update on galactic noise correction joe tenerelli smos quality working group # 9 esa esrin

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UPDATE ON GALACTIC NOISE CORRECTION Joe Tenerelli SMOS Quality Working Group # 9 ESA ESRIN 24 October 2012. PLAN. Briefly r eview the problem of scattered galactic radiation. Show impact on retrieved salinity . Review the seasonal dependence of the signal. - PowerPoint PPT Presentation

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UPDATE ON GALACTIC NOISE CORRECTION

Joe TenerelliSMOS Quality Working Group #9

ESA ESRIN24 October 2012

PLAN

1. Briefly review the problem of scattered galactic radiation. Show impact on retrieved salinity.

2. Review the seasonal dependence of the signal.

3. Look at the impact of the simple specular reflection solution. Motivate development of more complicate scattering models.

4. Review the performance and problems with the pre-launch Kirchhoff scattering model, focusing on descending passes.

5. Introduce development of empirically fit geometrical optics models. Show differences between models derived from ascending and descending passes.

6. Compare distributions of SSS biases for the various models as a function of scattered galactic brightness.

Faraday rotation

Cosmic+Galactic(up to 8 K after scattering)

scattering by rough surface

atm absorption(trans = 0.995)

atm absorption(trans = 0.995)

atm emission(2 K)

atm emission(2 K)

specular (100 K) +rough (10 K) surface emission

Galactic radiation incident from all directions

(Tx+Ty)/2

(Tx+Ty)/2 bias +1 K SSS bias -2 psu

SEASONAL AND PASS DIRECTION VARIATION

5 m/s

SCATTERING OF GALACTIC RADIATION

April 2 Sep 20June 25

SEASONAL AND PASS DIRECTION VARIATION

April 2Sep 20June 25

SEASONAL AND PASS DIRECTION VARIATION

IMPACT OF CELESTIAL SKY BRIGHTNESSAveraging the scattered celestial sky brightness along alias-free portions of dwell lines:

No correction for reflected celestial sky radiation leads to strong along-track bands of negative SSS anomalies:

IMPACT OF CELESTIAL SKY BRIGHTNESS

No correction for reflected celestial sky radiation leads to strong along-track bands of negative SSS anomalies:

IMPACT OF CELESTIAL SKY BRIGHTNESS

No correction for reflected celestial sky radiation leads to strong along-track bands of negative SSS anomalies:

IMPACT OF CELESTIAL SKY BRIGHTNESS

No correction for reflected celestial sky radiation leads to strong along-track bands of negative SSS anomalies:

IMPACT OF CELESTIAL SKY BRIGHTNESS

Correction assuming a specular surface:

IMPACT OF CELESTIAL SKY BRIGHTNESS

Correction assuming a specular surface:

IMPACT OF CELESTIAL SKY BRIGHTNESS

The preceding Kirchhoff formulation (using the Kudryavtsev wave spectral model) undercorrects for the celestial sky radiation, leaving a noticable along-track band of negative SSS bias (or high brightness temperature bias):

IMPACT OF CELESTIAL SKY BRIGHTNESS

Initial fix for commissioning phase reprocessing was to use the ‘least rough’ Kirchhoff solution available, corresponding to a 10-m wind speed of 3 m/s. This significantly reduced the along-track bands of negative SSS bias, but some noticable banding remains:

Take high-frequency limit of the Kirchhoff approximation for scattering cross sections:

Obtain expression in terms of slope probability distribution:

Assume Gaussian slope probability distribution. Then fit the slope variance:

GEOMETRICAL OPTICS GALACTIC MODEL

1. Use reconstructed brightness temperatures over the alias-free field of view

2. Correct for running-averaged OTT. OTT based upon descending passes in first half of year and ascending passes in second half of year, to avoid large influence of galactic radiation upon OTTs.

