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Quality control. John Derber NCEP/EMC Reference slide at end. Quality Control - General. Quality control in data assimilation is used to ensure that the analysis is not degraded by the inclusion of certain observations
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Quality control John Derber NCEP/EMC Reference slide at end
Quality Control - General • Quality control in data assimilation is used to ensure that the analysis is not degraded by the inclusion of certain observations • Good quality control also often requires knowledge of the details the instrument design and processing system • Quality control can be applied by removing observations from analysis or by adjusting observation errors for observations • An infinite observation error in the same as removing an observation • Monitoring is enhanced if observation is used in analysis, but weight is zero. • Quality control requires monitoring of data and has significant impacts on the design of the database. • Quality control is extremely important, but not recognized.
Observation errors • For random observation errors should be Gaussian. • Reasons for non-random errors • Representativeness error • Inability of forward model to properly model observation • Instrument Difficulties
Observation errors • For random observation errors should be Gaussian.
Representativeness error • Models do not resolve all scales of the atmosphere. • Observations often are point measurements • When structures are observed which cannot be resolved – representativeness error. • Observation is correct – but does not represent the structures in the analysis • Example – Radiosonde launched in local thunderstorm used for large scale analysis
Inability of forward model to properly model observation • If forward model transforming analysis variables into observation variables cannot properly simulate observation • Example – cloudy radiances from satellite when only simulating clear radiances • Example 2 – not including CO2 in retrieval process – errors created at scales of CO2 variation • Observations correct, but errors introduced which can be aliased into analysis
Satellite data • Most simulation problems with satellite data come from 5 sources: • Instrument problems. • Inadequate characterization • Degrading instrument • Inadequately measured/modelled components of forward model. • Inadequately understood physics
Satellite radiances • IR cannot see through clouds. • Cloud height can be difficult to determine – especially with mixed FOVs. • Since measures deep layers, not many channels completely above clouds. • Microwave impacted by clouds and precipitation but signal is smaller from thinner clouds and can be modeled. • Surface emissivity and temperature characteristics not well known for land/snow/ice. • Also makes detection of clouds/precip. more difficult over these surfaces. • Error distribution may be asymmetric due to clouds and processing errors.
Instrument Difficulties • If the instrument is fails – observations usually not good (by definition) • Instrument design • ascending/descending aircraft • Non-Gaussian errors – Scatterometer ambiguity • Insufficient sensitivity – GPS RO • Monitoring vital to detect problems • Surface data examples
Mismatch between top planetary boundary layer Model BA exceeds limit for observation Below, obs rejected by QC
Instrument Difficulties • If the instrument is fails – observations usually not good (by definition) • Instrument design • ascending/descending aircraft • Non-Gaussian errors – Scatterometer ambiguity • Insufficient sensitivity – GPS RO • Monitoring vital to detect problems • Surface data examples
Quality control usually has multiple steps • Choice of observations used in analysis • Physically realistic? • Pressure > 0, Moisture > 0, Surface observation < 500mb, etc. • Complex quality control – attempting to save observations • Station monitoring – Blacklist • Must have capability to add/remove stations from list • Manual QC – Human intervention • Greatly complicates operational system • Instrument specific checks based on instrument design • Variational QC (replaces buddy check)
Variational quality control • Modifies weight given observation based on deviation from guess/analysis • Assumes that observation error is not Gaussian. • Examples – Assume error PDF is Gaussian + constant • Examples – Assume error PDF is sum of Gaussians • Will make minimization non-linear – will generally slow convergence and may create multiple minima. • Generally makes weight a function of how close the data is to current solution – solution should be close to final solution
Correlated errors • If observational errors are correlated – all parts of quality control must be rethought • Nearby obs may have same signal because of real signal or correlated errors. • Can be extremely difficult to distinguish correlated error • Correlated errors occur because of • Instrument/forward model biases • Retrievals from multiple observations spreads errors across all components of retrieval
Data Monitoring • It is essential to have good data monitoring. • Usually the NWP centres see problems with instruments prior to notification by provider (Met Office especially). • The data monitoring can also show problems with assimilation systems. • Needs to be ongoing/real time. • https://groups.ssec.wisc.edu/groups/itwg/nwp/monitoring
AIRS Channel 453 26 March 2007 Quality Monitoring of Satellite Data Increase in SD Fits to Guess
Summary • Quality control is a very important (but under-recognized) component of data assimilation • Often performed in multiple steps – platform dependent and cross-platform components • Inclusion of quality control within analysis can be done (variational QC) and is being done at operational centres. • However, variational QC significantly complicates minimization • Much QC work not documented in literature
References Andersson, E., and H. Jarvinen, 1999: Variational quality control Quart. J. Reoy. Meteor. Soc., 125, 697-722 – See also ECMWF tech memo #250. Baker, Nancy L., 1994: Quality control of meteorological observations at Fleet Numerical Meteorology and Oceanography Center, U.S. Navy, Naval Research Laboratory,23p. Collins, W. G., 2001: The operational complex quality control of radiosonde heights and temperatures at the National Centers for Environmental Prediction. Part I: Description of the Method, Jour. of App. Meteor.,40.2, 137-151. European Centre for Medium Range Weather Forecasts, WMO/ECMWF Workshop on Data Quality Control Procedures, Reading, England, March 6-10, 1989, Papers., Reading, England, European Centre for Medium-Range Weather Forecasts (ECMWF), 1989 Gandin, Lev S., 1988: Complex quality control of meteorological observations, Mon.Wea.Rev.116. 1137-1156. Ingleby, Nbruce, Lorenc, Andrew C., 1993, Bayesian quality control using multivariate normal distributions, Quart. J. Roy. Met. Soc, 119, 1195-1225. Kelly, G; Andersson, E; Hollingsworth, A; Loennberg, P; Pailleux, J; et al.; 1991: Quality control of operational physical retrievals of satellite sounding data, Mon. Wea. Rev.,1866-1880. Lorenc, A.C., and Hammon, O., 1988: Objective quality control of observations using Bayesian methods – Theory, and a practical implementation Quart. J. Roy. Met. Soc. 114, 515-543. Purser, R.J., 2011: Mathematical principles of the construction and characterization of a parameterized family of Gaussian mixture distributions suitable to serve as models for the probability distributions of measurement errors in nonlinear quality control, NCEP Office Note #468. Various ECMWF lectures and training courses.
