Testing of Objective Analysis of Precipitation Structures (Snowbands) using the NCAR Developmental Testbed Center (DTC) Model Evaluation Tools (MET) Software.

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Presentation transcript:

Testing of Objective Analysis of Precipitation Structures (Snowbands) using the NCAR Developmental Testbed Center (DTC) Model Evaluation Tools (MET) Software Sara A. Ganetis Ph.D. Candidate School of Marine and Atmospheric Sciences Stony Brook University 14 March 2016

Objective Analysis of Precipitation Structures using the NCAR Developmental Testbed Center (DTC) Model Evaluation Tools (MET) Software v Dec 2010 East Coast winter storm test case -- MODE Reflectivity structures ranged in scale including small convective cells meso-β bands large meso-α primary snowband Goal: Tune MODE to objectively identify objects across all scales for observational dataset

Objective Analysis of Precipitation Structures using the NCAR Developmental Testbed Center (DTC) Model Evaluation Tools (MET) Software v. 5.0 Step 1: MATLAB to NetCDF Input data: NCState stitched radar composite MATLAB files of ~5-minute 1 km AGL reflectivity on a 2-km x 2-km grid MATLAB script converts MATLAB file to NetCDF while retaining all grid information Step 2: Format file for Model Evaluation Tools (MET) Method for Object-based Diagnostic Evaluation (MODE) use Perl script to add the necessary global and variable attributes that MODE requires, such as time in EPOCH units Step 3: Run MODE After tuning the following parameters, MODE is run to identify objects raw_thresh = 28 dBZ; conv_radius = 1 grid unit; conv_thresh = >= 15.0; vld_thresh = 0.75; area_thresh = NA; inten_perc_value = 100; inten_perc_thresh = NA; merge_thresh = >= 1.25; merge_flag = NONE; Step 4: Reformat text output (Perl script) and plot (NCL)

Band Aspect Ratio (AR) ≤ 0.75 Cell Area ≤ 2500 km 2 and 0.75 < AR < 1.00 Undefined Area > 2500 km 2 and AR > 0.75 Reflectivity

Band Aspect Ratio (AR) ≤ 0.75 Cell Area ≤ 2500 km 2 and 0.75 < AR < 1.00 Undefined Area > 2500 km 2 and AR > 0.75 Reflectivity

Objective Analysis of Precipitation Structures using the NCAR Developmental Testbed Center (DTC) Model Evaluation Tools (MET) Software v Dec 2010 East Coast winter storm test case -- MODE Strengths Objects are separated out from each other, i.e. not clustered into one large object Length, width, area, and centroid location information is readily available for each object Weaknesses Large number of objects are identified, which makes working with the data more difficult Tracking individual objects between time steps must be done manually

Objective Analysis of Precipitation Structures using the NCAR Developmental Testbed Center (DTC) Model Evaluation Tools (MET) Software v. 5.1 Tests of MODE Time Domain (MTD) Goal: objectively identify, track, and get spatial information about precipitation structures of varying scales MTD configuration grid_res = 2; ⦁ raw_thresh= >=27.0; conv_radius = 1.0; ⦁ conv_thresh = >=27.0; vld_thresh = 0.75; ⦁ area_thresh = NA; inten_perc_value = 100; ⦁ inten_perc_thresh = NA; merge_thresh = >=1.25; ⦁ merge_flag = NONE; min_volume = 25; Edits done to MTD code Added length and width 2d text output by editing the following files: 2d_moments.cc / 2d_moments.h 2d_att.cc mtd_file_int.cc / mtd_file_int.h

Band Aspect Ratio (AR) ≤ 0.75 Cell Area ≤ 2500 km 2 and 0.75 < AR < 1.00 Undefined Area > 2500 km 2 and AR > 0.75 Reflectivity

Object ID # Features are being clustered into a single object

Band Aspect Ratio (AR) ≤ 0.75 Cell Area ≤ 2500 km 2 and 0.75 < AR < 1.00 Undefined Area > 2500 km 2 and AR > 0.75 Reflectivity

Object ID # Features are still being mostly clustered into a single object

Objective Analysis of Precipitation Structures using the NCAR Developmental Testbed Center (DTC) Model Evaluation Tools (MET) Software v Dec 2010 East Coast winter storm test case -- MTD Strengths Objects are organized and tracked within a case Length, width, area, and centroid location information is readily available for each object Weaknesses Less separation between objects as compared to MODE, in fact no separation in the snapshots provided on the previous slides, thus rendering the length/width/area/centroid location information faulty Next steps Test of the “one config. setup fits all band sizes” approach by tuning for larger bands, mid- sized multi-bands and small-scale cells separately Potentially use MODE data instead of MTD for information about the degree of bandedness within each case, instead of gaining information about the tracking and evolution of objects Apply similar methods to WRF data