Contents:
I. File Naming Conventions
II. Header Information
III. Data Records
IV. Data File Specifics
V. Data Quality Control
VI. Important Note to Users
VII. Contacts


I. File Naming Conventions

The "QC CLASS" files are typically one-second data files with appropriate corrections and 
and quality control measures applied.  The naming convention for most 
of these files is the same - "D", followed by  "yyyymmddhhmmQC.cls" where yyyy =  year,
mm = month, hh = hour of the day GMT, mm = minute of the hour,   
and "QC.cls" refers to the quality controlled NCAR CLASS format. 


II. Header Information

The header records contain data type, project ID, site ID, site location, actual release time, 
nominal release time, and possibly other specialized information.  The first five header lines 
contain information identifying the sounding, and have rigidly defined form.  The following
6 header lines contain auxiliary information and commments about the sounding, and they can
vary from data set to data set. The last 3 header records contain header information for the
data columns.  Line 13 holds the field names, line 14 the field units, and line 15 contains
dashes (--- characters) signifying the end of the header.

The six standard header lines are as follows:

Line  Label  (fixed to 35 chars in length)                  Contents

1. Data Type:					   Description of type and resolution of 
						   data.
2. Project ID:					   ID of weather project.
3. Launch Site Type/Site ID:			   Description of launch site.
4. Launch Location (lon,lat,alt):		   Position of launch 
5. GMT Launch:                                     Time of release, in format:
						   yyyy, mm, dd, hh:mm:ss

The release location is given as : lon (deg min), lat (deg min), lon (dec. deg), lat (dec. deg), 
alt (m).

Longitude in deg min is in the format: ddd mm.mm'W where ddd is the number of degrees from True 
North (with leading zeros if necessary), mm.mm is the decimal number of minutes, and W represents 
represents W or E for west or east longitude, respectively. Latitude has the same format as 
longitude, except there are only two digits for degrees and N or S for north/south latitude.
The decimal equivalent of longitude and latitude and station elevation follow.

The six non-standard header lines may contain any label and contents.  The label is fixed to 
35 characters to match the standard header lines.


III. Data Records

The data records each contain time from release, pressure, temperature, dew point, relative 
humidity, U and V wind components, wind speed and direction, ascent rate, balloon position
data, altitude, and quality control flags.  

Field                   Parameter                     Units                 Missing Value
 No. 
------------------------------------------------------------------------------------------

 1			Time                         Seconds		     9999.0
 2 			Pressure		     Millibars               9999.0
 3			Dry-bulb Temp		     Degrees C  	      999.0
 4			Dew Point Temp 		     Degrees C		      999.0
 5			Relative Humidity            Percent                  999.0
 6			U Wind Component             Meters/Second            999.0
 7			V Wind Component  	     Meters/Second            999.0
 8			Wind Speed		     Meters/Second	      999.0
 9			Wind Direction		     Degrees		      999.0
 10			Ascension Rate		     Meters/Second            999.0
 11			Longitude		     Degrees		      999.0
 12			Latitude		     Degrees		      999.0
 13		        Range			     Kilometers               999.0	
 14			Angle			     Degrees		      999.0
 15 			Altitude		     Meters		    99999.0
 16			QC flag for Pressure                                   99.0
 17			QC flag for Temp				       99.0
 18 			QC flag for Humidity                                   99.0
 19			QC flag for U Component                                99.0
 20			QC flag for V Component				       99.0
 21			QC flag for Horizontal Wind			       99.0


IV. Data File Specifics 

The files contain data calculated at one-second intervals . The variables
pressure, temperature, and relative humidity are calibrated values from
measurements made by the sonde.  The dew point is calculated from the relative
humidity. The altitude value is calculated from the hydostatic equation using
pressure, temperature, and dew point.  The rate of ascent is obtained from 
the altitude difference between two successive time steps.  The position
(lat, lon), angle and range come from the GPS and altitude data. This data
is interpolated to one second in order to match the wind data.

All wind data are computed from GPS navigation signals received from the sonde.  The
raw wind values are calculatd at a one half second data rate by a commercial processing
card.  These raw values are subjected to a digital filter to remove low frequency oscillations
due to the sonde pendulum motion beneath the balloon. The resolution of the data is reduced to one
second.  This time record is used in the interpolation of the pressure, temperature, and 
humidity data. 


V. Data Quality Control

The raw soundings are first run through the Atmospheric Sounding Processing
ENvironment (ASPEN), which analyzes the data, performs smoothing, and removes
suspect data points.  The soundings are then visually evaluated for
outliers, or any other obvious problems. Scatter plots of the data are
then created to check for discrepencies between PTU data collected from the 
surface met station and data from the radiosonde. Lastly, we create profiles of 
temperature, RH, and dewpoint  (one plot per flight) in order to check  
any major inconsistencies found. 


VI. Important Note to Users. 

While visually analyzing the skew-t diagrams from the CR1 (Costa Rica mobile 1) 
system it became apparent that there were problems near the surface. The data 
collected from the surface met temperature and humidity sensors are much warmer 
(mean diff=3.1 degC) and drier (mean RH diff = 9.19%) than the pre-launch data 
collected from the radiosondes. We attribute these errors to a couple of factors.
First, a hand held device was bought from a local store to make surface
pressure, temperature, and humidity measurements (rather than the surface met 
sensors typically used by ATD). Secondly, the sondes were launched  by non-ATD staff.
Thirdly, it is unknown how they made the surface measurements, i.e. under direct
sunlight, under shaded area or right above heated surfaces.  Those conditions could
have affected the measurements.   
We believe improper handling of the surface instrument  was most 
likely the cause because we did not see the same errors from the CR2 surface 
instrument that was operated by ATD staff, who did not expose the surface sensor 
direct heat. We  recommend that the users do not use the surface met temperature,
RH, and dewpoint measurements from the first line in the data file for all
CR1 soundings.  We suggest that users use the prelaunch data collected by the 
radiosonde sensor (second line in the data at 0 second) as the surface value. 

In addition, for 9 of the 73 radiosondes launched by the mobile 1 (CR1), we suspect
that the operators failed to push the sonde launch button which prompts the system
to begin recording data. This error resulted in a loss of data between the surface 
and approximately ~750-800 mb.  The files affected are:

D200303020704QC.cls   D200303100918QC.cls   D200303181151QC.cls   
D200303181752QC.cls   D200303191222QC.cls   D200303080913QC.cls   
D200303180851QC.cls   D200303181451QC.cls   D200303191158QC.cls


VII. Contacts:
			Junhong Wang
			junhong@ucar.edu

			Kate Beierle
			kbeierle@ucar.edu

			Tim Lim
			tdlim@ucar.edu



Mailing Address:        NCAR/Atmospheric Technology Division
			P.O Box 3000
	        	1850 Table Mesa Drive
			Boulder, CO 80307; USA