Earth:Fujita scale: Difference between revisions

From HandWiki
(correction)
 
(url)
 
Line 1: Line 1:
{{Short description|Scale for rating tornado intensity}}
{{Short description|Scale for rating tornado intensity}}
{{Redirect2|F2 tornado|F3 tornado|the military aircraft|Panavia Tornado ADV|the EF scale|Enhanced Fujita scale|the IF-scale|International Fujita scale}}
{{Use mdy dates|date=July 2024}}
{{Fujita small}}


The '''Fujita scale''' ('''F-Scale'''; {{IPAc-en|f|u|ˈ|dʒ|iː|t|ə}}), or '''Fujita–Pearson scale''' ('''FPP scale'''), is a scale for rating [[Earth:Tornado intensity|tornado intensity]], based primarily on the damage tornadoes inflict on human-built structures and vegetation. The official Fujita scale category is determined by [[Meteorologist|meteorologist]]s and [[Engineering:Civil engineer|engineers]] after a ground or [[Social:Aerial survey|aerial damage survey]], or both; and depending on the circumstances, ground-swirl patterns ([[Cycloid|cycloid]]al marks), [[Earth:Weather radar|weather radar]] data, witness testimonies, media reports and damage imagery, as well as [[Earth:Photogrammetry|photogrammetry]] or [[Videogrammetry|videogrammetry]] if motion picture recording is available. The Fujita scale was replaced with the [[Earth:Enhanced Fujita scale|Enhanced Fujita scale]] (EF-Scale) in the {{wipe|United States}} in February 2007. In April 2013, {{wipe|Canada}} adopted the EF-Scale over the Fujita scale along with 31 "Specific Damage Indicators" used by Environment Canada (EC) in their ratings.<ref name="NOAA: Fujita Tornado Damage Scale">{{cite web|url=http://www.spc.noaa.gov/faq/tornado/f-scale.html |title=Fujita Tornado Damage Scale|website=spc.noaa.gov|access-date=May 27, 2017}}</ref><ref name="FJFK: Fujita Scale - Tornado Damage Scale">{{cite web|url=https://www.factsjustforkids.com/weather-facts/tornado-facts-for-kids/fujita-scale.html |title=Fujita Scale – Tornado Damage Scale|website=factsjustforkids.com|access-date=June 14, 2019}}</ref>
The '''Fujita scale''' ('''F-Scale'''; {{IPAc-en|f|u|ˈ|dʒ|iː|t|ə}}), or '''Fujita–Pearson scale''' ('''FPP scale'''), is a scale for rating [[Earth:Tornado intensity|tornado intensity]], based primarily on the damage tornadoes inflict on human-built structures and vegetation. The official Fujita scale category is determined by [[Meteorologist|meteorologist]]s and [[Engineering:Civil engineer|engineers]] after a ground or [[Social:Aerial survey|aerial damage survey]], or both; and depending on the circumstances, ground-swirl patterns ([[Cycloid|cycloid]]al marks), [[Earth:Weather radar|weather radar]] data, witness testimonies, media reports and damage imagery, as well as [[Earth:Photogrammetry|photogrammetry]] or [[Videogrammetry|videogrammetry]] if motion picture recording is available. The Fujita scale, named for the meteorologist Ted Fujita, was replaced with the [[Earth:Enhanced Fujita scale|Enhanced Fujita scale]] (EF-Scale) in the [[United States]] in February 2007. In April 2013, Canada adopted the EF-Scale over the Fujita scale along with 31 "Specific Damage Indicators" used by Environment Canada (EC) in their ratings.<ref name="NOAA: Fujita Tornado Damage Scale">{{cite web|url=http://www.spc.noaa.gov/faq/tornado/f-scale.html |title=Fujita Tornado Damage Scale|website=spc.noaa.gov|access-date=May 27, 2017}}</ref><ref name="FJFK: Fujita Scale - Tornado Damage Scale">{{cite web|url=https://www.factsjustforkids.com/weather-facts/tornado-facts-for-kids/fujita-scale.html |title=Fujita Scale – Tornado Damage Scale|website=factsjustforkids.com|access-date=June 14, 2019}}</ref>


== Background ==
== Background ==
The scale was introduced in 1971 by Ted Fujita of the [[Organization:University of Chicago|University of Chicago]], in collaboration with Allen Pearson, head of the National Severe Storms Forecast Center/NSSFC (currently the [[Earth:Storm Prediction Center|Storm Prediction Center]]/SPC). The scale was updated in 1973, taking into account path length and width. In the United States, starting in the late 1970s,<ref>{{Cite journal |last1=Edwards |first1=Roger |last2=LaDue |first2=James G. |last3=Ferree |first3=John T. |last4=Scharfenberg |first4=Kevin |last5=Maier |first5=Chris |last6=Coulbourne |first6=William L. |date=2013-05-01 |title=Tornado Intensity Estimation: Past, Present, and Future |url=https://www.spc.noaa.gov/publications/edwards/ef-scale.pdf |journal=Bulletin of the American Meteorological Society |language=en |volume=94 |issue=5 |pages=641–653 |doi=10.1175/BAMS-D-11-00006.1 |bibcode=2013BAMS...94..641E |s2cid=7842905 |issn=1520-0477}}</ref> tornadoes were rated soon after occurrence. The Fujita scale was applied retroactively to tornadoes reported between 1950 and the adoption of the scale in the [[Organization:National Oceanic and Atmospheric Administration|National Oceanic and Atmospheric Administration (NOAA)]] National Tornado Database. Fujita rated tornadoes from 1916 to 1992<ref>{{cite journal|title=American Meteorological Society |journal=Bulletin of the American Meteorological Society |volume=82 |pages=63–72 |doi=10.1175/1520-0477(2001)000<0063:TTFHCT>2.3.CO;2 |year = 2001|last1 = McDonald|first1 = James R.|issue=1 |doi-access=free |bibcode=2001BAMS...82...63M }}</ref><ref>{{cite web |url=https://www.spc.noaa.gov/publications/mccarthy/f-scale.pdf |title=NWS Tornado Surveys and the Impact on the National Tornado|last= McCarthy|first=Daniel |website=www.spc.noaa.gov }}</ref> and Tom Grazulis of The Tornado Project retroactively rated all known significant tornadoes (F2–F5 or causing a fatality) in the U.S. back to 1880.<ref name="significant tornadoes"/>
The scale was introduced in 1971 by Ted Fujita of the [[Organization:University of Chicago|University of Chicago]], in collaboration with Allen Pearson, head of the National Severe Storms Forecast Center/NSSFC (currently the [[Earth:Storm Prediction Center|Storm Prediction Center]]/SPC). The scale was updated in 1973, taking into account path length and width. In the United States, starting in the late 1970s,<ref>{{Cite journal |last1=Edwards |first1=Roger |last2=LaDue |first2=James G. |last3=Ferree |first3=John T. |last4=Scharfenberg |first4=Kevin |last5=Maier |first5=Chris |last6=Coulbourne |first6=William L. |date=2013-05-01 |title=Tornado Intensity Estimation: Past, Present, and Future |url=https://www.spc.noaa.gov/publications/edwards/ef-scale.pdf |journal=Bulletin of the American Meteorological Society |language=en |volume=94 |issue=5 |pages=641–653 |doi=10.1175/BAMS-D-11-00006.1 |bibcode=2013BAMS...94..641E |s2cid=7842905 |issn=1520-0477}}</ref> tornadoes were rated soon after occurrence. The Fujita scale was applied retroactively to tornadoes reported between 1950 and the adoption of the scale in the [[Organization:National Oceanic and Atmospheric Administration|National Oceanic and Atmospheric Administration (NOAA)]] National Tornado Database. Fujita rated tornadoes from 1916 to 1992<ref>{{cite journal|title=American Meteorological Society |journal=Bulletin of the American Meteorological Society |volume=82 |pages=63–72 |doi=10.1175/1520-0477(2001)000<0063:TTFHCT>2.3.CO;2 |year = 2001|last1 = McDonald|first1 = James R.|issue=1 |doi-access=free |bibcode=2001BAMS...82...63M }}</ref><ref>{{cite web |url=https://www.spc.noaa.gov/publications/mccarthy/f-scale.pdf |title=NWS Tornado Surveys and the Impact on the National Tornado|last= McCarthy|first=Daniel |website=www.spc.noaa.gov }}</ref> and Tom Grazulis of The Tornado Project retroactively rated all known significant tornadoes (F2–F5 or causing a fatality) in the U.S. back to 1880.<ref name="significant tornadoes"/>
The Fujita scale was adopted in most areas outside of the {{wipe|United Kingdom}}.{{citation needed|date=April 2012}}


