CLN QA/QC efforts CCNY – (Barry Gross) UMBC- (Ray Hoff) Hampton U. (Pat McCormick) UPRM- (Hamed Parsiani)

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Presentation transcript:

CLN QA/QC efforts CCNY – (Barry Gross) UMBC- (Ray Hoff) Hampton U. (Pat McCormick) UPRM- (Hamed Parsiani)

Outline “Raw” signal tests. –Matchups against Rayleigh –Linearity tests with ND filters Member processing algorithms Efforts to test algorithms for consistency Indirect (Downstream) tests for retrieval accuracy Potential QA/QC efforts for CLN

Testing multi-wavelength lidar signals to the molecular reference Lidar System Calibration Regression at km Representative matching of lidar profiles with Molecular profiles

Good linearity! NDF-1 (OD=1.6) at 12:56 pm NDF-2 (OD=1.0) at 12:59 pm Lidar signal profiles Lidar signal ratio Lidar signal linearity: signal profiles and their ratios

CCNY Processing Standard processing for 355 and 532 channels using Fernald Back-Integration method with S ratio pinned by AERONET AOD closure Far end Scattering Ratio Condition (1.01 at 355nm, 1.06 at 532 nm) Zmax determined by “minimum signal” method 1064 channel uses system constant based on cirrus cloud calibration

CCNY Lidar Algorithm and Cross-Testing Efforts Different algorithms tested against each other. –Intercompare iterative and Fernald solutions Consistency check –Compare Measured Signal with Retrieved Signal after optical property retrieval 1064 channel system constant evaluation over long time periods Indirect assessment of standard Mie and Raman optical properties using thin Cloud Optical Depth retrievals. Some preliminary cross-matchups with UPRM.

Validation (1) Fernald vs Iterative Range Blue=exact Fernald Green=iterative approximations N=2 N=5 N=10 N=20

Validation (2) Consistency Check Comparison of theoretical and Measurement Signal 532nm 355 nm Errors <.3%

Long term stability and evaluation of Lidar System Ratio

Indirect Check of Optical Property retrieval using Cloud Optical Depth Raman COD retrieval based on successful derivation of cloud extinction and integrating Mie COD based on S. Young regression method and uses aerosol backscatter corrections above and below cloud Clear sky for aerosol backscatter correction to COD

Cross-Testing of Retrieval Algorithms on same Data CCNY Processing UPRM Processing

Extra slides

Test of lidar signal linearity at 355-nm 1.Time and date: 1256PM--1259PM, April 21, Method:  Insert the different Neutral density Filters (NDF) in front of interference filter and PMT.  Background level is calculated from the average of last 5-km lidar raw data. Mean and standard deviation are given.  Signal ratios are calculated with the different NDFs. Their ratios should be the constant if both two signals are in the linear ranges.  All data are the 2-min average lidar signal profiles. please note: ignore the variability of atmosphere and laser power. 3. For the NDF, higher optical density (OD) values correspond to the LOWER transmittances.