Download - Task 3: Management Activities
ECMWF Summer SeminarsSeptember 2011
Task 3: Management Activities
• Orial Kryeziu recruited started June 18th
• September coupled DA workshop• Chris Old recruited starting 1st October• Weekly Skype meetings Reading and Edinburgh
started 1st October
• Outline• Chris Old: Background on SST in Reanalyses and
Observations• Orial Kryeziu: Progress on extending SST matchups • Chris Old: Uncertainty in SST products for Coupled
Data Assimilation
Task 3: Deliverables
• KO+ 9 months D6 (initial): A current reanalysis assessment report identifying case study periods and showing areas where coupled model improvements may be expected
• KO+15 months D7: Documentation for Opensource Visualisation software and demonstrator presenting comparisons between ocean and atmosphere reanalysis products using the observation operator codes developed for assimilation, and observations, particularly near ocean surface, for scientific and outreach use
• KO+24 months D6 (final): An final impact assessment report based on Task 1, WP3.3 and 3.4 studies, describing improved representations of coupled phenomena and improved fitting to observational data.
Satellite SST in Coupled Data Assimilation
Chris Old and Chris MerchantSchool of GeoSciences, The University of Edinburgh
ESA Data Assimilation Projects, Progress Meeting 111th December 2012, The University of Reading
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OBSERVATION vs MODEL INCONSISTENCIES
Satellite SST in Coupled Data Assimilation
Introduction 6
Satellite SST in coupled data assimilation
Task 3: Evaluating observation strategies
The key objective of this task is to review the correlated variability of surface oceanic and atmospheric datasets, both within the coupled model systems and with the observations themselves. These results will provide input to the development of a set of test experiments (Task 4), by identifying suitable test periods and data sets.
WP3.1 Consistency of current surface ocean and atmospheric analysis products
Use satellite measurements as a baseline to examine any inconsistencies within the products, e.g. regions where there are discrepancies in SSTs between atmosphere and ocean products, such as regions where strong (or weak) SST diurnal cycles are detected but where the analysed surface wind speeds seem too high (or low).
Introduction 7
Observed SST Diurnal Variability
Solar heating produces near surface thermal stratification, while wind driven mixing erodes diurnal stratification.
Modification of instantaneous air-sea heat flux from warm-layer formation can be 50 Wm-2.
Amplitude of cycle often observed up to 4K, larger events are observed (>6K).
dSST excursions spatially and temporally coherent.
dSST event magnitude and horizontal length scale anti-correlated.
Extreme dSST maxima arise where low wind speed sustained from early morning to mid-afternoon.
Observed dSST between 9AM and 2PM on 2nd June 2006. Data from the SEVIRI instrument on MSG2.
References: Gentemann et al., 2008; Merchant et al., 2008
Introduction 8
Methodology
First stage in the process is to look for instances of discrepancy between observed and simulated diurnal SSTs.
Use SST data retrieved from SEVIRI on MSG2 to calculate observed diurnal SST.
Simulate diurnal SST using a statistical model based on ERA wind and heat flux fields.
Use the difference between observed and simulated dSST to identify regions of inconsistency between model fields and observations.
Apply this test to a long time series of model fields and observations to determine current state of modelling capability.
Use the results to identify a set of suitable data periods that can be used test the performance of the new coupled assimilation systems being developed.
Methodology 9
Statistical Model for dSST
tc
tWtbtatQtD 21
tQ
tW
Integrated heat flux during warming period
Maximum 10m wind speed during warming period
Reference: Filipiak et al., 2012
Constructed using ERA40 reanalysis atmosphere data and SST retrieved from SEVIRI data.