On February 1, 2007, the Fujita scale was decommissioned, and the Enhanced Fujita Scale was introduced in the United States.<ref name="SPC"/> The new scale more accurately matches wind speeds to the severity of damage caused by the tornado.{{cn|date=May 2023}}
On February 1, 2007, the Fujita scale was decommissioned, and the [[Earth:Enhanced Fujita scale|Enhanced Fujita Scale]] was introduced in the United States.<ref name="SPC"/> The new scale more accurately matches wind speeds to the severity of damage caused by the tornado.<ref>{{Cite web |last=Center |first=Storm Prediction |title=NOAA's NWS Storm Prediction Center |url=https://www.spc.noaa.gov/efscale/ |access-date=2024-12-20 |website=www.spc.noaa.gov |language=EN-US}}</ref>


Though each damage level is associated with a wind speed, the Fujita scale is effectively a damage scale, and the wind speeds associated with the damage listed are not rigorously verified. The Enhanced Fujita Scale was formulated due to research that suggested that the wind speeds required to inflict damage by intense tornadoes on the Fujita scale are greatly overestimated. A process of [[Expert elicitation|expert elicitation]] with top engineers and meteorologists resulted in the EF scale wind speeds, but these are biased to United States construction practices. The EF scale also improved damage parameter descriptions.{{cn|date=May 2023}}
Though each damage level is associated with a wind speed, the Fujita scale is effectively a damage scale, and the wind speeds associated with the damage listed are not rigorously verified. The Enhanced Fujita Scale was formulated due to research that suggested that the wind speeds required to inflict damage by intense tornadoes on the Fujita scale are greatly overestimated. A process of [[Expert elicitation|expert elicitation]] with top engineers and meteorologists resulted in the EF scale wind speeds, but these are biased to United States construction practices. The EF scale also improved damage parameter descriptions.{{cn|date=May 2023}}
Line 14: Line 16:
[[File:Fujita scale technical.svg|thumb|right|200px|A diagram illustrating the relationship between the Beaufort, Fujita, and Mach number scales.]]
[[File:Fujita scale technical.svg|thumb|right|200px|A diagram illustrating the relationship between the Beaufort, Fujita, and Mach number scales.]]


The original scale as derived by Fujita was a theoretical 13-level scale (F0–F12) designed to smoothly connect the Beaufort scale and the [[Physics:Mach number|Mach number]] scale. F1 corresponds to the twelfth level of the Beaufort scale, and F12 corresponds to Mach number 1.0. F0 was placed at a position specifying no damage (approximately the eighth level of the Beaufort scale), in analogy to how Beaufort's zeroth level specifies little to no wind. From these wind speed numbers, qualitative descriptions of damage were made for each category of the Fujita scale, and then these descriptions were used to classify tornadoes.<ref name="enhancedIntro">{{cite web|url=http://www.spc.noaa.gov/efscale/ |title=Storm Prediction Center|website=spc.noaa.gov|access-date=May 27, 2017}}</ref>  
The original scale as derived by Fujita was a theoretical 13-level scale (F0–F12) designed to smoothly connect the Beaufort scale and the [[Physics:Mach number|Mach number]] scale. F1 corresponds to the twelfth level of the Beaufort scale, and F12 corresponds to Mach number 1.0. F0 was placed at a position specifying no damage (approximately the eighth level of the Beaufort scale), in analogy to how Beaufort's zeroth level specifies little to no wind. From these wind speed numbers, qualitative descriptions of damage were made for each category of the Fujita scale, and then these descriptions were used to classify tornadoes.<ref name="enhancedIntro">{{cite web|url=http://www.spc.noaa.gov/efscale/ |title=Storm Prediction Center|website=spc.noaa.gov|access-date=May 27, 2017}}</ref>


At the time Fujita derived the scale, little information was available on damage caused by wind, so the original scale presented little more than educated guesses at [[Physics:Wind speed|wind speed]] ranges for specific tiers of damage. Fujita intended that only F0–F5 be used in practice, as this covered all possible levels of damage to frame homes as well as the expected estimated bounds of wind speeds. He did, however, add a description for F6, which he called an "inconceivable tornado", to allow for wind speeds exceeding F5 and possible advancements in damage analysis that might show it.<ref name="SPC FAQ"/> In total, two tornadoes received the rating of F6, but both were later downgraded to F5.<ref>{{cite web |last1=Anna |first1=Carly |title=Explaining the 'Inconceivable F6' Tornado |url=https://www.youtube.com/watch?v=Eaok5-sg3Vw |website=[[Company:YouTube|YouTube]] |publisher=@CarlyAnnaWx |access-date=26 October 2023 |archive-url=https://web.archive.org/web/20231026155205/https://www.youtube.com/watch?v=Eaok5-sg3Vw |archive-date=26 October 2023 |format=[[Engineering:Video|Video]] |date=26 October 2023 |url-status=live}}</ref>
=== F6 rating ===


Based on aerial photographs of the damage it caused, Fujita assigned the strongest tornado of the 1974 Super Outbreak, which affected Xenia, Ohio, a preliminary rating of F6 intensity ± 1 scale.<ref>{{cite web|url = https://www.weather.gov/media/ohx/PDF/fujita_april31974.pdf|last = Fujita| first = T. Theodore|title = Jumbo Tornado Outbreak of 3 April 1974|year = 1974}}</ref>  The 1977 Birmingham–Smithfield F5 tornado's damage was surveyed by Ted Fujita and he “toyed with the idea of rating the Smithfield tornado an F6.<ref>{{cite web |title=April 4, 1977, Smithfield F5 Tornado |url=https://www.weather.gov/bmx/event_04041977 |publisher=[[Earth:National Weather Service|National Weather Service]] |access-date=8 April 2022}}</ref> In 2001, tornado expert Thomas P. Grazulis stated in his book ''F5–F6 Tornadoes''; "In my opinion, if there ever was an F6 tornado caught on video, it was the Pampa, Texas tornado of 1995".<ref>{{cite book |author1=Thomas P. Grazulis |title=F5-F6 Tornadoes |date=2021 |publisher=The Tornado Project}}</ref> In 2023, it was announced by the [[Earth:Storm Prediction Center|Storm Prediction Center]] and National Weather Service Norman, Oklahoma that the 1970 Lubbock tornado was originally rated F6, which was later downgraded to its official rating of F5.<ref>{{cite journal |author1=Roger Edwards (SPC) |author2=Matthew S. Elliott (SPC) |author3=Patrick T. Marsh (SPC |author4=Douglas A. Speheger (NWS) |title=Errors, Oddities and Artifacts in U.S. Tornado Data, 1995–2021 |journal=Storm Prediction Center Publications |pages=1–10 |url=https://www.spc.noaa.gov/publications/edwards/oddities.pdf |access-date=11 January 2023}}</ref>
At the time Fujita derived the scale, little information was available on damage caused by wind, so the original scale presented little more than educated guesses at [[Physics:Wind speed|wind speed]] ranges for specific tiers of damage. Fujita intended that only F0–F5 be used in practice, as this covered all possible levels of damage to frame homes as well as the expected estimated bounds of wind speeds. He did, however, add a description for F6, which he called an "inconceivable tornado", to allow for wind speeds exceeding F5 and possible advancements in damage analysis that might show it.<ref name="SPC FAQ"/>
 
