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Nimbus Temperature-Humidity Infrared Radiometer 6.7 µm Water Vapor Swath L1, HDF5, Version 1
This data set (NmTHIR67-1H) consists of daily, global radiative temperatures measured in the 6.7 µm window (6.5 µm - 7.0 µm) by the Temperature-Humidity Infrared Radiometer (THIR) on board the Nimbus 4 satellite. The THIR 6.7 µm window was used to map the water vapor distribution in the upper troposphere and stratosphere.
Geographic Coverage
Spatial Coverage: |
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Spatial Resolution: |
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Temporal Coverage: |
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Temporal Resolution: | 10 minute |
Parameter(s): |
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Platform(s) | NIMBUS-4 |
Sensor(s): | THIR |
Data Format(s): |
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Version: | V1 |
Data Contributor(s): | David Gallaher, G. Garrett Campbell |
Metadata XML: | View Metadata Record |
Data Citation
As a condition of using these data, you must cite the use of this data set using the following citation. For more information, see our Use and Copyright Web page.
Gallaher, D. and G. Campbell. 2015. Nimbus Temperature-Humidity Infrared Radiometer 6.7 µm Water Vapor Swath L1, HDF5, Version 1. [Indicate subset used]. Boulder, Colorado USA. NASA National Snow and Ice Data Center Distributed Active Archive Center. doi: http://dx.doi.org/10.5067/NIMBUS/NmTHIR67-1H. [Date Accessed].Detailed Data Description
The THIR detected emitted thermal radiation in two windows: 6.7 µm (6.5 µm — 7.0 µm) and 11.5 µm (10.5 µm — 12.5 µm). Each file in this data set contains 10 minutes of cross-track scan swath data from the 6.7 µm window. The corresponding THIR 11.5 µm window measurements are available as a separate data set here.
Data are provided as HDF5-formatted files. Browse images are also available.
HDF5 is a data model, library, and file format maintained by the HDF Group. For details, visit the HDF Group's HDF5 Home Page.
This section explains the file naming convention used for NmTHIR67-1H data files.
Example File Name: NmTHIR67-1H.19700510_01-27-17_00428_01.hdf
NmTHIR67-1H.[yyyy][mm][dd]_[hh]-[mi]-[ss]_[orb]_[ggg].hdf
Refer to Table 1 for the valid values for the file name variables listed above.
Variable | Description |
---|---|
yyyy | Four-digit year |
mm | Month |
dd | Day |
hh | Hour |
mi | Minute |
ss | Second |
orb | Orbit number |
ggg | Granule number (within orbit) |
Data files typically about 4 MB.
Intermittent data are available from 10 May 1970 to 25 March 1971.
Temporal Resolution
Each file contains 10 minutes of swath data.
Table 2 lists the variables (data fields) and corresponding attributes stored in NmTHIR67-1H data files. Refer to Table 3 to decode the bit flags stored in the Flags
variable.
Data Field | Description | Attributes | Value |
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Flags | Bit flags (see Table 3 for descriptions) | Key | bits 0,1: 00=ocean, 01=25% land, 10=50% land, 11=land bit 2: on=ascending, off=descending bit 3: on=day, off=night bit 4: on=bad data due to reflection from spacecraft bit 5: spare bit 6: on=temperature out of range bit 7: spare |
THIR-67-Temp |
Radiative temperatures (K) as derived in the 1960s. |
DOI | 10.5067/NIMBUS/NmTHIR67-1H |
ESDT | Data set short name (NmTHIR67-1H) | ||
long_ESDT | Data set long name (Nimbus Temperature-Humidity Infrared Radiometer 6.7 µm Water Vapor Swath L1, HDF5) | ||
units | kelvin | ||
Sat Latitude | Satellite latitude (at nadir) when scan line was acquired | units | degrees |
Sat Longitude | Satellite longitude (at nadir) when scan line was acquired | units | degrees |
cosine sun zenith angle | Cosine sun zenith angle from satellite nadir | units | 1 |
cosine view angle | Cosine view angle of observation | units | 1 |
latitude | Observation latitude | units | degrees_north |
longitude | Observation longitude | units | degrees_east |
scan Time millisec | Time scan line was acquired (ms since 1970) | units | millisecond |
shift value | Spatial shift (pixels) applied to each scan line to help offset random alignment errors. See Derivation Techniques and Algorithms. | units | pixels |
Bit(s) | Description |
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0, 1 | Ocean/Land Coverage Flag: 00=ocean, 01=25% land, 10=50% land, 11=land |
2 | Ascending/Descending Half of Orbit: 0=descending; 1=ascending |
3 | Day/Night Flag: 0=night, 1=day |
4 | Reflected Light. Flag set to on means bad data due to reflected light from satellite component. |
5 | Spare. Set to 0. |
6 | Data Out of Range. Flag set to on means T < 190 K or T > 330 K. |
7 | Spare. Set to 0 |
Software and Tools
Data Acquisition and Processing
The THIR on the Nimbus 4 satellite transformed measured radiation into electrical voltages that were recorded on tape and played back when the satellite came within range of a receiving station. These data were then transmitted to the Goddard Space Flight Center (GSFC), where they were calibrated, converted to temperatures, and archived on 7-track, digital magnetic tapes. In 2013, the contents of these tapes were recovered and written to a binary tape emulation file format (TAP) for preservation. GES DISC, the NASA Goddard Earth Sciences Data and Information Services Center, maintains a Nimbus Overview page through which users can obtain the TAP files and historical Nimbus documentation such as instrument user guides and mission reports.
