in (1): 

ij i ij j
O ( f ) S ( f )P ( f )G ( f )=     (1) 

where O is the observed EGM, S is the source characteristic, P 
is the path characteristic, G is the SAF, i is the event number, j 
is the station number, and f is the frequency. The values of each 
characteristic for each frequency can be obtained by solving the 
equations simultaneously using (2) in which the equation is 
expressed as a common logarithm. 

ij i ij j
logO logS logP logG= + +     (2) 

The path characteristic can be expressed by (3): 

( )
1

ij ijn

ij

P ( f ) exp f r / QVs
r

= −π     (3) 

where r is the hypocentral distance and n is a value 
representing the geometric attenuation of the body wave, with 
its typical value being 1.0, but it is pointed out that n = 2 when 
the hypocentral distance is significantly long [18]. In this study, 
n = 2 was assumed for a dataset with hypocentral distances of 
120km or more. Vs is the average S-wave velocity along the 
propagation path, and Vs = 3.8km/s in the target area. Q is the 
Q-value, which represents the inelastic attenuation of EGM. 

There is a trade-off relationship among the characteristics: 
for example, a product of large path characteristics and small 
SAF can result in the same value as a product of small path 
characteristics and large SAF. Therefore, one constraint 
condition must be imposed to solve the equations 
simultaneously. The constraint condition is set as the SAF at 
one station and calculated as a theoretical SAF assuming one-
dimensional (1D) ground structure [19]. The SAF of a 
significantly small rock site is chosen for the constraint 
condition. However, even at rock sites, EGM is amplified in 
many cases because of weathering [20]. Furthermore, because 
of the heterogeneity of a three-dimensional (3D) ground 
structure, the SAF assuming 1D ground structures often 
underestimates the actual SAF [2, 21]. Therefore, it is desirable 
that the SAF used as a constraint condition to be as small as 
possible and the S-wave velocity profile down to seismic 
bedrock is disclosed. As shown in Figure 3, the amplification 
factor at GIFH24 is significantly small in the frequency band 
below 10Hz, and we can assume that the difference in SAF 
between the actual and the one calculated by assuming a 1D 
structure is negligible. As a constraint condition, this study uses 
the 1D amplification factor (1DA) at GIFH24. 

III. RESULTS AND DISCUSSION 

A. SAF Variation in Low-Frequency Bands at Hard Rock 

Sites 

Path characteristic and SAF can be separated in the spectral 
inversion and variations of the two characteristics can be 
discussed. However, the variation cannot be evaluated for the 
constraint condition. The constraint condition, which is the 
SAF at the reference hard rock site, also varies. Therefore, 
variations in the obtained characteristics include variations in 
the constraint conditions. Because seismographs are installed at 
the ground surface (S) and in boreholes (B) at KiK-net sites, the 
variation can be evaluated using the spectral ratio (S/B). 
However, even if the seismograph in the borehole is installed 
on the seismic bedrock, S/B cannot be considered as the SAF 
because borehole records include the upward EGM (E) and 
downward EGM (F), which are reflected at the layer boundary 
(E + F). Because E and F are identical on the ground surface, 
EGM is 2E, and the S/B becomes 2E/(E + F). However, the 
SAF is defined as the spectral ratio of the EGM at the ground 
surface to that obtained by doubling the incident EGM (E) at 
the bedrock (2E/2E). Figure 5 compares the S/B (= 2E/(E + F)) 
with the SAF (= 2E/2E) under horizontally stratified ground 
conditions, using GIFH24 and NGNH20 as examples. The red 
line represents the SAF, and the blue line represents the S/B. 
Although the difference between the two is large in the 
frequency band higher than 1Hz, it is tiny in the frequency 
band lower than 1Hz. Therefore, the variation in S/B in the 
frequency band lower than 1Hz of these two sites is the 
variation in the SAF. Figure 6 shows the variation in S/B 
calculated with the observation record. The gray line represents 
the individual S/B and the red line represents the average value. 
Each characteristic is separated on a logarithmic scale in the 
spectral inversion, as shown in (2). Therefore, unless otherwise 
specified, these results are on a logarithmic scale hereafter. The 
value of S/B agrees with the theoretical value on average in the 
frequency band of 1Hz or lower, although there is some 
dispersion.  

