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A Survey of Observers for Nonlinear Dynamical Systems Read chapter Read first chapter

2013 | OriginalPaper | Chapter

19. All-Sky Satellite Radiance Data Assimilation: Methodology and Challenges

Author : Milija Zupanski

Published in: Data Assimilation for Atmospheric, Oceanic and Hydrologic Applications (Vol. II)

Publisher: Springer Berlin Heidelberg

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Abstract

Assimilation of satellite radiances is the backbone of today’s operational data assimilation. Satellites can cover all parts of globe and provide information in areas not accessible by any other observation type. Of special interest are high-impact weather areas, such as tropical cyclones and severe weather outbreaks, which are mostly covered by clouds. Unfortunately, in current operational practice only clear-sky satellite radiances are assimilated, with only few exceptions. This effectively filters out a potentially useful information from all-sky radiances related to clouds and microphysics, and consequently limits the utility of satellite data. In this paper we will address numerous challenges related to the use of all-sky satellite radiances.All-sky satellite radiances present a formidable challenge for data assimilation as they relate to numerous technical aspects of data assimilation such as: (1) forecast error covariance, (2) correlated observation errors, (3) nonlinearity and non-differentiability, and (4) non-Gaussian errors. Assimilation of all-sky radiances is also challenging from a dynamical/physical point of view, since observing clouds implies a need for better understanding and ultimately simulation of cloud microphysical processes. Given that a reliable prediction of clouds requires a high-resolution cloud-resolving model, assimilation of all-sky radiancesis also a high-dimensional problem that requires addressing computational challenges.

