How to Apply the AATSR VIS-SWIR Calibration Corrections 1 Background
Transcription
How to Apply the AATSR VIS-SWIR Calibration Corrections 1 Background
How to Apply the AATSR VIS-SWIR Calibration Corrections Dave Smith and Caroline Poulsen Contact: dave.smith@stfc.ac.uk Last updated: 23/11/2010 1 Background Three modifications to the AATSR VIS-SWIR calibration processing have been implemented by the operational processing since the launch of ENVISAT in 2002. 14-December-2004 - 1.6um non-linearity correction introduced (PO-TN-RAL-AT-0540). This was traced to an error in the general calibration file (GC1) that did not properly implement the known non-linearity effects in the 1.6um channel that was measured during pre-launch testing. The problem was fixed by a modification to the GC1 file. All L1b data processed after 14th December 2004 has the non-linearity correction applied. 29-November-2005 – Exponential Drift Correction is applied to VC1 files (PO-TN-RAL-AT0542). This correction was based on the first two years of data aquired over stable desert and ice targets using the method described in Smith et al. 2002. For the early phase of the mission the calibration trend followed an exponential decay function as predicted from the experience of ATSR-2, AVHRR etc. such that D(t) = exp(-kt). 18-December-2006 – Thin Film Drift Correction is introduced to VC1 files (PO-TN-RAL-AT0552). This correction was implemented post 2005 to account for results that showed that the exponential decay model was incorrect in the case of the AATSR visible channels. The observed long term trends suggest that the drift is caused by a thin-film interference effect (Etalon) of the form D(t) = 1+Asin2(2πnxt/λ) (where n is the refractive index and x is the thickness) Although the ‘thin film’ model provided a reasonable representation of the observed drift, analysis showed that a simple parametric model could not adequately account for all variations in the measured drift. So, instead of a parametric model to obtain the drift correction, a smoothed average of the drift measurements are used to provide a drift correction table. Before applying the ‘improved’ drift correction, it is essential to remove any previous non-linearity corrections to avoid over compensating the drift. This is described in Smith et al 2008. 2 Do I need to apply a drift correction? Yes! if you are using ANY (MERCI RAL etc...) ESA provided AATSR lv1b product then you should be applying the following drift correction. The current correction applied to the data is a predicted correction decided at a time early in the mission. Careful drift monitoring has shown that the drift is not easily predicted and needs constant monitoring. The drift correction is constantly being improved and updated so users are advised to use the latest drift correction and to store in the processed data the calibration table used. 3 Drift Correction Table and Tools The latest version of the AATSR drift correction table and tools can be found at any of the following locations: • The AATSR engineering data system http://aatsr2.ag.rl.ac.uk/EDSX/OtherInfo/ in the Visible Calibration Information link • The NEODC ATSR on-line archive http://www.neodc.rl.ac.uk/?option=displaypage&Itemid=91&op=page&SubMenu=9 1 • The CEOS Cal-Val portal http://calvalportal.ceos.org/cvp/web/guest/aatsr-envisat The AATSR drift correction table is regularly updated and the latest calibration file stored here. If you would like to be regularly updated with the latest calibration file please email Dave Smith. This folder contains plots of the latest derivation of the drift correction as well as comparisons with MERIS visible channels. The folder also contains the IDL code needed to apply the corrections. Details on how to apply the drift correction are outlined below. We ask that users provided some evidence that show the improvements to retrievals as a result of the calibration corrections being applied to the data. This could simply be some before and after trends with some accompanying text (e.g. Aerosol trends). This is to support our service in maintaining the AATSR visible calibration tables on behalf of ESA and will ultimately go towards improving the quality of the calibration corrections for AATSR. 