Dataset: P3_SST_chl
Deployment: Aircraft_P3_NABE

Aircraft observed sea surface temperature and chlorophyll

Principal Investigator:

Dr Frank E. Hoge (National Aeronautics and Space Administration, NASA)

BCO-DMO Data Manager:

Cynthia L. Chandler (Woods Hole Oceanographic Institution, WHOI BCO-DMO)

Project:

U.S. JGOFS North Atlantic Bloom Experiment (NABE)

Version:

February 4, 2002

Version Date:

2002-02-04

Data URL:

https://osprey.bco-dmo.org/dataset-deployment/450806/data

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Description

Aircraft observed sea surface temperature and chlorophyll

Methods & Sampling

Dataset acquisition description

   PI:              Frank Hoge
   of:              NASA/Goddard Space Flight Ctr., Wallops Island, VA
   dataset:         Aircraft observed sea surface temperature and chlorophyll
   dates:           May 21, 1989
   location:        N: 63.872  S: 51.6826  W: -22.7278  E: -9.1751
   project/cruise:  NABE/NASA P3 flight of May 21, 1989
   ship:            NASA P3 aircraft
 
   
   Flight track
 
   Flight leg notes:
   Flight leg 1
   Starting Coordinates:  52 36.6 N 09 10.5 W
   Ending Coordinates:    52 24.7 N 14 59.7 W
   Flight leg 2
   Starting Coordinates:  52 18.2 N 15 49.2 W
   Ending Coordinates:    52 05.3 N 17 19.3 W
   Flight leg 3 not reported
   Flight leg 4
   Starting Coordinates:  51 40.8 N 20 00.1 W
   Ending Coordinates:    55 22.8 N 19 51.6 W
   Flight leg 5
   Starting Coordinates:  55 42.3 N 19 59.8 W
   Ending Coordinates:    59 32.1 N 20 03.5 W
   Flight leg 6
   Starting Coordinates:  59 32.4 N 20 04.6 W
   Ending Coordinates:    59 40.6 N 22 01.3 W
   Flight leg 7
   Starting Coordinates:  60 01.0 N 22 03.6 W
   Ending Coordinates:    63 52.3 N 22 43.7 W

Airborne
Oceanographic Lidar (AOL) data description

for the JGOFS North Atlantic Bloom Experiment (NABE)

21 May 1989 Frank Hoge

NASA/Goddard Space Flight Ctr., Wallops Island, VA

The laser-induced chlorophyll fluorescence has been normalized by the water
Raman backscatter to correct for variations in the optical attenuation properties
of the upper water column along the flight track. A discussion of the AOL
instrumentation and the water Raman normalization procedure are given in
the references listed below. The laser-induced chlorophyll fluorescence
was acquired using 532 nm excitation from a frequency doubled Nd:YAG laser
with an output power of ~15 mjoule/pulse. The laser was operated at 10 pulses/second.
At the nominal 120 m/sec velocity of the NASA P-3A aircraft, this sampling
rate yields an observation every 1.2 m along the flight track. The data
contained in these files are 30 point simple averages providing an observation
approximately every 0.4 km. The 532 nm laser excitation also stimulates
fluorescence from the phycoerythrin pigment contained in some strains of
marine phytoplankton. The amount of laser-induced phycoerythrin fluorescence
found during the 21 May 1989 survey was found to be low (below the detection
limitation of the AOL sensor) and accordingly is not included with the data
set contained on this disk.