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previous chapter Entropic Balance Theory and Radar Observation for Prospective Tornado Data Assimilation
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Appendix
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Literature
Abramov RF, Majda AJ (2004) Quantifying uncertainty for non-Gaussian ensembles in complex systems. SIAM J Sci Comput 26:411–447CrossRef
Anderson JL (2003) A local least squares framework for ensemble filtering. Mon Wea Rev 131:634–642CrossRef
Auligne T, Lorenc A, Michel Y, Montmerle T, Jones A, Hu M, Dudhia J (2011) Toward a new cloud analysis and prediction system. Bull Am Meteorol Soc 92:207–210CrossRef
Axelsson O (1994) Iterative solution methods. Cambridge University Press, Cambridge, p 668CrossRef
Axelsson O, Barker VA (1984) Finite-element solution of boundary-layer problems. Theory and computations. Academic Press, Orlando, p 432
Bauer P, Geer A, Lopez P, Salmond D (2010) Direct 4D-Var assimilation of all- sky radiances. Part I: implementation. Q J Roy Meteorol Soc 136A:1868–1885CrossRef
Bauer P, Lopez P, Salmond D, Benedetti A, Saarinen S, Moreau E (2006) Implementation of 1D + 4D-Var assimilation of precipitation-affected microwave radiances at ECMWF. II: 4D-Var. Q J Roy Meteorol Soc 132:2307–2332CrossRef
Bauer P, Ohring G, Kummerow C, Auligne T (2011) Assimilating satellite observations of clouds and precipitation into NWP models. Bull Am Meteorol Soc 92:ES25–ES28CrossRef
Bocquet M, Pires CA, Wu L (2010) Beyond Gaussian statistical modeling in geophysical data assimilation. Mon Wea Rev 138:2997–3023CrossRef
Cover TM, Thomas JA (2006) Elements of information theory, 2nd edn. Wiley, Hoboken, 776 pp
Daley R (1993) Atmospheric data analysis. Cambridge University Press, Cambridge, 472 pp
Dee DP, Uppala S (2009) Variational bias correction of satellite radiance data in the ERA-Interim reanalysis. Q J Roy Meteorol Soc 135:1830–1841CrossRef
Errico RM, Ohring G, Bauer P, Ferrier B, Mahfouf J-F, Turk J, Weng F (2007a) Assimilation of satellite cloud and precipitation observations in numerical weather prediction models: introduction to JAS special collection. J Atmos Sci 64:3737–3741CrossRef
Errrico RM, Bauer P, Mahfouf JF (2007b) Issues regarding the assimilation of cloud and precipitation data. J Atmos Sci 64:3785–3798CrossRef
Evensen G (2003) The ensemble Kalman filter: theoretical formulation and practical implementation. Ocean Dyn 53:343–367CrossRef
Evensen G (2009) Data assimilation: the ensemble Kalman filter. Springer, Berlin/Heideberg, p 307
Evensen G, van Leeuwen PJ (2000) An ensemble Kalman smoother for nonlinear dynamics. Mon Wea Rev 128:1852–1867CrossRef
Fertig EJ, Hunt BR, Ott E, Szunyogh I (2007) Assimilating non-local observations with a local ensemble Kalman filter. Tellus 59A:719–730
Fletcher SJ, Zupanski M (2006a) A hybrid normal and lognormal distribution for data assimilation. Atmos Sci Lett 7:43–46CrossRef
Fletcher SJ, Zupanski M (2006b) A data assimilation method for log-normally distributed observational errors. Q J Roy Meteorol Soc 132:2505–2519CrossRef
Fletcher SJ, Zupanski M (2008) Implications and impacts of transforming lognormal variables into normal variables in VAR. Met Zeit 16:755–765CrossRef
Gaspari G, Cohn SE (1999) Construction of correlation functions in two and three dimensions. Q J Roy Meteorol Soc 125:723–757CrossRef
Geer A, Bauer P, Geer A, Lopez P (2010) Direct 4D-Var assimilation of all- sky radiances. Part II: assessment. Q J Roy Meteorol Soc 136A:1886–1905CrossRef
Geer A, Bauer P (2010) Enhanced use of all-sky microwave observations sensitive to water vapour, cloud and precipitation. ECMWF Tech Memorandum 620:41
Golub GH, and van Loan CF (1989) Matrix computations. The John Hopkins University Press, Baltimore, p 642
Gordon NJ, Salmond DJ, Smith AFM (1993) Novel approach to nonlinear/non-Gaussian Bayesian state estimation. IEE Proc 140:107–113
Gu Y, Oliver DS (2007) An iterative ensemble Kalman filter for multiphase fluid flow data assimilation. SPE J 12:438–446
Haarala M, Miettinen K, Makela MM (2004) New limited memory bundle method for large-scale nonsmooth optimization. Optim Meth Softw 19:673–692CrossRef
Hamill T, Whitaker J, Snyder C (2001) Distance-dependent filtering of background error covariance estimates in an ensemble Kalman filter. Mon Wea Rev 129:2776–2790CrossRef
Harris BA, Kelly G (2001) A satellite radiance-bias correction scheme for data assimilation. Q J Roy Meteorol Soc 127:1453–1468CrossRef
Houtekamer P, Mitchell H (2001) A sequential ensemble Kalman filter for atmospheric data assimilation. Mon Wea Rev 129:123–136CrossRef
Huang X-Y, et al (2009) Four-dimensional variational data assimilation for WRF: formulation and preliminary results. Mon Wea Rev 137:299–314CrossRef
Jazwinski AH (1970) Stochastic processes and filtering theory. Academic, San Diego, 376 pp
Kalnay E (2003) Atmospheric modeling, data assimilation and predictability. Cambridge University Press, Cambridge, 341 p
Karmitsa N, Bagirov A, Makela MM (2012) Comparing different nonsmooth minimization methods and software. Optim Meth Softw 27:131–153CrossRef
Kullback S, Leibler RA (1951) On information and sufficiency. Annals Math Stat 22:79–86CrossRef
