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E. Fishbein, E. Fetzer , S. Friedman, S-Y Lee and B. Kahn

Climate Data Record Assessments for the Cross-track Infrared Microwave Sounder Suite Analysis of ATMS EDRs. E. Fishbein, E. Fetzer , S. Friedman, S-Y Lee and B. Kahn. Conclusions. Fix the microwave retrieval first! Cloud-clearing can not recover from a bad microwave retrieval

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E. Fishbein, E. Fetzer , S. Friedman, S-Y Lee and B. Kahn

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  1. Climate Data Record Assessments for the Cross-track Infrared Microwave Sounder SuiteAnalysis of ATMS EDRs E. Fishbein, E. Fetzer, S. Friedman, S-Y Lee and B. Kahn

  2. Conclusions • Fix the microwave retrieval first! • Cloud-clearing can not recover from a bad microwave retrieval • c2is dominated by residuals in near-surface channels and is a poor indicator of profile quality. • Scene-dependent EOF representation of profiles introduces unphysical vertical and horizontal structures • Strive to produce measurements which reflect information content of observations

  3. Global Comparisons with ECMWFTemperature Global statistics on microwave retrieved temperature compared with ECMWF (ATMS-ECMWF) Mean Differences − proxy for accuracy • No significant bias below 3 hPa • ECMWF assimilates NOAA-19 BTs • NOAA19 is practically in the same orbit • Minimal temperature bias near tropopause Standard deviation − proxy for precision • 2K difference across the region of sensitivity • Increases to 3K near surface Tropopause • MW temperature profile IP • No Q//C applied, but makes no difference • 17 Oct 2012

  4. Zonal Comparisons with ECMWFTemperature Zonal-height temperature cross-section comparisons • Large mean differences above 1 hPa shows effects a simplistic background • This prevents interpretation of regions with little information • Lack of rippling in standard deviation points to a correlated error source • Large vertical rippling consequence of EOF vertical representation • Representation of the tropopause • Basic properties of the tropopause • Equatorial tropopause is higher, lower temperature, sharper minimum • Polar tropopause is lower, warmer temperatures and weak minimum • A retrieved profile with limited vertical resolution smoothes minima producing a warm bias • Global ensemble doesn’t show warm bias because of “climatology-added” information adds a “climatological tropopause” • Warm bias follows tropopause from equator to pole EOF representations are not conducive to producing climate data records Mean Standard Deviation

  5. Global Comparisons with ECMWFWater Vapor Global statistics on microwave retrieved water vapor compared with ECMWF • ECMWF water vapor is less reliable than temperature, especially in upper troposphere • ATMS has little information about water vapor above 400 hPa. • Jump in standard deviation arises from hard constraint on saturation Hard-constraints should be replaced by penalty functions or find source of anomalous water vapor • Percentages are calculated relative to global-mean ECMWF vertical profile • 17 Oct 2012 Caveat op emptor

  6. Zonal Comparisons with ECMWF Zonal-height water vapor cross-section comparisons • The effect of saturation hard constraint is primarily located in the tropics above 300 hPa • Polar to equator increase in bias reflects not sensitivity and dryer tropical tropopause relative to mid-latitude and poles • Possible radiance forward model or background solution and covariance matrix could be source of problem Fix RTA or background is preferred over hard constraints. Mean Standard Deviation

  7. Global Distribution of χ2 • c2axis is log • MW is dominated by residuals in low-noise near surface channels • Roughly 20% of footprints are contained in tail with c2> 30 • Precipitation does not affect 20% of observations Log10 (c2)

  8. Temperature Quality Control Using c2 • How well is χ2 a predictor of temperature quality? • Temperature statistics, compared with ECMWF conditioned on χ2 • Statistics are not conditional on χ2except at large χ2and near the surface. • Vertical rippling doesn’t depend on χ2 • Mean difference (accuracy) degrades at larger χ2 χ2 is not a useful predictor of quality and probably never will be Mean Standard Deviation

  9. Water Vapor Quality Control Using c2 • Water vapor statistics, compared with ECMWF conditioned on χ2 • No obvious relation between χ2 and except at high χ2 values • Clamped high saturation is filtering on χ2, but nothing else • Once this is fixed other problems will be more evident • When the retrieval is unstable, the final product is biased. • High χ2 correlated with clamped 300 hPa water vapor is a good indicator that background covariance matrix to too tight for background state Mean Standard Deviation

  10. Atmospheric Representation Projection of retrieval parameters on the vertical coordinate against geophysical parameters on the horizontal axis • Using EOFs has the advantage of producing a “good-looking” profile with a minimal number of EOFs. • Using EOFs adds climatology to the resulting products with little control • EOFs transfer information from a region of the atmosphere where CrIMSS has information to where it does not • For example for ATMS, • Water vapor above 400 hPa • Temperature above 2 hPa • Bayesian algorithms control the amount of climatology entering the final solution, but EOF’s negate this control • MW surface emissivity is represented with EOFs, but a physical MW model should be used over ocean • IR emissivity and reflectivity are represented by hinge points, • not enough and no physical emissivity model over ocean • Reflectivity representation needs further evaluation Water vapor vertical representation functions

  11. Atmospheric Representations Tropical Temperature Comparisons of ATMS and ECMWF Equatorial Swath Maps • Above tropopause ATMS temperature does not show spatial variability arising from mesoscale variability • Variability could be shallow and confined to tropopause transition zone (ATMS would not be sensitive) • Retrieval uses difference EOF representation over land and water • 4K bias between land and water (even inland lakes) 1.5 km above the surface is not realistic 100 hPa 800 hPa ATMS ECMWF

  12. Atmospheric Representations Tropical • Filtering on χ2,shows precipitation regions, except χ2 are not that high • EOF representation propagates information where there isn’t any 10 hPa 100 hPa 500 hPa ATMS ECMWF

  13. Conclusions EOFs used in atmospheric representation lead to unphysical vertical correlations not supported by measurements c2is dominated by residuals in near-surface channels and is a poor indicator of profile quality. EOF representation of surface emissivity provides poor constraints on scan-angle and channel dependence

  14. Water Vapor Channel Residuals

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