3. Removal AF-FoV averaged bias as derived from time-latitude bias evolution.

4. Subtract model predicted brightness temperature, excluding contribution from celestial sky brightness.

5. Project resulting ‘residual’ brightness temperatures into a regular 1ox1o grid in celestial coordinates.

6. Use all data from June 2010-July 2012. Fit model on ascending and descending passes separately.

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: APPROACH

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: ASCENDING PASSES

SMOS residuals

Example geometrical optics trial solutions

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: ASCENDING PASSES

SMOS residuals

Example geometrical optics trial solutions

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: ASCENDING PASSES

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: ASCENDING PASSES

IMPACT OF CELESTIAL SKY BRIGHTNESS

Reflected radiation for ascending passes in March not as strong as for descending passes in Sep/Oct:

IMPACT OF CELESTIAL SKY BRIGHTNESS

Scattered radiation for ascending passes in March also not as strong as that for descending passes in Sep/Oct:

IMPACT OF CELESTIAL SKY BRIGHTNESS

IMPACT OF CELESTIAL SKY BRIGHTNESS

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

SMOS residuals

Example geometrical optics trial solutions

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

SMOS residuals

Example geometrical optics trial solutions

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

COMPARING THE ASC AND DESC MSS FITS

• At high incidence angles, optimal mean square slopes for descending passes are lower than those for ascending passes. Discrepancy is largest at 50o incidence angle (where the GO fit is most problematic).

• At low incidence angles, the opposite is true.

• Change occurs somewhere between 20o and 40o incidence angle.

AN EXAMPLE OF THE FIT

40o incidence angleDescending passes

6-8 m/s ECMWF surface wind speedfirst Stokes parameter: (Tx+Ty)/2

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

Descending SMOS

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

Descending geometrical optics model

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

Descending geometrical optics model

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

Kirchhoff model at 3 m/s

LOWER SURFACE WIND SPEED

40o incidence angleDescending passes

3-6 m/s ECMWF surface wind speedfirst Stokes parameter: (Tx+Ty)/2

LOWER SURFACE WIND SPEED

Descending geometrical optics model

Kirchhoff model at 3 m/s underpredicts scattered brightness along galactic plane and overpredicts it on either side.

LOWER SURFACE WIND SPEED

Kirchhoff model at 3 m/s

COMPARING ASCENDING AND DESCENDING GEOMETRICAL OPTICS MODEL FITS

40o incidence angleDescending passes

3-6 m/s ECMWF surface wind speedfirst Stokes parameter: (Tx+Ty)/2

COMPARING ASC AND DESC GO MODELS

Descending Empirical GO model – SMOS derived (Tx+Ty)/2:

Ascending empirical GO model underpredicts scattered celestial sky brightness along the galactic plane and overpredicts it on either side:

Ascending Empirical GO model – SMOS derived (Tx+Ty)/2:

COMPARING ASC AND DESC GO MODELS

Descending pass empirical GO model predictsA more sharply peaked distribution of scattered celestial sky noise:

Descending - Ascending Empirical GO model

COMPARING ASC AND DESC GO MODELS

ORIENTATION ANGLE DEPENDENCE

surface

scattering cross sections

galactic brightness

A possible explanation for descending-ascending differences in scattered galactic radiation for a given specular point…

ORIENTATION ANGLE DEPENDENCE

The brightness incident at antenna for any given specular point depends upon orientation of the incidence plane.

Models predict this and the data also suggest such a dependence.

IMPACT OF THE ORIENTATION ANGLE

SPECULAR REFLECTION OF THE GALAXY AT VERY LOW ECMWF 10

METER WIND SPEEDS

IMPACT OF CELESTIAL SKY BRIGHTNESSIn some cases it appears that the galactic radiation is specularly reflected at ECMWF surface wind speeds below 2-3 m/s. But this is not always the case:

IMPACT OF CELESTIAL SKY BRIGHTNESS

Green circles: evidence of specular reflection of galactic radiation

OVERALL MODEL PERFORMANCE

Compile statistics on the SSS error obtained with each galactic model over a rectangular lat-lon domain from 50oS to 20oN latitude and from 180o to 110oW longitude.