Based on aerial photographs of the damage it caused, Fujita assigned the strongest tornado of the 1974 Super Outbreak, which affected Xenia, Ohio, a preliminary rating of F6 intensity ± 1 scale.<ref>{{cite web|url = https://www.weather.gov/media/ohx/PDF/fujita_april31974.pdf|last = Fujita| first = T. Theodore|title = Jumbo Tornado Outbreak of 3 April 1974|year = 1974}}</ref>  The 1977 Birmingham–Smithfield F5 tornado's damage was surveyed by Ted Fujita and he "toyed with the idea of rating the Smithfield tornado an F6".<ref>{{cite web |title=April 4, 1977, Smithfield F5 Tornado |url=https://www.weather.gov/bmx/event_04041977 |publisher=[[Earth:National Weather Service|National Weather Service]] |access-date=8 April 2022}}</ref> In 2001, tornado expert Thomas P. Grazulis stated in his book ''F5–F6 Tornadoes''; "In my opinion, if there ever was an F6 tornado caught on video, it was the Pampa, Texas tornado of 1995".<ref>{{cite book |author1=Thomas P. Grazulis |title=F5-F6 Tornadoes |date=2021 |publisher=The Tornado Project}}</ref> In 2023, it was announced by the [[Earth:Storm Prediction Center|Storm Prediction Center]] and National Weather Service Norman, Oklahoma that the 1970 Lubbock tornado was originally rated F6, which was later downgraded to its official rating of F5.<ref>{{cite journal |author1=Roger Edwards (SPC) |author2=Matthew S. Elliott (SPC) |author3=Patrick T. Marsh (SPC |author4=Douglas A. Speheger (NWS) |title=Errors, Oddities and Artifacts in U.S. Tornado Data, 1995–2021 |journal=Storm Prediction Center Publications |pages=1–10 |url=https://www.spc.noaa.gov/publications/edwards/oddities.pdf |access-date=11 January 2023}}</ref>
 
Furthermore, the original wind speed numbers have since been found to be higher than the actual speeds required to incur the damage described at each category. The error manifests itself to an increasing degree as the category increases, especially in the range of F3 through F5. NOAA notes that "precise wind speed numbers are actually guesses and have never been scientifically verified. Different wind speeds may cause similar-looking damage from place to place—even from building to building. Without a thorough engineering analysis of tornado damage in any event, the actual wind speeds needed to cause that damage are unknown."<ref name="SPC FAQ">[http://www.spc.noaa.gov/faq/tornado/ Tornado FAQ]. [http://www.spc.noaa.gov Storm Prediction Center]. Site accessed June 27, 2006.</ref>
 
The Tornado Project, headed by tornado expert Thomas P. Grazulis, states in reference to the F6 rating, <q>[i]f this level is ever achieved, evidence for it might only be found in some manner of ground swirl pattern, for it may never be identifiable through engineering studies</q>.<ref>{{cite web |url=https://www.tornadoproject.com/cellar/fscale.htm |title=The Fujita Scale |website=The Tornado Project |location=St. Johnsbury, Vermont |date=2015 }}</ref>


Furthermore, the original wind speed numbers have since been found to be higher than the actual speeds required to incur the damage described at each category. The error manifests itself to an increasing degree as the category increases, especially in the range of F3 through F5. NOAA notes that "precise wind speed numbers are actually guesses and have never been scientifically verified. Different wind speeds may cause similar-looking damage from place to place—even from building to building. Without a thorough engineering analysis of tornado damage in any event, the actual wind speeds needed to cause that damage are unknown."<ref name="SPC FAQ">[http://www.spc.noaa.gov/faq/tornado/ Tornado FAQ]. [http://www.spc.noaa.gov Storm Prediction Center]. Site accessed June 27, 2006.</ref> Since then, the Enhanced Fujita Scale has been created using better wind estimates by engineers and meteorologists.
{{clear}}
{{clear}}


== Parameters ==
== Parameters ==
The six categories are listed here, in order of increasing intensity.{{cn|date=May 2023}}
The six categories are listed here, in order of increasing intensity.
* The rating of any given tornado is of the most severe damage to any well-built frame home or comparable level of damage from engineering analysis of other damage.
* The rating of any given tornado is of the most severe damage to any well-built frame home or comparable level of damage from engineering analysis of other damage.
* Since the Fujita scale is based on the severity of damage resulting from high winds, a tornado exceeding F5 is an immeasurable theoretical construct. Frame-home structural damage cannot exceed total destruction and debris dispersal, which constitutes F5 damage. A tornado with wind speeds greater than {{convert|319|mph}} is theoretically possible, and the 1999 Bridge Creek-Moore Tornado may have been such an event, but no such wind speed has ever been recorded and that measurement was not near ground level.
* Since the Fujita scale is based on the severity of damage resulting from high winds, a tornado exceeding F5 is an immeasurable theoretical construct. Frame-home structural damage cannot exceed total destruction and debris dispersal, which constitutes F5 damage. Tornadoes with wind speeds over {{cvt|319|mph|km/h}} are possible and such extreme gusts have been determined using mobile radar observation, but no tornado has received an official damage-based F6 rating.