4 Methodology An example of how to apply the corrections is given in the IDL function AATSR_APPLY_CORRECTIONS.PRO. It is important to implement the corrections in the right sequence as described below. 1) Apply the non-linearity correction to the 1.6um channel data if not already done so using the function AATSR_CORRECT_V16_NONLINEARITY.PRO with the call IDL> V16_CORRECTED = AATSR_CORRECT_V16_NONLINEARITY (GC1_FILENAME, V16_UNCORRECTED) Where: GC1_FILENAME - String containing name of GC1 filename associated with L1B product DSD32 in product V16_UNCORRECTED - Variable containing 1.6um reflectance values from L1B product. The value(s) must be in the range 0-1 2) In order to implement the ‘improved’ long term drift correction it is necessary to remove any previous corrections where they had been applied by the processor. This is done by using the IDL function AATSR_REMOVE_DRIFT_CORRECTION.PRO with the call IDL> UNCORRECTED_REFLETCANCE = AATSR_REMOVE_DRIFT_CORRECTION(VC1_FILENAME, ACQ_TIME, ICH, REFLECTANCE) Where: VC1_FILENAME - String containing name of VC1 filename associated with L1B product DSD31 in product ACQ_TIME - String containing acquistion time of product - format = DD-MMM-YYYY HH:MM:SS ICH - Integer Variable Containing Channel Number to be processed 0 = 555nm 1 = 659nm 2 = 870nm 3 = 1600nm REFLECTANCE - Variable containing reflectance reading from L1B product 3) Use drift correction look up table to obtain the drift measurement for a given channel and acquisition using the function AATSR_APPLY_DRIFT_CORRECTION.PRO with the call IDL> CORRECTED_REFLECTANCE = AATSR_APPLY_DRIFT_CORRECTION(ACQ_TIME,ICH,UNCORRECTED_REFLECTA NCE,DRIFT_TABLE=DRIFT_TABLE) Where: ACQ_TIME - String containing acquistion time of product - format = DD-MMM-YYYY HH:MM:SS ICH - Integer Variable Containing Channel Number to be processed 0 = 555nm 1 = 659nm 2 = 870nm 3 = 1600nm UNCORRECTED_REFLECTANCE - Variable containing reflectance reading DRIFT_TABLE - If specified, a structure containing the drift look up table The drift correction table can be read into an IDL structure using the function AATSR_READ_DRIFT_TABLE.PRO with the call IDL> NTAB = AATSR_READ_DRIFT_TABLE(DRIFT_TABLE) 5 Additional Functions In addition to the drift correction procedure described above, there are some additional functions that allow the reflectance data to be rescaled to a different reference, e.g. AATSR to MERIS. SCALE_ATSR2_TO_AATSR.PRO Scales ATSR2 reflectance values to AATSR using biases measured by intercomparisons over deserts This routine applies an offset correction and assumes a normalised radiance NOT scaled to cos(sza) in the range 0-1. The call is IDL> CORRECTED_REFLECTANCE = SCALE_ATSR2_TO_AATSR(ICH,UNCORRECTED_REFLECTANCE) Where: ICH - Integer Variable Containing Channel Number to be processed 0 = 555nm 1 = 659nm 2 = 870nm 3 = 1600nm UNCORRECTED_REFLECTANCE - Variable containing reflectance reading SCALE_AATSR_TO_MERIS.PRO Scales AATSR (or ATSR-2) reflectance values to MERIS using biases measured by intercomparisons over deserts (Smith et al 2008) using the call IDL> CORRECTED_REFLECTANCE = SCALE_AATSR_TO_MERIS(ICH,UNCORRECTED_REFLECTANCE) Where: ICH - Integer Variable Containing Channel Number to be processed 0 = 555nm 1 = 659nm 2 = 870nm UNCORRECTED_REFLECTANCE - Variable containing reflectance reading 6 References Smith, D. L., C. T. Mutlow, and C. R. N. Rao, (2002). “Calibration monitoring of the visible and near-infrared channels of the Along-Track Scanning Radiometer-2 by use of stable terrestrial sites.” Appl. Opt., 41, p515—523. Smith D.L. and Poulsen C.A., 2008, “Calibration Status of the AATSR Reflectance Channels”, Proceedings of MERIS/AATSR Workshop Smith, D.L., 2008, PO-RP-RAL-AT-0599 , “Final Report on Multi-Mission Calibration Study”, Envisat project document. 7 Acknowledgements This works has been funded by ESA under the Multi-Mission Vicarious Calibration -Contract No. 23011-09-I-OL