Desc: Sep/Oct 2010-2012

Asc: Mar/Apr 2011-2012

OVERALL MODEL PERFORMANCEDistribution of samples as function of scattered celestial sky brightness temperature for descending passes in September/October 2010-2012:

OVERALL MODEL PERFORMANCEDistribution of samples as function of scattered celestial sky brightness temperature for descending passes in September/October 2010-2012:

OVERALL MODEL PERFORMANCE

Descending passes, very low ECMWF surface wind speeds:

OVERALL MODEL PERFORMANCE

Descending passes, light-moderate ECMWF surface wind speeds:

OVERALL MODEL PERFORMANCE

Descending passes, moderate ECMWF surface wind speeds (most likely case):

OVERALL MODEL PERFORMANCE

Distribution of error for descending passes in September/October 2010-2012:Comparing the descending pass GO and the Kirchhoff model at 3 m/s.

OVERALL MODEL PERFORMANCE

Distribution of error for descending passes in September/October 2010-2012:Comparing the descending and ascending pass empirical GO models.

OVERALL MODEL PERFORMANCE

Distribution of error for descending passes in September/October 2010-2012:Comparing the descending pass GO and the Kirchhoff-3 model for high scattered celestial sky brightness.

CONCLUSIONS: GALACTIC MODEL1. Model for scattering of celestial sky brightness has been under continual

refinement.

2. Originally proposed Kirchhoff scattering model using the Kudryavtsev wave spectrum strongly underpredicts the scattered brightness near the galactic plane and overpredicts the brightness away from the galactic plane under most surface wind speeds.

3. Kirchhoff scattering model evaluated at surface wind speed of 3 m/s better predicts the scattered brightness under most wind conditions, but still underpredicts brightness near galactic plane at low wind speeds, and overpredicts brightness at high wind speeds. Lack of wind speed dependence is unrealistic.

4. Semi-empirical models based upon geometrical optics produce improved predictions relative to those based on Kirchhoff and retain wind speed dependence.

5. Geometrical optics fits to the data are different for ascending and descending passes, possibly due to inaccurate representation of scattering cross sections away from specular direction. Possible solution is to introduce ascending and descending lookup tables for scattered celestial sky brightness.

OVERALL MODEL PERFORMANCE

Distribution of error for ascending passes in March/April 2011-2012:Comparing the ascending pass GO and the Kirchhoff model at 3 m/s for high scattered celestial sky brightness.

OVERALL MODEL PERFORMANCE

Distribution of error for ascending passes in March/April 2011-2012:Comparing the descending and ascending pass empirical GO models for high scattered celestial sky brightness.

• Appears clearly in global maps of monthly mean AF-FoV first Stokes parameter bias (descending-ascending).

• Latitudinal drift apparent towards the end of every year.

• Seasonal drift in latitudinally averaged bias.

BRIGHTNESS TEMPERATURE DRIFT

• Impact upon global maps of salinity bias (descending-ascending) is clearly evident.

• Latitudinal drift apparent towards the end of every year.

• Seasonal drift in latitudinally averaged bias.

BRIGHTNESS TEMPERATURE DRIFT

BRIGHTNESS TEMPERATURE DRIFTTime-latitude structure of the AF-FoV bias over the mission lifetime:

BRIGHTNESS TEMPERATURE DRIFTEvaluating the long-term drift of first Stokes parameter (averaged over large latitude range in southern hemisphere).

Descending passes: 1-Slope, Calibrated L1, JRECON (1-slope)

Over 1 K drop in (Tx+Ty)/2 towards the end of the year for both 1-slope model and the new ‘calibrated L1’ approach!

BRIGHTNESS TEMPERATURE DRIFTEvaluating the long-term drift of first Stokes parameter (averaged over large latitude range in southern hemisphere).

Ascending passes: 1-Slope, Calibrated L1, JRECON (1-slope)

Over 1 K drop in (Tx+Ty)/2 towards the end of the year for both 1-slope model and the new ‘calibrated L1’ approach!

BIAS TRENDS: NIR ANTENNA TEMPERATURE• Compare drift in latitudinally averaged NIR antenna temperatures to

corresponding AF-FoV averaged drift.

• Modify latitude range for averaging to avoid impact from land and ice at high latitudes.

• Account for sun impact on antenna temperatures. Especially important for descending passes late in the year.