tD Diurnal SST difference for a time t after start of warming
tctbta ,, Coefficient functions ( LUTs )
Methodology 10
Application to ALADIN DW database
Calculate observed dSSTobs between 9am and 2pm (local solar time)
Exclude pixels with in 0.2° of land (land surface temperature contamination)
Exclude pixels where SDI > 0.5 at any point during the day (dust contamination)
Exclude pixels where dSSTobs < -1.4K (cloud contamination)
Calculate dSSTsim using statistical model (based on NWP reanalysis fields)
Calculate Δ(dSST) = dSSTobs- dSSTsim
Locate peak values where |Δ(dSST)| > 1.5K (threshold of significant difference)
Locate all pixels around peak where |Δ(dSST)| > 1.0K (identify coherent regions)
Eliminate regions that are too small (fewer than 40 points)
Δ(dSST) > 1.5K modelled wind fields too large
Δ(dSST) < -1.5K modelled wind fields too weak
Methodology 11
Example of method – 2nd June 2006
SEVIRI Statistical Model(ERA Interim Fields)
Methodology 12
Observed - Modelled dSST – 2nd June 2006
Case 1: Wind speed too large
Case 2: Wind speed too low
Case3: Wind field offset
Observed – Modelled dSST difference ( K )
Methodology 13
Inconsistent regions – 2nd June 2006
Methodology 14
ERA 40 compared with ERA Interim
Using ERA40 data Using ERA Interim data
Sea Surface Diurnal Warming
Orial Kryeziu, Keith HainesDiurnal Warming: sub-daily variations in sea surface temperature (SST) defined
relative to the temperature prior to diurnal stratification (foundation temperature).
Achievements:
Implemented diurnal warming observation operator codes for ERA40, ERAInterim and ALADIN and compared with SEVIRI data
Extended search area to include full SEVERI disk data (June 2006), data obtained Apr 2006 – Sept 2008
Obtained ERAInterim 3 hourly wind data based on interleaved forecasts, to test sensitivity of diurnal SST Observation operator code
Initiated dialogue with ECMWF on incorporating surface wave data into diurnal model
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- The SST data are hourly observations from SEVIRI spanning -100°W to 45°E and -60°S to 60°N mapped on a 0.05° resolution grid. Currently, data is available for one month: June 2006. Also available from SEVIRI is the “Saharan dust index” (SDI)- non-dimensional index based on infra-red wavelengths. - Peak-to-peak mean amplitude in dSST for the ocean as whole is 0.25 K. Largest dSSTs exceed 6K, and affect 0.01% of the surface (Filipiak et al., 2012).
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Winds fields (ERA-interim, 3 hourly) derived from a numerical prediction model (NWF) are obtained from ECMWF. The winds in the western Mediterranean and European Seas are heavily defined by land-sea contrasts and orographic effects. Diurnal warming cases occur frequently in this region.The picture shows the mean of the reciprocal of the wind speed between 0900 and 1500 h UTC.
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Mean maximum value of dSST here shows correlation with the mean reciprocal of the wind strength. It is useful to consider knowledge of frequent local wind fields to see orographic influences on diurnal variability. For example:- Surface winds accelerated through the Corsica and Sardinia passage (Merchant et al. 2008).- Mistral winds are often responsible for the clear, sunny weather in the Golfe du Lion.
Mistral Wind
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● Extreme cases (>4K) arise under conditions with persistent light winds and strong sunlight.
● Sustained low winds in the morning are rare.
● In the North and Baltic Seas a prevalent factor in diurnal warming is the optical attenuation coefficient of water (Merchant et al. 2008).
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There is an anti-correlation between the magnitude and the length scale of dSST events. Also the scales of areas of sustained low winds are smaller than those of instantaneously low winds. A few examples of dSST>4 (14pm - 9am):
18th of June 2006
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14th of June 2006
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3rd of June 2006
Conclusions: ● Extreme diurnal events (peak dSST > 4K) are observed by
SEVIRI.● In the Mediterranean sea orographic influence is an important
factor. In the North and Baltic Seas, optical attenuation coefficient of water is a (significant ) driving factor.
● Sustained low winds are required for extreme warming events to be observed.
