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Transcript of Page 1 Determining changes in extratropical storm conditions - homogeneity and representativity Hans...
Page 1
Determining changes in extratropical storm conditions
- homogeneity and representativity
Hans von Storch
Institute of Coastal Research, GKSS Research Center, Geesthacht
and
CLISAP KlimaCampus, Hamburg University, Germany
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Message
a) The major problem for statisticians applying their (ancient or modern) tools is the sampling assumption. Most data (both observational or derived = analyzed) are inhomogeneous.
b) Simulation data are usually “better” – namely homogenous are available for long even very long times. But the degree of realism is always an issue.
Advice:
1) When dealing with “real” data have contact to meteorologists, oceanographers etc.
2) When dealing with simulated data, have contact to modellers.
3) When testing new method, begin with simulation data.
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Challenge Storminess best represented by wind statistics, possibly derived quantities such as stream function, vorticity, but wind time series are almost always
• inhomogeneous
• too short
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10-yearly sum of events with winds stronger than 7 Bft in Hamburg
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Wind speed measurements
SYNOP Measuring net (DWD)
Coastal stations at the German Bight
Observation period: 1953-2005
Representativity of near surface wind speed measurements
This and the next 3 transparencies: Janna Lindenberg, GKSS
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Representativity of near surface wind speed measurements
1.25 m/s
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Causes of inhomogenities:Changes in
Instruments Sampling
frequencies Measuring units Environments (e.g.
trees, buildings) Location
Station relocations
(Dotted lines)
Representativity of near surface wind speed measurements
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Representativity of near surface wind speed measurements
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Difference of max storm surge heights Hamburg - Cuxhaven
Storm surges intensified after 1962 event due to improving coastal defense and deepening shipping channel in the river.
Time series of frequency of stormy days in Kullaberg (south-western Sweden), number of days per year with wind speed V≥21 m/s.
Time series of frequency of stormy days in Kullaberg (south-western Sweden), number of days per year with wind speed V≥21 m/s.
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Counting storms in weather maps – steady increase of NE Atlantic storms since the 1930s ….
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“Great Miami”, 1926, Florida, Alamaba – damages of 2005 usage - in 2005 money: 139 b$
Katrina, 2005: 81 b$Pielke, Jr., R.A., Gratz, J., Landsea, C.W., Collins, D., Saunders, M., and Musulin, R., 2008. Normalized Hurricane Damages in the United States: 1900-2005. Natural Hazards Review
The increase in damages related to
extreme weather conditions is massive –
but is it because the weather is getting
worse?
Losses from Atlantic Hurricanes
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T
The major problem for applying statistical analysis (ancient and modern) is related
- to the assumptions on the sampling process, and
- to the assumption of representativity
The local data change their statistics by changing observational practices and conditions; also their representativity for a larger area is often compromised.
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For assessing changing storm conditions, principally two approaches are possible:
a) Use of proxies, such a air pressure readings.
b) Simulation by empirical or dynamical downscaling of large scale information.
Usage of weather analyses, incl. re-analyses and proxies such as damages are not suitable.
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Pressure proxies
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Pressure based proxies
Air pressure readings are mostly homogenous
Annual/seasonal percentiles of geostrophic wind derived from triangles of pressure readings (e.g., 95 or 99%iles); such percentiles of geostrophic wind and of “real” wind are linearly related.
Annual frequency of events with geostrophic wind equal or larger than 25 m/s
Annual frequency of 24 hourly local pressure change of 16 hPa in a year
Annual frequency of pressure readings less than 980 hPa in a year
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Geostrophic Wind
•The tropospheric wind is to first order approximation proportional to atmospheric pressure gradient
•The scaled pressure gradient is called “geostrophic wind”.
•The geostrophic wind flows parallel to isobars
•The geostrophic wind is a proxy for real wind.
•At the surface, the geostrophic wind is stronger than the real wind.
Oliver Krüger
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Geostrophic Wind - why is it useful?
•good approximation for synoptic scale airflow
•surface air pressure measurements can be used to calculate the geostrophic wind
• Pressure readings are usually homogenous
• Geostrophic winds may be derived for a long period.