BIAS TRENDS: NIR ANTENNA TEMPERATURE• Compare drift in latitudinally averaged NIR antenna temperatures to

corresponding AF-FoV averaged drift.

• Modify latitude range for averaging to avoid impact from land and ice at high latitudes.

• Account for sun impact on antenna temperatures. Especially important for descending passes late in the year.

Big jump in sun L-band Tb from end of 2010 to end of 2011!

BIAS TRENDS: NIR ANTENNA TEMPERATUREBias trends in NIR antenna temperatures similar to AF-FoV trends except for descending passes at the end of 2011:

BIAS TRENDS: NIR ANTENNA TEMPERATUREBias trends in NIR antenna temperatures similar to AF-FoV trends except for descending passes at the end of 2011:

OTT EVOLUTION

reference

OTT EVOLUTION

reference

OTT EVOLUTION

reference

OTT EVOLUTION

reference

OTT EVOLUTION

reference

CONCLUSIONS: DRIFT

1. Reconstructed brightness temperatures obtained from the first ESA reprocessing using the 1-Slope loss model, exhibit a strong drop of over 1 K in (Tx+Ty)/2 in

EXTRA SLIDES

BIAS TRENDS

BIAS TRENDS

BIAS TRENDS

BIAS TRENDS

BIAS TRENDS

BIAS TRENDS

The Kirchhoff integral in the previous equation is an integral over the surface

Kirchhoff kernel which is a function only of incident and scattered wave directions and polarization

Surface correlation function

PRE-LAUNCH KIRCHHOFF MODEL

The correlation function is computed from Kudryavtsev wave spectrum evamuated using ECMWF 10-m wind speed.

• Scattering up to 40o away from specular direction can contribute to total scattered brightness.

• Geometrical optics model rapidly becomes inaccurate beyond about 15o from the specular direction.

GEOMETRICAL OPTICS GALACTIC MODEL

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: ASCENDING PASSES

SMOS residuals

Example geometrical optics trial solutions

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: ASCENDING PASSES

SMOS residuals

Example geometrical optics trial solutions

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

SMOS residuals

Example geometrical optics trial solutions

FITTING A GEOMETRICAL OPTICS MODEL TO THE DATA: DESCENDING PASSES

SMOS residuals

Example geometrical optics trial solutions

A MORE DIFFICULT EXAMPLE OF THE FIT

50o incidence angleDescending passes

3-6 m/s ECMWF surface wind speedfirst Stokes parameter: (Tx+Ty)/2

A MORE DIFFICULT EXAMPLE OF THE FIT

As derived from the SMOS brightness temperatures:

As modeled using the descending empirical GO model:

A MORE DIFFICULT EXAMPLE OF THE FIT

Empirical GO model – SMOS derived (Tx+Ty)/2:

Model prediction of scattered brightness is too low either side of galactic plane

A MORE DIFFICULT EXAMPLE OF THE FIT

Original Kirchhoff at 3 m/s – SMOS derived (Tx+Ty)/2:

But the original Kirchhoff model, even using the solution at the lowest wind speed of 3 m/s, strongly underpredicts the maximum scattered brightness:

A MORE DIFFICULT EXAMPLE OF THE FIT

9 m/s

SCATTERING OF GALACTIC RADIATION

IMPACT OF CELESTIAL SKY BRIGHTNESS

Correction assuming a specular surface:

HIGHER SURFACE WIND SPEED

40o incidence angleDescending passes

8-12 m/s ECMWF surface wind speedfirst Stokes parameter: (Tx+Ty)/2

HIGHER SURFACE WIND SPEED

Empirical GO model – SMOS derived (Tx+Ty)/2:

Original Kirchhoff at 3 m/s – SMOS derived (Tx+Ty)/2:

Kirchhoff model at 3 m/s overpredicts scattered brightness along galactic plane and underpredicts it on either side.

HIGHER SURFACE WIND SPEED

IMPACT OF CELESTIAL SKY BRIGHTNESS

No correction for reflected celestial sky radiation leads to strong along-track bands of negative SSS anomalies:

IMPACT OF CELESTIAL SKY BRIGHTNESS

Ascending GO model does not completely eliminate low SSS trough

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