{| class="wikitable"
{| class="wikitable"
Line 40: Line 47:
| align="center" bgcolor="#{{storm color|storm}}" | <big>'''F0'''</big> {{Anchor|F0}}
| align="center" bgcolor="#{{storm color|storm}}" | <big>'''F0'''</big> {{Anchor|F0}}
| style="text-align:center;"| 40–72 ||  style="text-align:center;"| 64–116 || style="text-align:center;"| 44.14%
| style="text-align:center;"| 40–72 ||  style="text-align:center;"| 64–116 || style="text-align:center;"| 44.14%
| Light damage.{{pb}}Small trees are blown down and bushes are uprooted. Shingles are ripped off roofs, windows in cars and buildings are blown out, medium to large branches snapped off of large trees, sheds are severely damaged, and loose small items are tossed and blown away (i.e. lawn chairs, plastic tables, sports equipment, mattresses). Barns are damaged. Paper and leaves lifted off the ground.
| Light damage.{{pb}}Well-built structures are typically unscathed, though sometimes sustaining broken windows, with minor damage to roofs and chimneys. Billboards and large signs can be knocked down. Trees may have large branches broken off and can be uprooted if they have shallow roots.
|| [[File:F0 tornado damage example.jpg|150px|This house only sustained minor loss of shingles. Though well-built structures are typically unscathed by F0 tornadoes, falling trees, and tree branches can injure and kill people, even inside a sturdy structure.]]
|| [[File:FEMA - 40806 - Workers cleaning a damagaed roof in Arkansas.jpg|200px|Well-built structures are typically unscathed, though sometimes sustaining broken windows, with minor damage to roofs and chimneys. Billboards and large signs can be knocked down. Trees may have large branches broken off and can be uprooted if they have shallow roots.]]
|-
|-
| align="center" bgcolor="#{{storm color|cat1}}" | <big>'''F1'''</big> {{Anchor|F1}}
| align="center" bgcolor="#{{storm color|cat1}}" | <big>'''F1'''</big> {{Anchor|F1}}
| style="text-align:center;"| 73–112 || style="text-align:center;"| 117–180 || style="text-align:center;"| 34.24%
| style="text-align:center;"| 73–112 || style="text-align:center;"| 117–180 || style="text-align:center;"| 34.24%
| Moderate damage.{{pb}}Roofs stripped from shingles or planting. Small areas of the roof may be blown off the house. Doors and garage doors blown in, siding ripped off houses, mobile homes flipped or rolled onto their sides, small trees uprooted, large trees snapped or blown down, telephone poles snapped, outhouses and sheds blown away. Cars occasionally flipped or blown over, and moderate roof and side damage to barns. Corn stalks are slightly bent and stripped of leaves.
| Moderate damage.{{pb}}Damage to mobile homes and other temporary structures becomes significant, and cars and other vehicles can be pushed off the road or flipped. Permanent structures can suffer major damage to their roofs.
|| [[File:F1 tornado damage example.jpg|150px|F1 tornadoes cause major damage to mobile homes and automobiles and can cause minor structural damage to well-constructed homes. This frame home sustained major roof damage, but otherwise remained intact.]]
|| [[File:FEMA - 28916 - Photograph by Mark Wolfe taken on 03-08-2007 in Georgia.jpg|200px|There is damage to mobile homes and other temporary structures becomes significant, and cars and other vehicles can be pushed off the road or flipped. Permanent structures can suffer major damage to their roofs.]]
|-
|-
| align="center" bgcolor="#{{storm color|cat2}}" | <big>'''F2'''</big> {{Anchor|F2}}
| align="center" bgcolor="#{{storm color|cat2}}" | <big>'''F2'''</big> {{Anchor|F2}}
| style="text-align:center;"| 113–157 || style="text-align:center;"| 181–253 || style="text-align:center;"| 16.17%
| style="text-align:center;"| 113–157 || style="text-align:center;"| 181–253 || style="text-align:center;"| 16.17%
| Significant damage.{{pb}}Whole roofs ripped off frame houses, interiors of frame homes damaged, small and medium trees uprooted. Weak structures such as garages, barns, and mobile homes are completely destroyed. Cars lifted off the ground. Large trees snapped.
| Significant damage.{{pb}}Well-built structures can suffer serious damage, including roof loss, and the collapse of some exterior walls may occur in poorly built structures. Mobile homes, however, are destroyed. Vehicles can be lifted off the ground, and lighter objects can become small missiles, causing damage outside of the tornado's main path. Wooded areas have a large percentage of their trees snapped or uprooted.
|| [[File:F2 tornado damage example.jpg|150px|At this intensity, tornadoes have a more significant impact on well-built structures, removing the roofs, and collapsing some exterior walls of poorly built structures. F2 tornadoes are capable of completely destroying mobile homes and generating large amounts of flying debris. This home completely lost its roof, but its walls remained intact.]]
|| [[File:FEMA - 40846 - Homeowner and volunteers assess the damage to his home in Arkansas.jpg|200px|Well-built structures can suffer serious damage, including roof loss, and the collapse of some exterior walls may occur in poorly built structures. Mobile homes, however, are destroyed. Vehicles can be lifted off the ground, and lighter objects can become small missiles, causing damage outside of the tornado's main path. Wooded areas have a large percentage of their trees snapped or uprooted.]]
|-
|-
| align="center" bgcolor="#{{storm color|cat3}}" | <big>'''F3'''</big> {{Anchor|F3}}
| align="center" bgcolor="#{{storm color|cat3}}" | <big>'''F3'''</big> {{Anchor|F3}}
| style="text-align:center;"| 158–206 || style="text-align:center;"| 254–332 || style="text-align:center;"| 4.35%
| style="text-align:center;"| 158–206 || style="text-align:center;"| 254–332 || style="text-align:center;"| 4.35%
| Severe damage.{{pb}}Roofs and numerous outside walls blown away from frame homes, all trees in its path uprooted and/or lofted, two-story homes have their second floor destroyed, highrises have many windows blown out, radio towers blown down, metal buildings (i.e. factories, power plants, and construction sites) are heavily damaged, sometimes completely destroyed. Large vehicles such as tractors, buses, and forklifts are blown from their original positions. Severe damage to large structures such as shopping malls. Trains flipped or rolled onto their sides.
| Severe damage.{{pb}}A few parts of affected buildings are left standing. Well-built structures lose all outer and some inner walls. Unanchored homes are swept away, and homes with poor anchoring may collapse entirely. Trains and train cars are all overturned. Small vehicles and similarly sized objects are lifted off the ground and tossed as projectiles. Wooded areas suffer an almost total loss of vegetation and some tree debarking may occur.
|| [[File:F3 tornado damage example.jpg|150px|Here, the roof and all but some inner walls of this frame home have been demolished. While taking shelter in a basement, cellar, or inner room improves one's odds of surviving a tornado drastically, occasionally even this is not enough.]]
|| [[File:FEMA - 9697 - Photograph by Bob McMillan taken on 05-27-2004 in Nebraska.jpg|200px|A few parts of affected buildings are left standing. Well-built structures lose all outer and some inner walls. Unanchored homes are swept away, and homes with poor anchoring may collapse entirely. Trains and train cars are all overturned. Small vehicles and similarly sized objects are lifted off the ground and tossed as projectiles. Wooded areas suffer an almost total loss of vegetation and some tree debarking may occur.]]
|-
|-
| align="center" bgcolor="#{{storm color|cat4}}" | <big>'''F4'''</big> {{Anchor|F4}}
| align="center" bgcolor="#{{storm color|cat4}}" | <big>'''F4'''</big> {{Anchor|F4}}
| style="text-align:center;"| 207–260 || style="text-align:center;"| 333–418 || style="text-align:center;"| 1.00%
| style="text-align:center;"| 207–260 || style="text-align:center;"| 333–418 || style="text-align:center;"| 1%
| Devastating damage.{{pb}}Trees are partially debarked, cars are mangled and thrown in the air, frame homes are completely destroyed and some may be swept away, moving trains are blown off railroad tracks, and barns are leveled. High-rises are significantly damaged.
| Devastating damage.{{pb}}Well-built homes are reduced to a short pile of medium-sized debris on the foundation. Homes with poor or no anchoring are swept completely away. Large, heavy vehicles, including airplanes, trains, and large trucks, can be pushed over, flipped repeatedly, or picked up and thrown. Large, healthy trees are entirely debarked and snapped off close to the ground or uprooted altogether and turned into flying projectiles. Passenger cars and similarly sized objects can be picked up and flung for considerable distances.
|| [[File:F4 tornado damage example.jpg|150px|Brick homes get reduced to piles of rubble. Above-ground structures are almost completely vulnerable to F4 tornadoes, which level well-built structures, toss heavy vehicles through the air, and uproot trees, turning them into flying missiles.]]
|| [[File:FEMA - 9698 - Photograph by Bob McMillan taken on 05-27-2004 in Nebraska.jpg|200px|Well-built homes are reduced to a short pile of medium-sized debris on the foundation. Homes with poor or no anchoring are swept completely away. Large, heavy vehicles, including airplanes, trains, and large trucks, can be pushed over, flipped repeatedly, or picked up and thrown. Large, healthy trees are entirely debarked and snapped off close to the ground or uprooted altogether and turned into flying projectiles. Passenger cars and similarly sized objects can be picked up and flung for considerable distances.]]
|-
|-
| align="center" bgcolor="#{{storm color|cat5}}" | <big>'''F5'''</big> {{Anchor|F5}}
| align="center" bgcolor="#{{storm color|cat5}}" | <big>'''F5'''</big> {{Anchor|F5}}
| style="text-align:center;"| 261–318 || style="text-align:center;"| 419–512 || style="text-align:center;"| 0.10%
| style="text-align:center;"| 261–318 || style="text-align:center;"| 419–512 || style="text-align:center;"| 0.1%
| Incredible damage.{{pb}}Nearly all buildings aside from heavily built structures are destroyed. Cars are mangled and thrown hundreds, possibly thousands of yards away. Frame homes, brick homes, and small businesses are swept away, trees debarked, corn stalks flattened or ripped out of the ground, skyscrapers sustain major structural damage, grass ripped out of the ground. Wood and any small solid material become dangerous projectiles.
| Incredible damage.{{pb}}Well-built and well-anchored homes are taken off their foundations and they go into the air before obliteration. The wreckage of those homes is flung for miles and those foundations are swept completely clean. Large, steel-reinforced structures such as schools are completely leveled. Low-lying grass and vegetation are shredded from the ground. Trees are completely debarked and snapped. Very little recognizable structural debris is generated with most materials reduced to a coarse mix of small, granular particles and dispersed. Large, multiple-ton steel frame vehicles and farm equipment are often mangled beyond recognition and tossed miles away or reduced entirely to unrecognizable parts. Tall buildings collapse or have severe structural deformations. The official description of this damage highlights the extreme nature of the destruction, noting that "incredible phenomena can and will occur".  
|| [[File:F5 tornado damage example.jpg|150px|These tornadoes cause complete destruction, obliterating and sweeping away almost anything in their paths, including those sheltering in open basements, sending any vehicles or trains flying through the air, and causing tall buildings to collapse or to have severe structural deformations.]]
|| [[File:FEMA - 35405 - Tornado damage in Iowa.jpg|200px|Well-built and well-anchored homes are taken off their foundations and they go into the air before obliteration. The wreckage of those homes is flung for miles and those foundations are swept completely clean. Large, steel-reinforced structures such as schools are completely leveled. Low-lying grass and vegetation are shredded from the ground. Trees are completely debarked and snapped. Very little recognizable structural debris is generated with most materials reduced to a coarse mix of small, granular particles and dispersed. Large, multiple-ton steel frame vehicles and farm equipment are often mangled beyond recognition and tossed miles away or reduced entirely to unrecognizable parts. Tall buildings collapse or have severe structural deformations. The official description of this damage highlights the extreme nature of the destruction, noting that "incredible phenomena can and will occur".]]
|}
|}