 

 
Fig. 5.  Comparison of 2E/(E + F) and (2E/2E). 

 
Fig. 6.  Variation in S/B. 



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Fig. 7.  SD of S/B. 

Figure 7 shows the standard deviation (SD) of S/B in the 
frequency band lower than 1Hz. The SD is large in frequencies 
lower than 0.4Hz because of the poor S/N ratio in the 
seismograms of small amplitude. The SD of the SAF of hard 
rock sites in the frequency band lower than 1Hz was 
determined to be 0.048 using the average SD in the range of 
0.488 to 1.074Hz. Figure 8 shows the histogram of the S/B, 
referring to the results at frequencies 0.586 and 0.781Hz. The 
probability distribution can be considered normal.

  

 

 
Fig. 8.  Histogram of S/B. 

B. Evaluation of Q-Value and Path Characteristic Variation 

Because the variation in the SAF at hard rock sites was 
obtained when considering the frequency band of 1Hz or 
lower, the variation in the path characteristics can be evaluated 
based on the results. The Q-value used to evaluate path 
characteristics varies by region, and its frequency dependence 
has been mentioned. There have been no previous studies on 
the Q-value for the regions covered in this study, but the Q-
values for other Japanese regions are Q = 83 f 

0.73 
[22] and  

Q = 33 f 
1.0 
[23]. In this study, we first evaluate the Q-value for 

the target area. Based on the simultaneous records from two 
locations (i.e. GIFH24 and NGNH20), we can evaluate the Q-
value using (4) and combining (2) and (3). 

( ) 10j k

k j k j j k

f r r log e

VsQ
logO logO logG logG nlogr nlogr

π −

=
− − + − +

    (4) 

where j and k are the observation stations.  

SAF in the frequency band higher than 1Hz cannot be 
determined at this point, but for frequencies lower than 1Hz the 
SAF of the two stations can be considered as 1.0. Therefore, 
the Q-value can be determined by (4). The Q-value was 
obtained as in (5) regarding the average Q-value for each 
frequency, and the minimum spectral residual, which is to be 
described later.  

Q = 70 f 
0.90
    (5) 

Figure 9 compares the average Q-value with the value 
obtained by (5). The blue line represents the average Q-value, 
and the red line represents the value according to (5). 

The variation in path characteristic is evaluated based on 
the obtained Q-value. By applying (2) to the records of two 
sites j and k (i.e. GIFH24 and NGNH20), the spectral residual 
(SR) is obtained as follows: 

j k j k j k
SR logO logO log P log P logG logG= − − + − +     (6) 

 

 
Fig. 9.  Q-value. 

The SR distribution is displayed in the left panel of Figure 
10. The gray lines represent individual results, and the red line 
represents the average value. If path characteristic and SAF do 
not vary, SR becomes zero. Although the average SR is 
generally zero for frequencies lower than 1Hz, the variation in 
SR is large. The SD of SR is shown in the right panel of Figure 
10. The average value of SD in the frequency band 0.293-
1.074Hz was determined to be 0.184. The histograms of SR at 
frequencies 0.586 and 0.781Hz are shown in Figure 11. 
Although the result at 0.586Hz deviates from the normal 
distribution, the frequency distribution at 0.781Hz can be 
considered normal. 

 

 
Fig. 10.  Distribution and SD of SR. 

 
Fig. 11.  Histogram of SR. 

0.2 0.4 0.6 0.8 1 1.2
0

0.02

0.04

0.06

0.08

0.1

frequency(Hz)

st
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a
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0.1 1 10
0

100

200

300

frequency (Hz)

Q
 v
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This SR variation includes the variations in path 
characteristics and SAFs of the two sites. Assuming that the 
path characteristic and SAF at each site follow independent 
normal distributions, the following equation holds: 

( )2 2 22SR P Gσ = σ + σ     (7) 

where σ is the SD. 

