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TORNADO FAQs

A wall cloud is not always present. It is possible, though, that you cannot see a wall cloud because of your viewing angle.

People who have been in a tornado say it sounds like a jet engine or a freight train and is very loud. They said it hurt their ears but they were more worried about what might happen to them than they were about the pain in their ears.

Today, the development of Doppler radar has made it possible, under certain circumstances, to detect a tornado's winds with a radar. However, human beings remain an important part of the system to detect tornadoes, because not all tornadoes occur in situations where the radar can "see" them. Ordinary citizen volunteers make up what is called the SKYWARN network of storm spotters, who work with their local communities to watch for approaching tornadoes, so those communities can take appropriate action in the event of a tornado. Spotter information is relayed to the National Weather Service, which operates the national Doppler radar network and which issues warnings to the public by radio, TV, and NOAA Weather Radio, using information obtained from weather maps, weather radars, and local storm spotters.

You may have read about a technique called "the Weller Method" of tornado detection. The idea was to be able to use your TV as a lightning detector to detect the radio waves emitted by a lightning flash, with the assumption that tornadic thunderstorms were very active lightning producers. But, not all tornadic storms produce large amounts of lightning. And, TV's are all different and have different sensitivities, and some are even made to filter out lightning signals. Plus, if you are connected to cable, it won't work. The method was found to be completely unreliable and it has mostly been abandoned.

Visit SKYWARN, a cooperative effort between the National Weather Service and communities to organize spotters. On that site there is a link to local SKYWARN groups. If your area is not listed, contact your local National Weather Service Office.

We receive literally hundreds of ideas for observing, controlling, or stopping destructive storms. Our scientists are likely to look at ideas that are investigated by a researcher who publishes the results in a peer-reviewed journal. In this way they can review, and if necessary, replicate the results, which then will suggest the next step to move the science forward.

Detecting Tornadoes

What does a tornadic storm look like?

Forecasters and storm spotters have learned to recognize certain thunderstorm features and structure that make tornado formation more likely. Some of these are visual cues, like the rear-flank downdraft, and others are particular patterns in radar images, like the tornadic vortex signature (TVS).

A supercell storm viewed from above, showing the position of the fronts, the inflow bands, and the tornado
larger image

VISUAL EVIDENCE

The most reliable evidence of a tornado is for someone who has been trained to recognize tornadoes to actually see one. Storm spotters report what they see to the National Weather Service and provide important information to warning forecasters who must make critical warning decisions. Storm spotters can be emergency managers or even local people with a keen interest in severe weather who have undergone formal storm spotter training in their community. Some of the features storm spotters and forecasters look for in tornadic storms include:

RADAR EVIDENCE

A tornadic storm observed by radar also has certain distinguishing features. Computer programs, called algorithms, analyze Doppler radar data and display it in ways that make it easier to identify dangerous weather. Forecasters are trained to recognize the precise radar signatures produced automatically by these sophisticated computer applications. Today's weather radars typically provide on average 11 minutes lead-time, and can pinpoint locations directly in harm's way with a high degree of accuracy. Some of the radar features forecasters look for Include:

» More About RADAR EVIDENCE  

The next generation of weather radars is now being developed. Scientists are adapting phased array technology, currently used on Navy ships, for use in weather forecasting. Phased array technology is expected to lengthen the average lead time for tornado warnings from 12 minutes to 20 minutes.

Other computer programs, like the Advanced Weather Interactive Processing System (AWIPS) used in all forecast offices, identify different kinds of severe weather, including tornadoes, using the latest observational data from Doppler radars, surface and upper air observing systems, mesoscale numerical models, satellites, and the National Lightning Detection Network. These computer applications incorporate image recognition, artificial intelligence, data mining, and statistical methods and couple them with state-of-the-art display platforms.

HOW DOES NSSL CONTRIBUTE?

Radar Development
NSSL built the first real-time displays of Doppler velocity data. This lead to an NSSL scientist's discovery of the Tornadic Vortex Signature in radar velocity data in the 1970's. These developments helped spur deployment of the WSR-88D NEXRAD radar network. The Department of Commerce recognized NSSL's contribution to the NEXRAD program and to our Nation by awarding a Gold Medal to NSSL.

NSSL made the first observations of a tornadic storm with two Doppler radars (called dual-Doppler). The radars were located about 40 miles from each other and were able to record data on the same storm but from two different perspectives. The data was used to map the structure of a tornadic storm at several altitudes.

Airborne Doppler
NSSL continues to refine the use of airborne Doppler radar (installed on NOAA's P-3 research aircraft) to study storms. The first direct measurements of a tornado recorded with an airborne Doppler radar were made by NSSL. New concepts of making dual-Doppler measurements using the WSR-88D with the airborne Doppler were first tested in 1989 and are now used routinely.

Mobile Doppler Radars
NSSL collaborated with the University of Oklahoma, Texas Tech and Texas A&M University to build the Shared Mobile Atmospheric Research and Teaching-Radars, two 5-cm wavelength mobile Doppler radars than can scan and penetrate through an entire tornado or hurricane. The SMART-Radars will be used to study convective and mesoscale atmospheric processes to help improve forecasts of significant weather events.

Dual-polarization
Engineers at NSSL developed polarimetric technology for the NEXRAD Doppler radar network. A polarized radar has the ability to measure reflected power returned to the radar from both horizontal and vertical pulses. Scientists recently discovered polarimetric signatures aloft that might be related to a developing tornado.

WDSS-II
NSSL's second generation Warning Decision Support System, WDSS-II, is an advanced algorithm development and visualization platform that accepts data from multiple sources and organizes it in ways that convey critical severe weather information to warning meteorologists.

NSSL developed the Tornado Detection Algorithm now used by the National Weather Service in their forecasting operations.

Phased Array
The National Weather Radar Testbed at NSSL, constructed in 2003, is where the next generation of weather radars is being developed. NSSL engineers and scientists are adapting phased array technology, currently used on Navy ships, for use in weather forecasting. Phased array technology is expected to lengthen the average lead time for tornado warnings from 11 minutes to 20 minutes.

OK-WARN
The Oklahoma Weather Alert Remote Notification program provides deaf and hard-of-hearing Oklahoman's access to emergency severe weather information via alphanumeric pagers and/or E-mail addresses. NSSL scientist Vincent Wood received the Department of Commerce Gold Medal award for his part in developing this hazardous weather pager program.

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