Cross-Calibrating OSCAT Land Sigma-0 to Extend the QuikSCAT Land Sigma-0 Climate Record

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Cross-Calibrating OSCAT Land Sigma-0 to Extend the QuikSCAT Land Sigma-0 Climate Record David G. Long Department of Electrical and Computer Engineering Brigham Young University May 2013 0

Scatterometer Resolution Enhancement σ 0 imaging SIR/AVE for OSCAT Beta version of OSCAT enhanced resolution land/ice products now available at the Scatterometer Climate Record Pathfinder (www.scp.byu.edu) Conventional Resolution SIR Enhanced Resolution db Wind from σ 0 Ultra-high resolution (UHR) (1.25 km/pixel) OSCAT ASCAT wind processing now operational OSCAT includes near-land, and sea-ice wind retrieval Conventional Resolution Ultra-High Resolution 1

Ice Contamination Mitigation for QuikSCAT and OSCAT Model: Ice Contribution Ratio (ICR) Monte Carlo simulation to set wind error threshold on ICR of each sigma0 measurement Wind speed/direction Ice backscatter intensity Cross-track location Sea ice prior probability map Discard high ICR sigma0s prior to retrieval 2

Ice Contamination Wind Mitigation Eliminates ice winds and enables retrieval nearer to sea ice Similar to near-land approach, but using Bayes sea ice maps Both L2B and UHR winds available in BYU product Retrieves winds on average 30 km closer to sea-ice edge than conventional L2B winds (which are nominally 50 km from the ice edge) W.J. Hullinger and D.G. Long, Mitigation of Sea Ice Contamination in QuikSCAT Wind Retrieval, IEEE Transactions on Geoscience and Remote Sensing, to appear, 2013. 3

OSCAT SRF Estimates from Island targets H-pol Slices H-pol Egg V-pol Egg J.P. Bradley and D.G. Long, "Estimation of the OSCAT Spatial Response Function Using Island Targets", IEEE Transactions on Geoscience and Remote Sensing, to appear, 2013. 4

Scatterometer Climate Record Pathfinder (SCP) Standard Regions (OSCAT images) Lambert Equal Area, Polar Stereographic Projection EASE grid Compatible grids for ERS-1/2, NSCAT, SeaWinds/QuikSCAT, OSCAT, ASCAT1/2, SSM/I, AMSRE 5

OSCAT/QuikSCAT Differences for the Land/Ice Scatterometer Climate Record Orbit geometry Orbit revisit time (Q=4 day repeat, O=2 day repeat) Observation azimuth angles differ and vary with time Time of orbit ascending node differ QuikSCAT=6:30 am OSCAT=noon Measurement incidence angle H: QuikSCAT=46, OSCAT=48 V: QuikSCAT=54, OSCAT=56 Instrument azimuth gain variation Cross calibration parameters Incidence angle Azimuth angle Local time of day 6

Cross-calibration over Land & Ice Goal: Determine a correction factor to apply to OSCAT land/ice images to enable extension of QuikSCAT time series Correct azimuth prior to image formation Otherwise, use ocean-calibrated OSCAT sigma-0s Fixed calibration offset + incidence angle correction applied post-image formation Question: Is this simple cross-calibration scheme adequate for extending the land/ice scatterometer climate record? 7

Greenland & Scatterometer Calibration Evaluate locations within the dry snow zone of Greenland for calibrating scatterometers using the 10-year long QuikSCAT data set. K.R. Moon and D.G. Long, Considerations for Ku-band scatterometer calibration using the dry snow zone of the Greenland ice sheet, IEEE Geoscience and Remote Sensing Letters, to appear, 2013. Dry snow zone extent and average sigma-0. Note significant variability in spatial extent Seasonal cycle of sigma-0 within dry snow zone 8

Greenland Summer Melt During the Summer of 2012, Greenland endured one of the largest areal melt cycle observed in the satellite record. The melt event was recorded by OSCAT and ASCAT. False color RGB images from a single day of Ku-band data (Oceansat-2 H=Red, V=Grn) and C-band data (ASCAT=Blu). Land shows up as pink-grey. Deep melt is the green. Surface melt is red. Refrozen melt is bright white. Unmelted firn is dark grey/blue. This event affects future calibration activities in this region. 9

Amazon Study Region Rain forest is a good calibration target (anisotropic), but exhibits spatial inhomogeneity Select homogenous region Time-of-day variation Sigma-0 varies with time of day as moisture moves up/down in canopy Several tenths of a db effect OSCAT and QuikSCAT observe at different local times Different incidence angles Select region that both QuikSCAT and OSCAT sigma-0 fall within narrow range 10

Amazon rainforest Egg Sigma-0 vs Azimuth Angle 11

Amazon rainforest Azimuth-Corrected Egg Sigma-0 vs Azimuth Angle 12

Comparison of Corrected Sigma-0 Distribution in Amazon Study Region H-pol bias 0 db V-pol bias 0.25 db 13

Amazon rainforest Slice Sigma-0 vs Azimuth Angle 14

Amazon rainforest Az-Corrected Slice Sigma-0 vs Azimuth Angle 15

Comparison of Corrected Slice Sigma-0 Distribution in the Amazon Study Region H-pol bias 0.2 db V-pol bias 0.35 db 16

Rainforest study regions Congo East Amazon West Amazon Homogenous study regions selected with narrow sigma-0 range, low temporal variation 17

Time/Location Dependence of Incidence Angle Difference East Amazon Congo West Amazon 18

Region Distributions different years 19

Region Distributions different years 20

Incidence Angle Bias Maps 21

Incidence Angle Bias Maps 22

Sigma-0 Region Distributions QuikSCAT and OSCAT trends generally follow each other. Differences are primarily due to weather differences between 2009 and 2012 Incidence angle response dependent on terrain, vegetation, as well as soil moisture and freeze-thaw (Gamma normalization applies only for perfectly rough surfaces) Notional plot of sigma-0 versus incidence angle Incidence angle 23

Conclusion QuikSCAT and OSCAT produce very similar land/ice sigma-0 distributions Azimuth angle dependent bias must be removed from OSCAT Mean sigma-0 offsets Egg: Hpol 0.0 db and Vpol 0.25 db Slice: Hpol 0.2 db and Vpol 0.35 db Incidence angle dependence makes it difficult to develop an incidence angle adjustment Get close 24

OSCAT Enhanced Resolution Antarctic Image Enhanced resolution OSCAT image, 2 Nov 2012 Selected major icebergs circled Daily tracking of icebergs using OSCAT data is continuing 25

BYU Summary David Long Paper on scatterometer calibration in Greenland accepted, IEEE Geoscience and Remote Sensing Letters Paper on OSCAT spatial response function estimation accepted, IEEE Trans. Geoscience and Remote Sensing Beta version OSCAT land, ice, & UHR wind processing running at BYU Have processed entire OSCAT data set available to images: www.scp.byu.edu Regularly extracting and reporting iceberg positions from OSCAT image data in Near Real Time (NRT) Enhanced resolution ASCAT1/2 and OSCAT UHR hurricane and NRT polar ice processing BYU code ported to NOAA. Installed and in use. 26

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