The relationship between water Raman normalized laser-induced chlorophyll
fluorescence ratio and chlorophyll concentration varies somewhat due to
changes in the fluorescence pigment quantum efficiency of the in situ chlorophyll
molecules much as chlorophyll fluorescence from a continuous underway fluorometer
does. Changes in the fluorescence quantum efficiency are affected by such
factors as available light, nutrients, etc., however from previous experiments
we have seldom seen variations in excess of 20% within a single mission
over a period of 4 to 5 hours under daylight conditions. In comparing the
data set with available chlorophyll data from the R/V Discovery (U.K.) over
a contemporaneous span between 52.5 N and 53.5 N (over a period of 9 - 17
hours after the airborne sampling) we found that a scale factor 4.95 applied
to the water Raman normalized laser-induced chlorophyll provided reasonable
agreement. The data set from the R/V Discovery and the Raman normalized
laser-induced chlorophyll fluorescence data from the AOL were resampled
at 0.02 degree increments as a function of latitude and combined. A linear
regression between the absolute chlorophyll values and the chlorophyll fluorescence
yielded an R coefficient of 0.80 and the above 4.95 scale factor between
the Raman normalized laser-induced chlorophyll fluorescence values and chlorophyll
in ug/liter units. The 4.95 scale factor was applied to all data sets obtained
during the May 21 mission. The SST observations were collected from an auxiliary
Barnes PRT-5 infrared radiometer. A linear regression of the PRT-5 ocean
surface temperature values along all 7 flight lines with the ocean surface
temperature values from the Airborne Expendable Bathythermographs (AXBT's)
yielded a r coefficient of 0.95. Note that Leg 3 was not included because
of some instrument problems experienced at that point in the mission.

References:

Hoge, F. E., and R. N. Swift, Airborne dual laser excitation and mapping
of phytoplankton photopigments in a Gulf Stream warm core ring, Appl.
Opt. 22, 2272-2281, 1983.

Smith, R. C., O. B. Brown, F. E. Hoge, K. S. Baker, R. H. Evans, R.
N. Swift, and W. E. Esaias, Multiplatform sampling (ship, aircraft, and
satellite) of a Gulf Stream warm core ring, Appl. Opt. 26, 2068-2081,
1987a.

Data Processing Description

Dataset Processing Description

More information about this dataset deployment

Funding

Award Number	Funding Source
unknown NABE NASA	National Aeronautics & Space Administration

Instruments

Light Detection and Ranging System

Supplied Description:

Instrument Type

Generic Name: Light Detection and Ranging System

Acronym: LIDAR

Community Identifier: http://vocab.nerc.ac.uk/collection/P10/current/GI000288/

Generic Description:

The Light Detection and Ranging (LIDAR) system is an active remote sensing system that can be operated in either a profiling or scanning mode using pulses of light to illuminate the terrain. LIDAR data collection involves mounting an airborne laser scanning system onboard an aircraft along with a kinematic Global Positioning System (GPS) receiver to locate an x, y, z position and an inertial navigation system to monitor the pitch, roll, and heading of the aircraft. By accurately measuring the round trip travel time of the laser pulse from the aircraft to the ground, a highly accurate spot elevation can be calculated. Depending upon the altitude and speed of the aircraft along with the laser repetition rate it is possible to obtain point densities that would likely take months to collect using traditional ground survey methods (June 2010 definition from: http://www.ngs.noaa.gov/RESEARCH/RSD/main/lidar/lidar.shtml).The LIDAR transmitter uses a Galium-Aluminum-Arsenic laser which emits energy in pulses at a constant rate and wavelength. The LIDAR has two sounding modes: active and acoustic.

Note: A LIDAR system was used during US JGOFS Arabian Sea cruises to acquire SST, DOM and fluorometric pigment data, but there are also bathymetric LIDAR systems.

Parameters

Supplied Name	Supplied description	Supplied Units	Standard Name
leg	cruise or flight track segment identification		no_bcodmo_term
time	GMT time (seconds of the day) (May 21, 1989)	seconds	no_bcodmo_term
lat	latitude, minus = South	decimal degrees	lat
lon	longitude, minus = West	decimal degrees	lon
temp_sst	temperature, sea surface, from infrared radiometer	decimal degrees C	no_bcodmo_term
LIF	Raman normalized Laser-Induced Fluorescence (LIF) ratio		no_bcodmo_term
chl	chlorophyll as calculated from LIF ratios	micrograms/liter	no_bcodmo_term

Database

Contribute Data

Dataset: P3_SST_chl
Deployment: Aircraft_P3_NABE

Dataset acquisition description

Airborne
Oceanographic Lidar (AOL) data description

Dataset Processing Description

Database

Contribute Data

Dataset: P3_SST_chlDeployment: Aircraft_P3_NABE

Dataset acquisition description

Airborne Oceanographic Lidar (AOL) data description

Dataset Processing Description

Dataset: P3_SST_chl
Deployment: Aircraft_P3_NABE

Airborne
Oceanographic Lidar (AOL) data description