===Pearson scales===
===Pearson scales===
Line 108: Line 114:


== Rating classifications ==
== Rating classifications ==
{| border="1" cellpadding="15" cellspacing="0" style="text-align:center; float:right; margin:0.46em 1.38em"
{| class="wikitable" style="width:20em; text-align:center; float:right; margin:0.5em 0 1.3em 1.4em;"
|-
|+ Tornado rating classifications
|+ Tornado rating classifications
|-
|-
! style="background: #e0e0ff;" | '''F0'''
! F0
! style="background: #e0e0ff;" | '''F1'''
! F1
! style="background: #e0e0ff;" | '''F2'''
! F2
! style="background: #e0e0ff;" | '''F3'''
! F3
! style="background: #e0e0ff;" | '''F4'''
! F4
! style="background: #e0e0ff;" | '''F5'''
! F5
|-
|-
| colspan="2" style="background: #fd0;"    | Weak
| colspan="2" style="background: #fd0;"    | Weak
Line 136: Line 141:
The Fujita scale, introduced in 1971 as a means to differentiate tornado intensity and path area, assigned wind speeds to damage that were, at best, educated guesses.<ref name="Fujita scale">{{cite book | last = Fujita| first = Tetsuya Theodore|  title = Proposed characterization of tornadoes and hurricanes by area and intensity| publisher = University of Chicago| year = 1971| location = Chicago }}</ref> Fujita and others recognized this immediately and intensive engineering analysis was conducted through the rest of the 1970s. This research, as well as subsequent research, showed that tornado wind speeds required to inflict the described damage were actually much lower than the F-scale indicated, particularly for the upper categories. Also, although the scale gave general descriptions of damage a tornado could cause, it gave little leeway for strength of construction and other factors that might cause a building to sustain more damage at lower wind speeds. Fujita tried to address these problems somewhat in 1992 with the Modified Fujita Scale,<ref>{{cite web|url=http://www.spc.noaa.gov/efscale/|title=NOAA's NWS Storm Prediction Center|first=Storm Prediction|last=Center|website=www.spc.noaa.gov|access-date=May 27, 2017}}</ref> but by then he was semi-retired and the National Weather Service was not in a position to update to an entirely new scale, so it went largely unenacted.<ref name="Fujita Memoirs">{{cite book | last = Fujita| first = Tetsuya Theodore| author-link = Ted Fujita| title = Memoirs of an Effort to Unlock the Mystery of Severe Storms| publisher = University of Chicago| year = 1992| location = Chicago }}</ref>
The Fujita scale, introduced in 1971 as a means to differentiate tornado intensity and path area, assigned wind speeds to damage that were, at best, educated guesses.<ref name="Fujita scale">{{cite book | last = Fujita| first = Tetsuya Theodore|  title = Proposed characterization of tornadoes and hurricanes by area and intensity| publisher = University of Chicago| year = 1971| location = Chicago }}</ref> Fujita and others recognized this immediately and intensive engineering analysis was conducted through the rest of the 1970s. This research, as well as subsequent research, showed that tornado wind speeds required to inflict the described damage were actually much lower than the F-scale indicated, particularly for the upper categories. Also, although the scale gave general descriptions of damage a tornado could cause, it gave little leeway for strength of construction and other factors that might cause a building to sustain more damage at lower wind speeds. Fujita tried to address these problems somewhat in 1992 with the Modified Fujita Scale,<ref>{{cite web|url=http://www.spc.noaa.gov/efscale/|title=NOAA's NWS Storm Prediction Center|first=Storm Prediction|last=Center|website=www.spc.noaa.gov|access-date=May 27, 2017}}</ref> but by then he was semi-retired and the National Weather Service was not in a position to update to an entirely new scale, so it went largely unenacted.<ref name="Fujita Memoirs">{{cite book | last = Fujita| first = Tetsuya Theodore| author-link = Ted Fujita| title = Memoirs of an Effort to Unlock the Mystery of Severe Storms| publisher = University of Chicago| year = 1992| location = Chicago }}</ref>