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•An example is given by Schmidt and von Storch, 1993.
•They calculated daily geostrophic wind speed from surface air pressure measurements at three synoptic stations around the German Bight.
•Annual distributions were obtained for the period of 1876-1990.
•Upper percentiles of wind speed were derived and used as a proxy for storm activity over the German Bight.
•Upper percentiles are the values of wind speed above which a certain percent of observations fall.
•Assessing these upper percentiles gives information about changes in the marine storm climate.
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Other storm proxies
Variance of local water levels relative to annual mean (high tide) water level.
Repair costs of dikes in historical times.
Sailing times of ships on historical routes.
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Proxies:
N Europe
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Geostropic wind stats N Europe
99%iles of annual geostrophic wind speeds
for a series of station triangles in the North Sea regions and in the Baltic Sea region.
Alexandersson et al., 2002
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Local pressure stats since 1800
Time series of pressure-based storminess indices derived from pressure readings in Lund (blue) and Stockholm (red). From top to bottom: Annual number of pressure observations below 980 hPa (Np980), annual number of absolute pressure differences exceeding 16 hPa/12 h (NDp/Dt),Intra-annual 95-percentile and 99-percentile of the pressure differences (P95 and P99) in units of hPa.
From Bärring and von Storch, 2005: see also BACC 2008.
Stockholm
Lund
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Regional development of storminess and temperature
Unchanging extratropcial storm conditions is not contradicting the fact that temperature is rising.
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Dynamical Dowscaling
N EuropeDownscaling NCEP/NCAR large-scale analysis of
1958-2006 weather
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Downscaling cascade
Globale development(NCEP)
Dynamical DownscalingREMO or CLM
Simulation with barotropicmodel of North Sea
Empirical Downscaling
Pegel St.
Pauli
Cooperation with a variety of governmental agencies and with a number of private companies
Mixed dynamical/empirical. downscaling cascade for
constructing variable regional and local marine
weather statistics
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Baroclinic storms in N Europe
Problem solved for synoptic systems in N Europe in CoastDat@GKSS, using RCM spectrally nudged to NCEP
- retrospective analysis 1958-2005- good skill with respect to statistics, but not all details are recovered.
Weisse, R., H. von Storch and F. Feser, 2005: Northeast Atlantic and North Sea storminess as simulated by a regional climate model 1958-2001 and comparison with observations. J. Climate 18, 465-479
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Stormcount 1958-2001
Weis
se et
al.,
J. C
limate
, 200
5
Change of # Bft 8/year
t ≤ T t ≥ T
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Oct
Polar Lows
c=0,72
Comparison with satellite data
Count of Polar Lows per month. – downscaling - satellite data (Blechschmidt, 2008)
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Downscaling re-analysis
Downscaling re-analysis
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Conclusion: Usage of proxies
1. Monitoring extra-tropical storminess may be based on air pressure proxies.
2. This allows assessments for 100 and more years.
3. Decades long upward and downwards trends have been detected in recent years.
4. These trends are not sustained and have show recent reversals in all considered regions.
5. Recent trends are not beyond the range of natural variations, as given by the historical past, but are more of intermittent character. Regional temperatures rose significantly at the same time.
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Conclusion: Usage of dynamical downscaling
1. Dynamical downscaling for describing synoptic and mesoscale variability is doable.
2. Meso-scale Polar Lows are also described, but the depth of the cyclones is not as deep as found in reality; also the winds are too weak.
3. Validation difficult, because homogeneous long term observed data do not exist.
4. Analysis of 60 year simulations point to strong year-to-year variability, to less decade-to-decade variability and no noteworthy trend.
Page 36
Message
a) The major problem for statisticians applying their (ancient or modern) tools is the sampling assumption. Most data (both observational or derived = analyzed) are inhomogeneous.
b) Simulation data are usually “better” – namely homogenous are available for long even very long times. But the degree of realism is always an issue.
Advice:
1) When dealing with “real” data have contact to meteorologists, oceanographers etc.
2) When dealing with simulated data, have contact to modellers.
3) When testing new method, begin with simulation data.