Future work:1) Extend Case criteria to using other near-surface variables:● Sea state information: Wave data from ERAInterim;
Scatterometer and Altimetric satellite data2) Develop uncertainty model for SST L2 coupled reanalysis.
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SSTobs ERROR COVARIANCES
Satellite SST in Coupled Data Assimilation
Observation Error Covariance 26
Uncertainties for SST assimilation
WP3.1 Consistency of current surface ocean and atmospheric analysis products
The space-time sampling of satellite data will be assessed against spatial and temporal variability of the ocean and atmospheric reanalysis fields. This sampling uncertainty will be used in combination with uncertainty components from other sources developed in the ARC SST and SST CCI projects.
Coupled Data Assimilation Workshop :
An understanding and quantification of satellite SST error covariance length scales in time and space can be used to constrain the coupled assimilation of surface fields.
Little work has been done to date to quantify satellite based SST error covariance length scales.
Observation Error Covariance 27
Components of SST uncertainty
• Radiometric noise
• Usually random (but variable)• 1/√n averaging over n pixels
• Algorithmic
• Geographically systematic component• Variable component usually correlated to synoptic scales ( average ≠ 1/√n )
• Sampling
• Spatial sub-sampling (only clear sky) - representativity• Time within diurnal cycle of SST
• Outliers
• cloud, aerosol problems
Observation Error Covariance 28
Radiometric noise
• Noise equivalent differential temperature (NEdT)
NEdT = SD of errors in brightness temperaturesPropagates simply to SST random uncertainty
• Can depend on
Variations in coefficientsChannel setScene temperatureInstrument properties and stateTime (degradation)
• Random uncertainty in SST varies in calculable way between SSTs
cy ySDc
cchannels
cc yax,
ˆ
cchannels
ycrandomsst ca,
2
Observation Error Covariance 29
Algorithmic Errors
Algorithmic limitations in coping with varying atmospheric conditions.
Synoptically correlated in time and space.
Error distributions can be simulated.
+
Radiative Transfer
BTs, y
SSTs, x
Least squares regression
Coefficients, a
x̂ xxSDoa ˆlg
xxavgoa ˆlg
Observation Error Covariance 30
Instantaneoussimulationof retrievalerror
Observation Error Covariance 31
Instantaneoussimulationof retrievalerror
Observation Error Covariance 32
Instantaneoussimulationof retrievalerror
Observation Error Covariance 33
Instantaneoussimulationof retrievalerror
Observation Error Covariance 34
Instantaneoussimulationof retrievalerror
Observation Error Covariance 35
Instantaneoussimulationof retrievalerror
Observation Error Covariance 36
Instantaneoussimulationof retrievalerror
Observation Error Covariance 37
Observation Error Covariance 38
r ~ ( 1/e time scale ) / days
Temporal correlation scales
Observation Error Covariance 39
Meridional Zonal
Approximation to r ~ ( 1/e length scales ) / km
Spatial correlation scales
Observation Error Covariance 40
Error Covariance Work Plan
Proposed approach:
Choice of case study: new AATSR L2P* ( full resolution
product )
• Simulate retrieval error fields
• Calculate covariance information
• Re-grid onto an assimilation grid ( ECMWF input required )
• Can also flag “trusted, independent obs” set for model testing
* Currently being developed at CEMS under NCEO and contains ARC/SST CCI uncertainty information
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References:Gentemann, C. L., P. J. Minnett, P. Le Borgne, C. J. Merchant. 2008. Multi-satellite measurements of large
diurnal warming events. Geophysical Research Letter, 35, L22602
Merchant, C. J., M. J. Filipiak, P. Le Borgne, H. Roquet, E. Autret, J. -F. Piollé, S. Lavender. 2008. Diurnal warm-layer events in the western Mediterranean and European shelf. Geophysical Research Letter, 35, L04601
Filipiak, M. J., C. J. Merchant, H. Kettle, P. Le Borgne. 2012. An empirical model for the statistics of sea surface diurnal warming. Ocean Science, 8, 197-209