In the United States, on February 1, 2007,<ref name=" NOAA: Fujita Tornado Damage Scale"/> the Fujita scale was decommissioned in favor of what scientists believe is a more accurate Enhanced Fujita Scale. The meteorologists and engineers who designed the EF Scale believe it improves on the F-scale on many counts. It accounts for different degrees of damage that occur with different types of structures, both manmade and natural. The expanded and refined damage indicators and degrees of damage standardize what was somewhat ambiguous. It also is thought to provide much better estimates of wind speeds and sets no upper limit on the wind speeds for the highest level, EF5. Environment Canada began using the Enhanced Fujita scale in Canada on April 1, 2013.<ref>[http://www.theweathernetwork.com/news/storm_watch_stories3&stormfile=Assessing_tornado_damage__EF-scale_vs._F-scale_19_04_2013?ref=ccbox_homepage_topstories Assessing tornado damage: EF-scale vs. F-scale] {{webarchive|url=https://web.archive.org/web/20130427003723/http://www.theweathernetwork.com/news/storm_watch_stories3%26stormfile%3DAssessing_tornado_damage__EF-scale_vs._F-scale_19_04_2013?ref=ccbox_homepage_topstories |date=April 27, 2013 }}</ref> The U.S. and Canada are the only countries to officially adopt the Enhanced Fujita scale.
In the United States, on February 1, 2007,<ref name=" NOAA: Fujita Tornado Damage Scale"/> the Fujita scale was decommissioned in favor of what scientists believe is a more accurate Enhanced Fujita Scale. The meteorologists and engineers who designed the EF Scale believe it improves on the F-scale on many counts. It accounts for different degrees of damage that occur with different types of structures, both manmade and natural. The expanded and refined damage indicators and degrees of damage standardize what was somewhat ambiguous. It also is thought to provide much better estimates of wind speeds and sets no upper limit on the wind speeds for the highest level, EF5. Environment Canada began using the Enhanced Fujita scale in Canada on April 1, 2013.<ref>[http://www.theweathernetwork.com/news/storm_watch_stories3&stormfile=Assessing_tornado_damage__EF-scale_vs._F-scale_19_04_2013?ref=ccbox_homepage_topstories Assessing tornado damage: EF-scale vs. F-scale] . Toronto has seen several tornados since the 1900s.
 
{{webarchive|url=https://web.archive.org/web/20130427003723/http://www.theweathernetwork.com/news/storm_watch_stories3%26stormfile%3DAssessing_tornado_damage__EF-scale_vs._F-scale_19_04_2013?ref=ccbox_homepage_topstories |date=April 27, 2013 }}</ref> The U.S. and Canada are the only countries to officially adopt the Enhanced Fujita scale.  
== See also ==
== See also ==
{{Div col|colwidth=30em|small=yes}}
{{Div col|colwidth=30em}}
* [[Earth:Enhanced Fujita scale|Enhanced Fujita scale]]
* [[Earth:Enhanced Fujita scale|Enhanced Fujita scale]]
* [[Earth:International Fujita scale|International Fujita scale]]
* [[Earth:International Fujita scale|International Fujita scale]]
Line 166: Line 171:
* [https://repository.library.noaa.gov/view/noaa/7227 The Tornado: An Engineering-Oriented Perspective] (NWS SR147)
* [https://repository.library.noaa.gov/view/noaa/7227 The Tornado: An Engineering-Oriented Perspective] (NWS SR147)
* [http://www.lib.utexas.edu/taro/ttusw/00271/tsw-00271.html Fujita archival records] ([[Organization:Texas Tech University|Texas Tech University]])
* [http://www.lib.utexas.edu/taro/ttusw/00271/tsw-00271.html Fujita archival records] ([[Organization:Texas Tech University|Texas Tech University]])
{{EF scale}}


[[Category:Tornado]]
[[Category:Tornado]]


{{Sourceattribution|Fujita scale}}
{{Sourceattribution|Fujita scale}}

Latest revision as of 16:40, 8 August 2025

Short description: Scale for rating tornado intensity
"F2 tornado" and "F3 tornado" redirect here. For the military aircraft, see Panavia Tornado ADV. For the EF scale, see Enhanced Fujita scale. For the IF-scale, see International Fujita scale.

Template:Fujita small

The Fujita scale (F-Scale; /fuˈtə/), or Fujita–Pearson scale (FPP scale), is a scale for rating tornado intensity, based primarily on the damage tornadoes inflict on human-built structures and vegetation. The official Fujita scale category is determined by meteorologists and engineers after a ground or aerial damage survey, or both; and depending on the circumstances, ground-swirl patterns (cycloidal marks), weather radar data, witness testimonies, media reports and damage imagery, as well as photogrammetry or videogrammetry if motion picture recording is available. The Fujita scale, named for the meteorologist Ted Fujita, was replaced with the Enhanced Fujita scale (EF-Scale) in the United States in February 2007. In April 2013, Canada adopted the EF-Scale over the Fujita scale along with 31 "Specific Damage Indicators" used by Environment Canada (EC) in their ratings.[1][2]

Background

The scale was introduced in 1971 by Ted Fujita of the University of Chicago, in collaboration with Allen Pearson, head of the National Severe Storms Forecast Center/NSSFC (currently the Storm Prediction Center/SPC). The scale was updated in 1973, taking into account path length and width. In the United States, starting in the late 1970s,[3] tornadoes were rated soon after occurrence. The Fujita scale was applied retroactively to tornadoes reported between 1950 and the adoption of the scale in the National Oceanic and Atmospheric Administration (NOAA) National Tornado Database. Fujita rated tornadoes from 1916 to 1992[4][5] and Tom Grazulis of The Tornado Project retroactively rated all known significant tornadoes (F2–F5 or causing a fatality) in the U.S. back to 1880.[6]

On February 1, 2007, the Fujita scale was decommissioned, and the Enhanced Fujita Scale was introduced in the United States.[7] The new scale more accurately matches wind speeds to the severity of damage caused by the tornado.[8]

Though each damage level is associated with a wind speed, the Fujita scale is effectively a damage scale, and the wind speeds associated with the damage listed are not rigorously verified. The Enhanced Fujita Scale was formulated due to research that suggested that the wind speeds required to inflict damage by intense tornadoes on the Fujita scale are greatly overestimated. A process of expert elicitation with top engineers and meteorologists resulted in the EF scale wind speeds, but these are biased to United States construction practices. The EF scale also improved damage parameter descriptions.[citation needed]

Derivation

A diagram illustrating the relationship between the Beaufort, Fujita, and Mach number scales.

