TY - JOUR
T1 - Lightning Mapping and Leader Propagation Reconstruction using LOFAR-LIM
AU - Hare, B.
AU - Ebert, U.
AU - Rutjes, C.
AU - Scholten, O.
AU - Trinh, G. T. N.
PY - 2017/12/1
Y1 - 2017/12/1
N2 - LOFAR (LOw Frequency ARray) is a radio telescope that consists of a
large number of dual-polarized antennas spread over the northern
Netherlands and beyond. The LOFAR for Lightning Imaging project
(LOFAR-LIM) has successfully used LOFAR to map out lightning in the
Netherlands. Since LOFAR covers a large frequency range (10-90 MHz), has
antennas spread over a large area, and saves the raw trace data from the
antennas, LOFAR-LIM can combine all the strongest aspects of both
lightning mapping arrays and lightning interferometers. These aspects
include a nanosecond resolution between pulses, nanosecond timing
accuracy, and an ability to map lightning in all 3 spatial dimensions
and time. LOFAR should be able to map out overhead lightning with a
spatial accuracy on the order of meters. The large amount of complex
data provide by LOFAR has presented new data processing challenges, such
as handling the time offsets between stations with large baselines and
locating as many sources as possible. New algorithms to handle these
challenges have been developed and will be discussed. Since the antennas
are dual-polarized, all three components of the electric field can be
extracted and the structure of the R.F. pulses can be investigated at a
large number of distances and angles relative to the lightning source,
potentially allowing for modeling of lightning current distributions
relevant to the 10 to 90 MHz frequency range. R.F. pulses due to leader
propagation will be presented, which show a complex sub-structure,
indicating intricate physics that could potentially be reconstructed.
AB - LOFAR (LOw Frequency ARray) is a radio telescope that consists of a
large number of dual-polarized antennas spread over the northern
Netherlands and beyond. The LOFAR for Lightning Imaging project
(LOFAR-LIM) has successfully used LOFAR to map out lightning in the
Netherlands. Since LOFAR covers a large frequency range (10-90 MHz), has
antennas spread over a large area, and saves the raw trace data from the
antennas, LOFAR-LIM can combine all the strongest aspects of both
lightning mapping arrays and lightning interferometers. These aspects
include a nanosecond resolution between pulses, nanosecond timing
accuracy, and an ability to map lightning in all 3 spatial dimensions
and time. LOFAR should be able to map out overhead lightning with a
spatial accuracy on the order of meters. The large amount of complex
data provide by LOFAR has presented new data processing challenges, such
as handling the time offsets between stations with large baselines and
locating as many sources as possible. New algorithms to handle these
challenges have been developed and will be discussed. Since the antennas
are dual-polarized, all three components of the electric field can be
extracted and the structure of the R.F. pulses can be investigated at a
large number of distances and angles relative to the lightning source,
potentially allowing for modeling of lightning current distributions
relevant to the 10 to 90 MHz frequency range. R.F. pulses due to leader
propagation will be presented, which show a complex sub-structure,
indicating intricate physics that could potentially be reconstructed.
KW - 3304 Atmospheric electricity
KW - ATMOSPHERIC PROCESSES
KW - 3324 Lightning
KW - 3360 Remote sensing
KW - 3394 Instruments and techniques
M3 - Meeting Abstract
VL - 22
JO - American Geophysical Union, Fall Meeting
JF - American Geophysical Union, Fall Meeting
M1 - AE22A-06
ER -