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Convert Vaisala CL51, CL31, and CT25K ceilometer dat files to NetCDF

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cl2nc

cl2nc is an open source command-line Python program for converting Vaisala CL51, CL31 and CT25K ceilometer DAT and HIS L2 files to NetCDF.

Example

On the command-line:

cl2nc input.dat output.nc

where input.dat is a Vaisala CL51, CL31, or CT25K DAT file and output.nc is the name of a NetCDF output file.

See cl2nc-examples.zip for examples of input and output.

Installation

It is recommended to run cl2nc on Linux.

Linux

On Debian-derived distributions (Ubuntu, Devuan, ...), install the required system packages with:

sudo apt install python3 python3-pip pipx

On Fedora, install the required system packages with:

sudo yum install python3 pipx

Install cl2nc:

pipx install cl2nc
mkdir -p ~/.local/share/man/man1
ln -s ~/.local/pipx/venvs/cl2nc/share/man/man1/cl2nc.1 ~/.local/share/man/man1/

Make sure that $HOME/.local/bin is included in the PATH environment variable if not already. This can be done with pipx ensurepath.

You should now be able to run cl2nc and see the manual page with man cl2nc.

To uninstall:

pipx uninstall cl2nc
rm ~/.local/share/man/man1/cl2nc.1

macOS

Open the Terminal. Install cl2nc with:

python3 -m pip install cl2nc

Make sure that /Users/<user>/Library/Python/<version>/bin is included in the PATH environment variable if not already, where <user> is your system user name and <version> is the Python version. This path should be printed by the above command. This can be done by adding this line to the file .zprofile in your home directory and restart the Terminal:

PATH="$PATH:/Users/<user>/Library/Python/<version>/bin"

You should now be able to run cl2nc and see the manual page with man cl2nc.

To uninstall:

python3 -m pip uninstall cl2nc

Windows

Install Python 3. In the installer, tick Add python.exe to PATH.

Open Command Prompt from the Start menu. Install cl2nc with:

pip install cl2nc

You should now be able to run cl2nc.

To uninstall:

pip uninstall cl2nc

Usage

cl2nc is a command-line program to be run on a terminal (Linux and macOS) or the Command Prompt (Windows).

Synopsis:

cl2nc [-chqstv] [--debug] input output
cl2nc -h|--help

input is an input .dat or .his (L2) file. output is an output .nc file. If directories are supplied for input and output, all .dat, .DAT, .his and .HIS files in input are converted to .nc files in output.

Options:

  • -c: Enable DAT checksum verification (slow).
  • --debug: Enable debugging output.
  • -h, --help: Show help message and exit.
  • -q: Run quietly (suppress output).
  • -s: Profile sampling rate in seconds for use with files with no timestamps.
  • -t: Initial time as year-month-dayThour:minute:second for use with files with no timestamps.
  • -v: Show program's version number and exit.

On Linux and macOS, see also the manual page with:

man cl2nc

Variables

Please see Vaisala CL51, CL31, or CT25K User's Guide for a complete description of the variables.

The DAT files can alternatively contain values in feet (instead of meters), in which case all values are converted by cl2nc to meters.

Time in DAT and HIS files is assumed to be UTC.

Missing values are encoded as NaN (floating-point variables) or -2147483648 (integer variables). The _FillValue attribute contains the missing value used in the given variable.

DAT files produce the following NetCDF output:

Variable Description Units Dimensions
background_light Background light mV time
backscatter Attenuated volume backscatter coefficient km-1.sr-1 time, level
backscatter_sum Backscatter sum sr-1 time
cbh_1 Lowest cloud base height m time
cbh_2 Second lowest cloud base height m time
cbh_3 Highest cloud base height m time
detection_status Detection status time
highest_signal Highest signal detected time
id Ceilometer identification string time
laser_temperature Laser temperature °C time
layer Layer number layer
layer_cloud_amount Layer cloud amount octas time, layer
layer_height Layer height m time, layer
level Level number level
measurement_mode (CT25K) Measurement mode time
message_number Message number time
message_subclass Message subclass time
pulse_energy Pulse energy % time
pulse_length Pulse length time
pulse_count Pulse count time
receiver_bandwidth Receiver bandwidth time
receiver_gain Receiver gain time
receiver_sensitivity (CT25K) Receiver sensitivity % time
sampling Sampling Hz time
self_check Self check time
sky_detection_status Sky detection status time
software_level Software level ID time
status_alarm Status alarm time
status_internal Status internal time
status_warning Status warning time
tilt_angle Tilt angle degrees time
time Time seconds since 1970-01-01 00:00:00 UTC time
time_utc Time (UTC) ISO 8601 time
unit Unit identification character time
vertical_resolution Vertical resolution m time
vertical_visibility Vertical visibility m time
window_transmission Window transmission estimate % time
window_contamination Window contamination mV time