The original scale as derived by Fujita was a theoretical 13-level scale (F0–F12) designed to smoothly connect the Beaufort scale and the Mach number scale. F1 corresponds to the twelfth level of the Beaufort scale, and F12 corresponds to Mach number 1.0. F0 was placed at a position specifying no damage (approximately the eighth level of the Beaufort scale), in analogy to how Beaufort's zeroth level specifies little to no wind. From these wind speed numbers, qualitative descriptions of damage were made for each category of the Fujita scale, and then these descriptions were used to classify tornadoes.[9]

F6 rating

At the time Fujita derived the scale, little information was available on damage caused by wind, so the original scale presented little more than educated guesses at wind speed ranges for specific tiers of damage. Fujita intended that only F0–F5 be used in practice, as this covered all possible levels of damage to frame homes as well as the expected estimated bounds of wind speeds. He did, however, add a description for F6, which he called an "inconceivable tornado", to allow for wind speeds exceeding F5 and possible advancements in damage analysis that might show it.[10]

Based on aerial photographs of the damage it caused, Fujita assigned the strongest tornado of the 1974 Super Outbreak, which affected Xenia, Ohio, a preliminary rating of F6 intensity ± 1 scale.[11] The 1977 Birmingham–Smithfield F5 tornado's damage was surveyed by Ted Fujita and he "toyed with the idea of rating the Smithfield tornado an F6".[12] In 2001, tornado expert Thomas P. Grazulis stated in his book F5–F6 Tornadoes; "In my opinion, if there ever was an F6 tornado caught on video, it was the Pampa, Texas tornado of 1995".[13] In 2023, it was announced by the Storm Prediction Center and National Weather Service Norman, Oklahoma that the 1970 Lubbock tornado was originally rated F6, which was later downgraded to its official rating of F5.[14]

Furthermore, the original wind speed numbers have since been found to be higher than the actual speeds required to incur the damage described at each category. The error manifests itself to an increasing degree as the category increases, especially in the range of F3 through F5. NOAA notes that "precise wind speed numbers are actually guesses and have never been scientifically verified. Different wind speeds may cause similar-looking damage from place to place—even from building to building. Without a thorough engineering analysis of tornado damage in any event, the actual wind speeds needed to cause that damage are unknown."[10]

The Tornado Project, headed by tornado expert Thomas P. Grazulis, states in reference to the F6 rating, [i]f this level is ever achieved, evidence for it might only be found in some manner of ground swirl pattern, for it may never be identifiable through engineering studies.[15]

Parameters

The six categories are listed here, in order of increasing intensity.

  • The rating of any given tornado is of the most severe damage to any well-built frame home or comparable level of damage from engineering analysis of other damage.
  • Since the Fujita scale is based on the severity of damage resulting from high winds, a tornado exceeding F5 is an immeasurable theoretical construct. Frame-home structural damage cannot exceed total destruction and debris dispersal, which constitutes F5 damage. Tornadoes with wind speeds over 319 mph (513 km/h) are possible and such extreme gusts have been determined using mobile radar observation, but no tornado has received an official damage-based F6 rating.
Scale Wind speed estimate[7] Frequency[16] Potential damage[7]
mph km/h
align="center" bgcolor="#
  1. REDIRECT Template:Storm colour" | F0
40–72 64–116 44.14% Light damage.
Well-built structures are typically unscathed, though sometimes sustaining broken windows, with minor damage to roofs and chimneys. Billboards and large signs can be knocked down. Trees may have large branches broken off and can be uprooted if they have shallow roots. 		Well-built structures are typically unscathed, though sometimes sustaining broken windows, with minor damage to roofs and chimneys. Billboards and large signs can be knocked down. Trees may have large branches broken off and can be uprooted if they have shallow roots.
align="center" bgcolor="#
  1. REDIRECT Template:Storm colour" | F1
73–112 117–180 34.24% Moderate damage.
Damage to mobile homes and other temporary structures becomes significant, and cars and other vehicles can be pushed off the road or flipped. Permanent structures can suffer major damage to their roofs. 		There is damage to mobile homes and other temporary structures becomes significant, and cars and other vehicles can be pushed off the road or flipped. Permanent structures can suffer major damage to their roofs.
align="center" bgcolor="#
  1. REDIRECT Template:Storm colour" | F2
113–157 181–253 16.17% Significant damage.
Well-built structures can suffer serious damage, including roof loss, and the collapse of some exterior walls may occur in poorly built structures. Mobile homes, however, are destroyed. Vehicles can be lifted off the ground, and lighter objects can become small missiles, causing damage outside of the tornado's main path. Wooded areas have a large percentage of their trees snapped or uprooted. 		Well-built structures can suffer serious damage, including roof loss, and the collapse of some exterior walls may occur in poorly built structures. Mobile homes, however, are destroyed. Vehicles can be lifted off the ground, and lighter objects can become small missiles, causing damage outside of the tornado's main path. Wooded areas have a large percentage of their trees snapped or uprooted.
align="center" bgcolor="#
  1. REDIRECT Template:Storm colour" | F3
158–206 254–332 4.35% Severe damage.
A few parts of affected buildings are left standing. Well-built structures lose all outer and some inner walls. Unanchored homes are swept away, and homes with poor anchoring may collapse entirely. Trains and train cars are all overturned. Small vehicles and similarly sized objects are lifted off the ground and tossed as projectiles. Wooded areas suffer an almost total loss of vegetation and some tree debarking may occur. 		A few parts of affected buildings are left standing. Well-built structures lose all outer and some inner walls. Unanchored homes are swept away, and homes with poor anchoring may collapse entirely. Trains and train cars are all overturned. Small vehicles and similarly sized objects are lifted off the ground and tossed as projectiles. Wooded areas suffer an almost total loss of vegetation and some tree debarking may occur.
align="center" bgcolor="#
  1. REDIRECT Template:Storm colour" | F4
207–260 333–418 1% Devastating damage.
Well-built homes are reduced to a short pile of medium-sized debris on the foundation. Homes with poor or no anchoring are swept completely away. Large, heavy vehicles, including airplanes, trains, and large trucks, can be pushed over, flipped repeatedly, or picked up and thrown. Large, healthy trees are entirely debarked and snapped off close to the ground or uprooted altogether and turned into flying projectiles. Passenger cars and similarly sized objects can be picked up and flung for considerable distances. 		Well-built homes are reduced to a short pile of medium-sized debris on the foundation. Homes with poor or no anchoring are swept completely away. Large, heavy vehicles, including airplanes, trains, and large trucks, can be pushed over, flipped repeatedly, or picked up and thrown. Large, healthy trees are entirely debarked and snapped off close to the ground or uprooted altogether and turned into flying projectiles. Passenger cars and similarly sized objects can be picked up and flung for considerable distances.
align="center" bgcolor="#
  1. REDIRECT Template:Storm colour" | F5
261–318 419–512 0.1% Incredible damage.
Well-built and well-anchored homes are taken off their foundations and they go into the air before obliteration. The wreckage of those homes is flung for miles and those foundations are swept completely clean. Large, steel-reinforced structures such as schools are completely leveled. Low-lying grass and vegetation are shredded from the ground. Trees are completely debarked and snapped. Very little recognizable structural debris is generated with most materials reduced to a coarse mix of small, granular particles and dispersed. Large, multiple-ton steel frame vehicles and farm equipment are often mangled beyond recognition and tossed miles away or reduced entirely to unrecognizable parts. Tall buildings collapse or have severe structural deformations. The official description of this damage highlights the extreme nature of the destruction, noting that "incredible phenomena can and will occur". 		Well-built and well-anchored homes are taken off their foundations and they go into the air before obliteration. The wreckage of those homes is flung for miles and those foundations are swept completely clean. Large, steel-reinforced structures such as schools are completely leveled. Low-lying grass and vegetation are shredded from the ground. Trees are completely debarked and snapped. Very little recognizable structural debris is generated with most materials reduced to a coarse mix of small, granular particles and dispersed. Large, multiple-ton steel frame vehicles and farm equipment are often mangled beyond recognition and tossed miles away or reduced entirely to unrecognizable parts. Tall buildings collapse or have severe structural deformations. The official description of this damage highlights the extreme nature of the destruction, noting that "incredible phenomena can and will occur".