By using the SD of SAF obtained in the previous section, 
the SD of the path characteristic was determined to be 0.121. 

C. SAF and its Variation 

Based on the above results, the variation in SAF at the site 
where the effect of the sedimentary layer cannot be ignored is 
evaluated. Because the path characteristics vary slightly with 
frequency, the SD obtained in the previous section is assumed 
to be applicable at all frequencies. Furthermore, because 
GIFH24 is a site with a significantly small amplification factor 
in the frequency band lower than 10Hz, it is assumed that the 
average value of SAF at GIFH24 agrees with the amplification 
factor assuming 1D ground structure (1DA) considering ground 
structure leading to the seismic bedrock. Regarding the 
variation in SAF at GIFH24, it is assumed that the SD value 
obtained in the previous section for the low-frequency band can 
be applied to all frequencies. Based on the simultaneous 
records at GIFH24 and NGNH20, SAF and its variations of 
NGNH20 are evaluated by solving (6) for SAF at NGNH20 as 
shown in the left panel of Figure 12. The gray lines represent 
the individual results, and the red line represents the average 
value. The right panel of Figure 12 shows the average value 
and the SD of SAF. The red line represents the average value 
and the blue line represents the SD. The SD is less dependent 
on the frequency. The SD has an average value of 0.323 in the 
0.195–10Hz frequency band. Because the SD here includes 
variation in path characteristics at two sites and variation in 
SAF at GIFH24, these variations are removed using the same 
approach as in (7). The average values of the SD of SAF at 
NGNH20 in the frequency bands of 1–10Hz and 0.195–10Hz 
were determined to be 0.282 and 0.270 respectively. 
Furthermore, the SAF at GIFH28 is discussed. The procedures 
are the same as in NGNH20. The left panel of Figure 13 shows 
the SAF, with the gray lines representing the individual results 
and the red line representing the average value.  

 

 
Fig. 12.  Average and SD of SAF (NGNH20). 

The right panel of Figure 13 shows the average SAF (red) 
and the SD (blue) lines. The SD in the frequency band higher 
than 2Hz is slightly larger than that in the lower-frequency 
band. The average value of SD in the frequency band of 0.195–

10Hz is 0.316. When the variation in the SAF of GIFH24 and 
path characteristics of the two sites were removed from the SD, 
the average value of SD of SAF at GIFH28 was 0.061 in the 
0.195–1.1Hz frequency band, 0.277 in the 1–10Hz frequency 
band, and 0.262 in the 0.195–10Hz frequency band. 

 

 
Fig. 13.  Average and SD of SAF (GIFH28). 

 
Fig. 14.  Average and SD of SAF (GIFH20). 

 
Fig. 15.  Average SD of SAF. 

The left panel of Figure 14 shows the SAF for GIFH20, 
with gray lines representing the individual results and the red 
line representing the average value. The right panel of Figure 
14 shows the average value and SD of SAF, with the red line 
representing the average value and the blue line the SD. The 
average SD in the frequency band from 0.195 to 10Hz is 0.217. 
When the variation of the SAF of GIFH24 and the path 
characteristics of the two sites were removed from this SD, the 
average value of the SD of SAF at GIFH20 was 0.080 in the 
0.195–1.1Hz frequency band, 0.130 in 1–10Hz, and 0.125 in 
0.195–10Hz. 

