VI. CONCLUSIONS
Mining explosions detonated at or near the earth's surface provide a source of
events that will have to be identified during the monitoring of a CTBT. In an
attempt to understand the seismic waveforms generated by these sources, a
series of techniques that combine multiple data sets and models of the blasting
practices have been developed. These same tools may be useful to the
blasting community as diagnostics of blasting practices.
Ground motion records, video, timing and spatial data have been used to
constrain critical physical processes in the blasts. The first step in the
synergy
of these different data sets and combination with models of the processes for
interpretation is conversion of all data sets to digital form. A series of
processing steps have been developed for converting standard Hi-8 video to
digital form. Important in this process is consideration of the large size of
the
resulting data sets, development of maximum time resolution, and removal of
artifacts of the explosive environment such as the ground motion effects on the
camera. De-interlacing of the video data after digitization provides 16.67 ms
resolution of near surface source processes with standard Hi-8 video hardware.
Combined images that include video, ground motion and models representing
timing information from the source provide the opportunity for improved
interpretation of the blasting process and its effect on the ground motion. The
video and the models allow inclusion of two and three dimensional spatial
effects in the interpretation. The time varying nature of the problem is
replicated
by creating movies of these visualizations .
Examples displayed in this paper demonstrate a new technique for data
interpretation as well as provide constraints on the seismic source functions
from mining explosions. Data from the explosive array indicate that, as a
result
of downhole delays, significant differences between design and measured
detonation times can occur. In cases where all explosions in a single row are
detonated with the same delay as in the Russian example (Figure 10 and 11),
this variation may not destroy the constructive and destructive interference
introduced by the energy from each row of explosions. In cases where each
hole in the blast is detonated at a different time (Figure 15 and 16), the
variance
in the detonation times can result in important degradation in the spectral
scalloping that might be used to identify such sources. Even in the case where
the scatter results in quite different individual detonation times, the total
duration of source processes remains relatively unchanged and thus spectral
interference representative of the total duration of the explosive array may
still
provide a useful discriminant for this event type.
Comparison of the videos of the explosive processes with ground motion
records indicates that within the bandwidth of the observations (2 Hz
seismometers) that secondary source processes, such as material cast or
spalled, have little contribution to near-source waveforms. The correlation in
time of the video and ground motion records supports this conclusion.
The time varying aspects of this problem, coupled with digital data quantifying
this aspect of the phenomenology, has motivated this exploration of new
techniques in data display and comparison to models. The World Wide Web
make possible easy dissemination of these interpretative products in
conjunction with a standard journal article.
ACKNOWLEDGMENTS
This work was made possible by the Department of Energy and the CTBT
Research and Development Program at Los Alamos National Laboratory. Initial
support for the video image processing was provided by AFOSR under Grant
F49620-93-1-0146 at SMU. John Smith, John Wiggins and R. Frank
Chiappetta are thanked for their support in the field. D. Craig Pearson,
Meredith
Ness and Ben Smith were responsible for the data acquisition. Xiaoning Yang
helped with preparation of some of the ground motion data.
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