8/18/2023 0 Comments Weather doppler radar in motionBased on those field observations and research into other storm events since then, computer programs (algorithms) to detect harmful features in storms were developed - and continue to be developed and modified today. In 1989, organized intercept teams went out into severe storms to verify the indications of a prototype NEXRAD radar in Norman. In the 1980s, the push to get Doppler radars into warning operations became well-organized as the NEXRAD (NEXt generation weather RADar) program. The Union City tornado in 1973 began a treasure trove of NSSL research Doppler measurements of supercells and other hazardous storms. Here, the mesocyclone and tornado in northern Moore are represented by progressively brighter greens (toward the radar) and reds (away from the radar).ĭoppler radar and severe storms research were joined in the early 1960s when the National Severe Storms Project began in Kansas City, and continue to this day at the National Severe Storms Laboratory ( NSSL) in Norman, Oklahoma. To make a storm-relative velocity image, the radar system's computer programs take away thunderstorm movement to give a truer look at the motions inside the storm. The debris, which reflects radar energy much stronger than rain does, caused the brightest white blocks of reflectivity within the hook echo. This large, violent and extremely destructive tornado was hurling many tons of debris high into the air as it approached I-35. In the dual image at left, the radar was unusually close to an F5 tornado in northern Moore, Oklahoma - close enough to make out signatures of the tornado itself. The farther away from the radar a storm is, the more coarse the view, because: 1) The radar beam spreads out with distance, like a flashlight beam, causing small features to be missed at a distance and 2) The beam shoots straight as the earth curves away from beneath - a horizon that forces the radar to miss more and more of the low and middle levels of a storm with distance. From a volume scan (a series of 360-degree sweeps, each tilting a little higher than the last), forecasters can get a detailed look at structures and movements in storms close to the radar. In other words, it can measure how fast rain or hail is moving toward or away from the radar. See for a more extensive discussion.Doppler radar can see not only the precipitation in a thunderstorm (through its ability to reflect microwave energy, or reflectivity), but motion of the precipitation along the radar beam. Weather radars can also pick up returns from nearby objects on the ground (ground clutter) and flying insects. So, rain will occur in some places (such as the western side of the Olympic Mountains) without it showing up on our loop. The beam can be blocked by mountains, and some areas are simply too far away from any radar. The coverage of the Pacific Northwest by weather radar is by no means uniform. Our loop shows the signals recorded by several radars in the northwest over the last several hours. High values of dbz (color scale to the right of the image) indicate large drops and heavy precipitation. Raindrops and snow produce reflections that become stronger as the size of the drop or flake increases. Weather radars send out pulses of microwave energy and listen between the transmitted pulses for part of that the energy to be reflected back to the radar.
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