Because the SD at each site varies with frequency, Figure 
15 shows the average SD in case of SAF with frequency. The 
SD is small for frequencies lower than 2Hz, in the range of 

0.10–0.15, but a large value of approximately 0.30 can be 
obtained in the case of GIFH28 and NGNH20 when 
considering frequencies higher than 3Hz. However, at GIFH20, 
the SD is almost constant in all frequency bands and is smaller 
than those at the other two sites. The average value of SAF 
varies significantly with frequency at the three sites, but the SD 

0 2 4 6 8 10
0

0.1

0.2

0.3

0.4

frequency (Hz)

S
D



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does not vary significantly with frequency and is not dependent 
on the average value of SAF. Because the SAF in the low-
frequency band is mainly determined by the deep subsurface 
structure, a low SD of the SAF in the low-frequency band 
indicates a minor local change in the deep subsurface structure 
near the observation sites. However, the SAF in the high-
frequency band mainly depends on the shallow subsurface 
structure, implying that the shallow subsurface structure is 
changing in a complex manner around the site where the SD of 
the SAF is large in the high-frequency band. However, the sites 
where the SDs of SAFs do not increase even in the case of 
high-frequency bands, such as in GIFH20, are considered to be 
sites at which the surrounding shallow subsurface structure 
does not change significantly. 

D. Comparison of 1DA and SAF  

Figure 16 compares the SAF in this study to 1DA used in 
design practice. The red line represents the average SAF, the 
blue line represents the 1DA considering shallow and deep 
subsurface, and the black line represents the 1DA considering 
shallow subsurface only. Note that those values are expressed 
on an arithmetic scale. Compared to the 1DA considering deep 
subsurface, the shallow subsurface 1DA significantly 
underestimates the amplification factors. This result is in 
accordance with the findings in [8]. Except for the second-
order peak at 1.5Hz of GIFH28, the 1DA considering deep 
subsurface underestimates the amplification factor compared to 
the SAFs in this study. Previous studies [2, 20] have also 
highlighted this trend. Except for the very thin sediment site, 
NGNH20, the SAFs at the other two thick sediment sites have 
high amplification factors over a wide-frequency band, whereas 
1DA has large amplifications only at certain frequencies. 
Therefore, when considering the EGM amplification in seismic 
design, it is necessary to use a method capable of evaluating the 
actual amplification factors, such as spectral inversion, rather 
than 1DA. 

 

 
Fig. 16.  SAF and 1DA. 

IV. CONCLUSION 

In this study, the source characteristic, path characteristic, 
and SAF were separated from observation records using the 
spectral inversion approach by utilizing the seismic records of 
four strong-motion observation sites in central Japan. The 
variation in path characteristics and SAF were quantified. The 
conclusions of this study are: 

• SAF and path characteristic can be separated by spectral 
inversion by imposing a single constraint condition, 
namely, SAF at a hard rock site. However, the variation 
cannot be evaluated for the constraint condition. Therefore, 
the variations obtained for each characteristic contain the 

variation in the constraint conditions. In this study, the SD 
of the constraint condition was evaluated using the variation 
in the spectral ratio of seismograms at the ground surface to 
those in the borehole. The obtained SD of the constraint 
condition was 0.048. 

• The SDs of the SR of two hard rock sites’ records were 
evaluated. The variation in path characteristic was 
evaluated by assuming that path characteristic and SAF 
follow independent normal distributions. The SD of the 
path characteristic was estimated to be 0.121. Finally, the 
variation in the SAF was evaluated. The SD of the SAF was 
independent of the average SAF and ranged from 0.10 to 
0.15 in the frequency band of 2Hz or lower. In the high-
frequency band, the SD of SAF was approximately 0.30 at 
GIFH28 and NGNH20 and approximately 0.10 at GIFH20. 
The SD in the high-frequency region varies significantly 
from point to point. This difference in SD is due to the 
difference in the uniformity of the shallow subsurface 
around the site. 

• The 1DA underestimates the SAF even when the ground 
structure down to the seismic bedrock is considered. At 
thick sediment sites, large SAF is observed in a wide-
frequency band, and the envelope of the SAF is completely 
different from that of the 1DA. Therefore, precise 
evaluation of the SAF is critical for rational seismic design. 

ACKNOWLEDGMENT 

Strong-motion records and ground data were provided by 
the National Research Institute for Earth Science and Disaster 
Resilience. Data-sorting was aided by Yusuke Yamane. 
Yasuhiro Fukushima helped us evaluate the hypocentral 
distances. 

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