HIS L2 files produce the following NetCDF output:

Variable Description Units Dimensions
backscatter Attenuated volume backscatter coefficient km-1.sr-1 time, level
ceilometer Ceilometer name time
level Level number level
period Period time
time Time seconds since 1970-01-01 00:00:00 UTC time
time_utc Time (UTC) ISO 8601 time

background_light

Background light (mV)

Millivolts at internal ADC input.

backscatter

Attenuated volume backscatter coefficient (km-1.sr-1)

backscatter_sum

Backscatter sum (sr-1)

Sum of detected and normalized backscatter (0–0.0999 sr-1).

cbh_1

Lowest cloud base height (m)

cbh_2

Second lowest cloud base height (m)

cbh_3

Highest cloud base height (m)

ceilometer

Ceilometer name (HIS L2 variable CEILOMETER).

detection_status

Detection status

  • 0 – no significant backscatter
  • 1 – one cloud base detected
  • 2 – two cloud bases detected
  • 3 – three cloud bases detected
  • 4 – full obscuration determined but no cloud base detected
  • 5 – some obscuration detected but determined to be transparent
  • / – raw data input to algorithm missing or suspect

sky_detection_status

Sky detection status

  • 0-8 – cloud coverage of the first layer in octas
  • 9 – vertical visibility
  • -1 – data missing, sky condition option not active or ceilometer in standby mode
  • 99 – not enough data (after start-up)

highest_signal

Highest signal detected

laser_temperature

Laser temperature (°C)

layer

Layer number

layer_cloud_amount

Layer cloud amount (octas)

Sky condition algorithm.

layer_height

Layer height (m)

Sky condition algorithm.

level

Level number

measurement_mode (CT25K)

Measurement mode

  • N – normal
  • C – close range

message_number

Message number

  • 1 – message without sky condition data
  • 2 – message with sky condition data

message_subclass

Message subclass

  • 6 – 10 m ⨉ 1540 samples, range 15400 m (msg1_10x1540)
  • 8 – without a backscatter profile (msg1_base)

period

Period (HIS L2 variable PERIOD).

pulse_energy

Pulse energy (% of nominal factory setting)

pulse_length

Pulse length

  • L – long (100 ns)
  • S – short

pulse_count

Pulse count

receiver_bandwidth

Receiver bandwidth

  • N – narrow
  • W – wide

receiver_gain

Receiver gain

  • H – high
  • L – low

High by default, may be low in fog or heavy snow.

receiver_sensitivity

Receiver sensitivity (%)

sampling

Sampling (Hz)

self_check

Self check

  • 0 – self-check OK
  • W – at least one warning active, no alarms
  • A – at least one alarm active

software_level

Software level ID

status_alarm

Status alarm

Flags:

  • 0x8000 – transmitter shut-off
  • 0x4000 – transmitter failure
  • 0x2000 – receiver failure
  • 0x1000 – voltage failure
  • 0x0400 – memory error
  • 0x0200 – light path obstruction
  • 0x0100 – receiver saturation

Flags (CT25K):

  • 0x80 – laser temperature shut-off
  • 0x40 – laser failure
  • 0x20 – receiver failure
  • 0x10 – voltage failure

status_internal

Status internal

Flags:

  • 0x8000 – blower is on
  • 0x4000 – blower heater is on
  • 0x2000 – internal heater is on
  • 0x1000 – working from battery
  • 0x0800 – standby mode is on
  • 0x0400 – self test in progress
  • 0x0200 – manual data acquisition settings are effective
  • 0x0080 – units are meters if on, else feet (note that units are always converted to m by cl2nc)
  • 0x0040 – manual blower control
  • 0x0020 – polling mode is on

Flags (CT25K):

  • 0x800 – blower is on
  • 0x400 – blower heater is on
  • 0x200 – internal heater is on
  • 0x100 – units are meters if on, else feet (note that units are always converted to m by cl2nc)
  • 0x080 – polling mode is on
  • 0x040 – working from battery
  • 0x020 – single sequence mode is on
  • 0x010 – manual settings are effective
  • 0x008 – tilt angle > 45°
  • 0x004 – high background radiance
  • 0x002 – manual blower control

status_warning

Status warning

Flags:

  • 0x8000 – window contamination
  • 0x4000 – battery voltage low
  • 0x2000 – transmitter expires
  • 0x1000 – high humidity
  • 0x0800 – blower failure
  • 0x0100 – humidity sensor failure
  • 0x0080 – heater fault
  • 0x0040 – high background radiance
  • 0x0020 – ceilometer engine board failure
  • 0x0010 – battery failure
  • 0x0008 – laser monitor failure
  • 0x0004 – receiver warning
  • 0x0002 – tilt angle > 45° warning

