570 likes | 585 Views
Understand the methodology behind generating standard deviations, apply them to extreme weather events, and evaluate model trends for better operational forecasting accuracy.
E N D
Using Standardized Anomaly Data in Operational Forecasting Mike Bodner NCEP/HPC Development Training Branch Spring/Summer 2005
Training Outline • Overview of standard deviations and statistical methods in forecasting • Methodology and computational information behind operational standard deviations • Application of standard deviations for extreme temperature and heavy precipitation events • Suggested methodologies for local meso-scale standardized anomalies • Look at significant cases
We are already using tools that apply stochastic methods in operational forecasting… • MOS output • Ensembles • Short Range Ensemble Forecasts (SREFs)
Standard deviations can be another tool to add to the chest… • Based on 50 years of climatology • Can be applied to a model forecast output and assist in evaluating model trends
How are standard deviations generated? Daily averages and standard deviations (variances) are computed for the period 1950-2003 from NCAR/NCEP Reanalysis data for • 500 hPa heights • 850 hPa temperatures • 850 hPa temperatures • 1000-500 hPa thickness and partial thicknesses
Another way of looking at it using 500 hPa heights… Standard deviation or σ is computed by the following formula.. σ= square root of the average of heights 2 - average height2 The number of standard deviations from the climatology is computed by subtracting the 50 year average height from the model forecast or observed height then dividing by the standard deviation. Standardized Anomaly = (fcst height - average height) ÷ σ
Reanalysis data is set on a 2.5 x 2.5 global grid domain • Model data is resized to coincide with the reanalysis domain
Keep in mind when looking at standard deviation data in an operational setting.. • Typically standardized anomalies of 3-4 units from climatology during the cold season and 2-3 in the warm season correspond with a significant temperature event • Forecast values of 5 and 6 are of extremely low probability and should be closely scrutinized if displayed in model forecast data
Surprise October 1996 snow event in Kansas City metro area..500 hPa heights were 4.5 SDs lower than climatology
Other items to be aware of when using this tool • It’s beneficial to be aware of the standard deviations or at least the SD pattern for your forecast data • The climatological standard deviations are not as large over the southern latitudes, particularly during the warm season • Standard deviations are larger over the northern latitudes with the greatest variance over the North Pacific, North Atlantic and northeast North America.
Here’s an example of the computed standard deviations for 500 hPa heights forJuly 4. Notice how the variance increases proportionally with latitude. Also note how the largest standard deviations occur over the North Pacific and North Atlantic.
Let’s apply the SD data from the July 4 image in the previous slide… • At Atlanta, GA. The average 500 hPa height for July 4 is588 dm, and the standard deviation for 500 hPa height over Atlanta is3dm • A forecast value of 3 standard deviationsfrom normal or -3 would suggest a forecast height of 579 dm which is 9 dm below climatology • At Seattle, WA. The average 500 hPa height for July 4 is about 570 dm, and the standard deviation for 500 hPa height over Seattle is 9 dm • A forecast value of 3 standard deviationsfrom normal or -3 would suggest a forecast height of 543 dmor 27 dm below climatology.
As mentioned several slides earlier, height and temperature regimes depicted as 3 or more standard deviations from climatology are very rare. The number of standard deviations are displayed with probability of occurrence of the number of standard deviations from climatology based on a standard probability density function (PDF) curve. The values include both above and below normal conditions.
The values plotted on the standard "bell curve" depict percent probability of a standard deviation being above or below the climatological mean (essentially these values are half of the probabilities sited in the above chart). As you can see, there is extremely low probability for forecast events greater than 3 standard deviations from climatology. Also note that temperature events trend slightly to the left or colder than the median.
Let’s take a look a few regional heat cases… • Northeast U.S. Heat Wave – July 1966 • Central U.S. Heat Wave – July 1980 • Southwest U.S. Extreme Heat – June 1990
4th of July Heat Wave over the Northeast U.S. Triple digit temperatures were noted over many Northeast locations during the 3 day period 3-5 July 1966. On July 3, 1966, record high temperatures included 102F at Hartford, CT, 107F at LaGuardia (highest NYC area temperature), 105F at Allentown, PA and 104F at Philadelphia, PA. The 500 hPa charts for this record breaking heat event do not depict a pattern typical of a severe heat wave. 500 hPa heights are 2 standard deviations above climatology but the 850 hPa thermal field also ended up being a signal for this extreme temperature event.
Chicago and Central U.S. Heat Wave 1995 On July 12-15 a deadly heat wave effected the Chicago, IL and central U.S. Numerous triple digit temperatures were observed and several maximum temperature records were established during this event, particularly on July 13. Some record from this day included 106F at Chicago Midway, 104F at Chicago O’Hare, 103F at Milwaukee, WI.
Southwest U.S. – Extreme Heat June 1990 A pre-monsoon 500 hPa anti-cyclone became established over the southwest U.S. in late June 1990. During the period June 25-28, numerous records were set. On June 26, a record maximum temperature of 122F was recorded at Phoenix, AZ. In Downtown Los Angeles a record 112F was observed. Both 500 hPa heights and 850 hPa temperatures were 2 SDs above climatology near the center of the upper high.
Note the close agreement of the 850-700 hPa thickness with the 850 hPa temperature field. As with cold cases, this partial thickness may be used over high terrain where 850 hPa is negated.
Applying this tool to extreme cold at the regional scale… • Northeast U.S. – January 1994 • Central U.S. – November 1991 • Western U.S. – February 1989
Record Cold Northeast U.S 19-21 January 1994 Temperatures remained below zero for over 50 hours in Pittsburgh and many other sections of Pennsylvania, Ohio New York and New England during 19-21 January 1994. 500 hPa height fields for 19 January 1994 show a deep trough over eastern North America, but the significant departure from climatology as depicted by the standard deviation fields illustrated the extent of the low level cold air. Moreover fresh snow cover increased the potential for an exceptionally cold boundary layer.
Record Cold over Central U.S. November 1991 Within days after the “perfect storm” churned up the western Atlantic and caused extensive damage to the Northeast coast, another intense cyclone resulted in an early season heavy snow event across the upper Mississippi Valley. In the aftermath of this storm, a full latitude trough delivered a record cold air mass to the plains states. Significant negative temperature anomalies were noted at 850 hPa. The images to the right show 500 and 850 hPa fields for 3 November 1991. This was the initial surge of arctic air into the central U.S. during a record breaking cold week.
Record cold over Western U.S. February 1989 A very large arctic air mass moved into the western U.S. in early February 1989. The coldest anomalies both at 850 hPa and the surface were noted over the Great Basin region. Eventually the cold migrated to the central and southern plains. On the graphics for 6 February 1989, note the anomalously large ridge over the Gulf of Alaska at 500 hPa and full latitude trough over the western states to delivery the cold air. February records were set at Reno, NV, -15F, -30F at Ely, NV and 31F at San Francisco, CA on 6 February 1989.
As was the case in the western heat event, since 850 hPa is “in the ground” over the inter-mountain region of the western U.S., we can look at the 1000-500 hPa and 850-700 hPa thickness fields.
In spite of being “in the ground”, the 850 hPa temperature field correlates well with the record cold observed at the surface. Notice the -3.0 to -3.5 standardized anomalies over the lower elevations of California and the Central Plains.
Evaluating Model Data • Two summer cold front cases where fronts pushed unseasonably far to the south • 500 hPa heights examined to evaluate upper level thrust behind surface the cold fronts
Heavy precipitation events… • Hurricane Floyd – September 1999 • Fort Collins, CO Flash Flood – July 1997 • Blizzard of 1996 – January 1996