Pearson scales

In 1973, Allen Pearson added additional path length and path width parameters to the Fujita scale. Under this version, each tornado would be assigned one Fujita scale rating and two Pearson scale ratings. For example, a tornado rated F4 based on damage with a path length of 63 miles (101 km) and a path width of 800 yards (730 m) would be rated F,P,P 4,4,4. Use of the Pearson scales was not widespread, however, and it remained more common to simply list a tornado's path length and path width directly.[6]

Pearson scales
Scale Path length Path width
<0.3 mi (0.48 km) <6 yd (5.5 m)
bgcolor="Template:Storm colour"| P0 0.3–0.9 mi (0.48–1.45 km) 6–17 yd (5.5–15.5 m)
bgcolor="Template:Storm colour"| P1 1.0–3.1 mi (1.6–5.0 km) 18–55 yd (16–50 m)
bgcolor="Template:Storm colour"| P2 3.2–9.9 mi (5.1–15.9 km) 56–175 yd (51–160 m)
bgcolor="Template:Storm colour"| P3 10–31 mi (16–50 km) 176–566 yd (161–518 m)
bgcolor="Template:Storm colour"| P4 32–99 mi (51–159 km) 0.3–0.9 mi (0.48–1.45 km)
bgcolor="Template:Storm colour"| P5 100–315 mi (161–507 km) 1.0–3.1 mi (1.6–5.0 km)

Rating classifications

Tornado rating classifications
F0 F1 F2 F3 F4 F5
Weak Strong Violent
Significant
Intense

For purposes such as tornado climatology studies, Fujita scale ratings may be grouped into classes.[6][17][18]

Decommissioning in the U.S.

The Fujita scale, introduced in 1971 as a means to differentiate tornado intensity and path area, assigned wind speeds to damage that were, at best, educated guesses.[19] Fujita and others recognized this immediately and intensive engineering analysis was conducted through the rest of the 1970s. This research, as well as subsequent research, showed that tornado wind speeds required to inflict the described damage were actually much lower than the F-scale indicated, particularly for the upper categories. Also, although the scale gave general descriptions of damage a tornado could cause, it gave little leeway for strength of construction and other factors that might cause a building to sustain more damage at lower wind speeds. Fujita tried to address these problems somewhat in 1992 with the Modified Fujita Scale,[20] but by then he was semi-retired and the National Weather Service was not in a position to update to an entirely new scale, so it went largely unenacted.[21]

In the United States, on February 1, 2007,[1] the Fujita scale was decommissioned in favor of what scientists believe is a more accurate Enhanced Fujita Scale. The meteorologists and engineers who designed the EF Scale believe it improves on the F-scale on many counts. It accounts for different degrees of damage that occur with different types of structures, both manmade and natural. The expanded and refined damage indicators and degrees of damage standardize what was somewhat ambiguous. It also is thought to provide much better estimates of wind speeds and sets no upper limit on the wind speeds for the highest level, EF5. Environment Canada began using the Enhanced Fujita scale in Canada on April 1, 2013.[22] The U.S. and Canada are the only countries to officially adopt the Enhanced Fujita scale.

See also


References

  1. 1.0 1.1 "Fujita Tornado Damage Scale". http://www.spc.noaa.gov/faq/tornado/f-scale.html. 
  2. "Fujita Scale – Tornado Damage Scale". https://www.factsjustforkids.com/weather-facts/tornado-facts-for-kids/fujita-scale.html. 
  3. Edwards, Roger; LaDue, James G.; Ferree, John T.; Scharfenberg, Kevin; Maier, Chris; Coulbourne, William L. (2013-05-01). "Tornado Intensity Estimation: Past, Present, and Future" (in en). Bulletin of the American Meteorological Society 94 (5): 641–653. doi:10.1175/BAMS-D-11-00006.1. ISSN 1520-0477. Bibcode2013BAMS...94..641E. https://www.spc.noaa.gov/publications/edwards/ef-scale.pdf. 
  4. McDonald, James R. (2001). "American Meteorological Society". Bulletin of the American Meteorological Society 82 (1): 63–72. doi:10.1175/1520-0477(2001)000<0063:TTFHCT>2.3.CO;2. Bibcode2001BAMS...82...63M. 
  5. McCarthy, Daniel. "NWS Tornado Surveys and the Impact on the National Tornado". https://www.spc.noaa.gov/publications/mccarthy/f-scale.pdf. 
  6. 6.0 6.1 6.2 Grazulis, Thomas P. (July 1993). Significant Tornadoes 1680–1991. St. Johnsbury, Vermont: The Tornado Project of Environmental Films. ISBN 978-1-879362-03-1. 
  7. 7.0 7.1 7.2 Fujita Tornado Damage Scale Storm Prediction Center. Accessed May 20, 2009.
  8. Center, Storm Prediction. "NOAA's NWS Storm Prediction Center" (in EN-US). https://www.spc.noaa.gov/efscale/. 
  9. "Storm Prediction Center". http://www.spc.noaa.gov/efscale/. 
  10. 10.0 10.1 Tornado FAQ. Storm Prediction Center. Site accessed June 27, 2006.
  11. Fujita, T. Theodore (1974). "Jumbo Tornado Outbreak of 3 April 1974". https://www.weather.gov/media/ohx/PDF/fujita_april31974.pdf. 
  12. "April 4, 1977, Smithfield F5 Tornado". National Weather Service. https://www.weather.gov/bmx/event_04041977. 
  13. Thomas P. Grazulis (2021). F5-F6 Tornadoes. The Tornado Project. 
  14. Roger Edwards (SPC); Matthew S. Elliott (SPC); Patrick T. Marsh (SPC; Douglas A. Speheger (NWS). "Errors, Oddities and Artifacts in U.S. Tornado Data, 1995–2021". Storm Prediction Center Publications: 1–10. https://www.spc.noaa.gov/publications/edwards/oddities.pdf. Retrieved 11 January 2023. 
  15. "The Fujita Scale". St. Johnsbury, Vermont. 2015. https://www.tornadoproject.com/cellar/fscale.htm. 
  16. "Storm Prediction Center WCM Data". Storm Prediction Center. https://www.spc.noaa.gov/wcm/data/. 
  17. The Fujita Scale of Tornado Intensity, Archived at:
  18. Brooks, Harold. "index". http://www.nssl.noaa.gov/hazard/. 
  19. Fujita, Tetsuya Theodore (1971). Proposed characterization of tornadoes and hurricanes by area and intensity. Chicago: University of Chicago. 
  20. Center, Storm Prediction. "NOAA's NWS Storm Prediction Center". http://www.spc.noaa.gov/efscale/. 
  21. Fujita, Tetsuya Theodore (1992). Memoirs of an Effort to Unlock the Mystery of Severe Storms. Chicago: University of Chicago. 
  22. Assessing tornado damage: EF-scale vs. F-scale . Toronto has seen several tornados since the 1900s.

Bibliography

  • Marshall, Timothy P. (2001). "Birth of the Fujita Scale". Storm Track 24 (3): 6–10. 
  • Edwards, Roger; J. G. LaDue; J. T. Ferree; K. Scharfenberg; C. Maier; W. L. Coulbourne (2013). "Tornado Intensity Estimation: Past, Present, and Future". Bull. Amer. Meteor. Soc. 94 (5): 641–653. doi:10.1175/BAMS-D-11-00006.1. Bibcode2013BAMS...94..641E. 

External links

Template:EF scale



Retrieved from "https://handwiki.org/wiki/index.php?title=Earth:Fujita_scale&oldid=3742036"