Flags (CT25K):

  • 0x800 – window contamination
  • 0x400 – battery low
  • 0x200 – laser power low
  • 0x100 – laser temperature high or low
  • 0x080 – internal temperature high or low
  • 0x040 – voltage high or low
  • 0x020 – relative humidity > 85% (option)
  • 0x010 – receiver optical cross-talk compensation poor
  • 0x008 – blower suspect

tilt_angle

Tilt angle (degrees from vertical)

time

Time (seconds since 1970-01-01 00:00:00 UTC, excluding leap seconds)

time_utc

Time (UTC) (ISO 8601)

unit

Unit identification character

vertical_resolution

Vertical resolution (m)

vertical_visibility

Vertical visibility (m)

window_transmission

Window transmission estimate (%)

90% to 100% means the window is clean.

Attributes

software

cl2nc identification: cl2nc (https://github.com/peterkuma/cl2nc).

version

cl2nc version string. Follows semantic versioning.

created

Time when the NetCDF file was created (ISO 8601 UTC).

License

This software is open source and can be used, shared, and modified freely under the terms of the MIT License (see LICENSE.md).

Support

If you encounter any issues with cl2nc you can contact me at Peter Kuma <[email protected]> or submit a GitHub Issue.

Known issues

There are many different undocumented variants of the CL31/CL51 format in use. cl2nc strives to support most of them, but if you encounter errors with your data files, it might be because it is yet another variant. In such a case, submit a GitHub Issue.

FAQ

cl2nc fails with an exception.

Please make sure that the Python package netCDF4 is installed. If it still does not work for you, contact me: Peter Kuma <[email protected]>. There are small variations in the .DAT file format with instruments. cl2nc may need to be modified to be able to read a particular type of format.

Where is the height information?

Height can be determined from vertical_resolution. The instrument samples vertical bins at regular intervals.

MATLAB cannot read the time_utc variable.

MATLAB NetCDF implementation currently does not support reading NC_STRING variables. You can use the time variable instead or use the MATLAB HDF functions to read the file (you may need to change the file extension to .h5).

Changelog

cl2nc follows semantic versioning.

3.7.1 (2024-12-17)

  • Remove support for processing of records with a timestamp at the end of the record.

3.7.0 (2024-12-17)

  • Support for files without timestamps. Time can be set defined by setting the initial time with -t and a sampling interval with -s.
  • Support for a CL51 file format where the checksum line has no special characters, and space at the beginning of the "line 3" format is trimmed.
  • New option -v for printing version.

3.6.0 (2024-09-10)

  • Added support for the CT25K ceilometer.
  • Improved output metadata.

3.5.0 (2024-04-18)

  • Added support for the HIS L2 format.

3.4.0 (2023-03-10)

  • Added support for a CL51 format as in R/V Polarstern data.

3.3.2 (2023-02-26)

  • Issue a warning when no output was created because an input file is empty.

3.3.1 (2021-03-24)

  • Fixed an issue of the last record in DAT files being skipped.

3.3.0 (2020-08-27)

  • Fixed handling of certain types of time encoding.
  • Issue a warning instead of an error when a line cannot be parsed.

3.2.2 (2020-07-17)

  • Fixed installation on Windows.

3.2.1 (2020-02-08)

  • Added manual page.

3.2.0 (2020-02-08)

  • Support for an alternative DAT format with UNIX timestamps.
  • Improved error logging.
  • New option: --debug.

3.1.0 (2019-04-27)

  • Support for Python 3.
  • Accept directory input and output arguments.

3.0.0 (2018-08-20)

  • Changed time variable to contain time offset in seconds since 1970-01-01 00:00:00 UTC. time_utc contains the original time values (UTC as ISO 8601 strings).

2.1.0 (2017-11-25)

  • Fixed parsing on Windows (line endings).
  • Added support for a specific CL31 format (timestamp line instead of checksum).

2.0.1 (2017-10-23)

  • Fixed writing of NA integer values.
  • Fixed scale factor of backscatter_sum.

2.0.0 (2017-10-19)

  • Important: Fixed units conversion for sky condition height data and vertical resolution. In previous versions, vertical_resolution is off by a factor of 0.3048 if input file units are ft. layer_height is off by a factor of 100 or 10 if units are ft or m, respectively.
  • Added NetCDF file attributes: software, version, created.
  • Format time with T as a delimiter to conform to ISO 8601.
  • Improved error handling.

See also

ALCF, ccplot, ccbrowse, mpl2nc, mrr2c