Lewis JM, Lakshmivarahan S, Dhall SK (2006) Dynamic data assimilation: a least squares approach. Cambridge University Press, Cambridge, 680 p
Li Z, Navon IM (2001) Optimality of 4D-Var and its relationship with the Kalman filter and Kalman smoother. Q J Roy Meteorol Soc 127:661–684CrossRef
Lorenc AC (1986) Analysis methods for numerical weather prediction. Q J Roy Meteorol Soc 112:1177–1194CrossRef
Luenberger DL (1989) Linear and non-linear programming. Addison-Wesley, Reading, 491 pp
Navon IM (1986) A review of variational and optimization methods in meteorology. In: Sasaki YK (ed) Variational methods in geosciences. Developments in Geomathematics, vol 5. Elsevier Science Publishers, Amsterdam, pp 29–35
Nocedal J (1980) Updating quasi-Newton matrices with limited storage. Math Comp 35:773–782CrossRef
Okamoto K, Derber JC (2006) Assimilatioon of SSM/I radiances in the NCEP global data assimilation system. Mon Wea Rev 134:2612–2631CrossRef
Parrish DF, Cohn SE (1985) A Kalman filter for a two-dimensional shallow- water model: formulation and preconditioning experiments. Office Note 304, National Meteorological Center, Washington, DC
Parrish DP, Derber JC (1992) The national meteorological center’s spectral statistical interpolation analysis system. Mon Wea Rev 120:1747–1763CrossRef
Polkinghorne R, Vukicevic T (2011) Data assimilation of cloud-affected radiances in a cloud-resolving model. Mon Wea Rev 139:755–773CrossRef
Shannon CE, Weaver W (1949) The mathematical theory of communication. University of Illinois Press, Urbana, 144 pp
Simon E, Bertino L (2009) Application of the Gaussian anamorphosis to assimilation in a 3-D coupled physical-ecosystem model of the North Atlantic with the EnKF: a twin experiment. Ocean Sci 5:495–510CrossRef
Stephens GL (1994) Remote sensing of the lower atmosphere. Oxford University Press, New York, p 544
Steward JL (2012) On a unifying interpretation of empirically-determined square-root background error covariance matrices for variational and ensemble data assimilation. JPL Earth Science Seminar, Pasadena
Steward JL, Navon IM, Zupanski M, Karmitsa N (2012) Impact of non-smooth observation operators on variational and sequential data assimilation for a limited-area shallow-water equation model. Q J Roy Meteorol Soc 138:323–339CrossRef
Thepaut J-N, Courtier P, Belaud G, Lemaitre G (1996) Dynamical structure functions in a four-dimensional variational assimilation: a case study. Q J Roy Meteorol Soc 122:535–561CrossRef
van Leeuwen PJ (2009) Particle filtering in geophysical systems. Mon Wea Rev 137:4089–4114CrossRef
Vukicevic T, Greenwald T, Zupanski M, Zupanski D, VonderHaar T, Jones AS (2004) Mesoscale cloud state estimation from visible and infrared satellite radiances. Mon Wea Rev 132:3066–3077CrossRef
Wang X, Hamill TM, Whitaker JS, Bishop CH (2007) A comparison of hybrid ensemble transform Kalman filter-OI and ensemble square-root filter analysis schemes. Mon Wea Rev 135:1055–1076
Wu W-S, Purser RJ, Parrish DF (2002) Three-dimensional variational analysis with spatially inhomogeneous covariances. Mon Wea Rev 130:2905–2916CrossRef
Xiong X, Navon IM, Uzunoglu B (2006) A note on the particle filter with posterior Gaussian resampling. Tellus 58A:456–460
Yang W, Navon IM, Courtier P (1996) A new Hessian preconditioning method applied to variational data assimilation experiments using adiabatic version of NASA/GEOS-1 GCM. Mon Wea Rev 124:1000–1017CrossRef
Zhang S, Zupanski M, Hou A, Lin X, Cheung S (2012) Assimilation of precipitation- affected radiances in a cloud-resolving WRF ensemble data assimilation system. Mon Weather Rev. doi:10.1175/MWR-D-12-00055.1 (in press)
Zupanski M (1993) A preconditioning algorithm for large scale minimization problems. Tellus 45A:578–592
Zupanski M (1995) A preconditionin algorithm for four-dimensional variational data assimilation. Mon Wea Rev 124:2562–2573CrossRef
Zupanski M (2005) Maximum likelihood ensemble filter: theoretical aspects. Mon Wea Rev 133:1710–1726CrossRef
Zupanski D, Mesinger F (1995) Four-dimensional variational assimilation of precipitation data. Mon Wea Rev 123:1112–1127CrossRef
Zupanski M, Navon IM, Zupanski D (2008) The maximum likelihood ensemble filter as a non-differentiable minimization algorithm. Quart J Roy Meteorol Soc 134:1039–1050CrossRef
Zupanski D, Zupanski M, Grasso LD, Brummer R, Jankov I, Lindsey D, Sengupta M, DeMaria M (2011a) Assimilating synthetic GOES-R radiances in cloudy conditions using an ensemble-based method. Int J Remote Sens 32:9637–9659CrossRef
Zupanski D, Zhang SQ, Zupanski M, Hou AY, Cheung SH (2011b) A prototype WRF-based ensemble data assimilation system for downscaling satellite precipitation observations. J Hydromet 12:118–134CrossRef
Metadata
Title
All-Sky Satellite Radiance Data Assimilation: Methodology and Challenges
Author
Milija Zupanski
Copyright Year
2013
Publisher
Springer Berlin Heidelberg
Book
Data Assimilation for Atmospheric, Oceanic and Hydrologic Applications (Vol. II)

Print ISBN: 978-3-642-35087-0

Electronic ISBN: 978-3-642-35088-7

Copyright Year: 2013

DOI
https://doi.org/10.1007/978-3-642-35088-7_19

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