In the original THIR data, cloud edges and land features appear jagged. Closer inspection reveals that adjacent scan lines appear to be shifted relative to each other by plus or minus several pixels in the cross-track direction. These small, random shifts likely reflect some kind of systemic error, due perhaps to repeatedly switching data acquisitions on and off to record only the earthward-facing portion of each scan mirror revolution.
To help minimize this error, reference scan lines were created by smoothing the data with a moving average (n=5). Each unsmoothed scan line was then incrementally shifted in the cross-track direction (maximum of ±10 pixels) and correlated at each step with its smoothed counterpart. Data from the original THIR files were then written to the THIR-67-Temp data field, offset by the pixel value that yielded the best correlation. Emptied pixels at the ends of scan lines were filled with a value of 3.4028235E+38. Each scan line's pixel shift is recorded in the shift value data field (see Table 2).
Error Sources
This data set was constructed from TAP files archived by GES DISC. As such, the data reflect the original THIR calibration and temperature conversion utilized in 1970. From a qualitative review of images over the poles, it is clear measurements at the low end of the temperature scale contain significant random noise.
The realignment described in the preceding section improves the visual appearance of the data and better represents the shapes of clouds and coastlines. In regions with very little spatial information, for example where the measurements are very noisy or very uniform, the shifts offer little or no improvement.
The Nimbus 4 Temperature-Humidity Infrared Radiometer (THIR) was a two-channel scanning radiometer designed to detect emitted thermal radiation in two windows: 6.7 µm (6.5 µm — 7.0 µm) and 11.5 µm (10.5 µm — 12.5 µm). The 6.7 µm window operated primarily at night and was used to map the distribution of water vapor in the upper troposphere and stratosphere. The 11.5 µm channel operated both day and night and measured cloud top or surface temperatures.
The Nimbus 4 instrument utilized a single scan mirror which rotated at 48 rpm and was inclined 45° to the axis of rotation to scan perpendicular to the flight path. The field of view scanned across the earth from east to west in daytime and west to east at night, traveling northward and southward respectively. Incoming energy was collected by the mirror and then focused into a dichromatic beam splitter which divided the energy spectrally and spatially into the two channels. Both channels transformed the received radiation into an electrical (voltage) output with an information bandwidth of 0.5 Hz to 120 Hz for the 6.7 µm channel and 0.5 Hz to 360 Hz for the 11.5 µm channel. The data were recorded on tape and subsequently played back to a ground acquisition station.
The THIR intially operated successfully but failed on January 11, 1971 (orbit 3731). It was restarted several times thereafter for very short periods before finally ceasing all operations in August 1971. For additional information about the Nimbus THIR, see the NASA National Space Science Data Center Temperature-Humidity Infrared Radiometer (THIR) Web page.
Version (Date) | Details |
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V1 (24 November, 2015) | Initial release. |
References and Related Publications
Contacts and Acknowledgments
Investigators
David Gallaher
National Snow and Ice Data Center
CIRES, 449 UCB
University of Colorado
Boulder, CO 80309-0449 USA
G. Garrett Campbell
National Snow and Ice Data Center
CIRES, 449 UCB
University of Colorado
Boulder, CO 80309-0449 USA
The Nimbus Data Rescue Project was supported by NASA contract #NNG08HZ07C as a subtask to NSIDC at the University of Colorado. The PIs also wish to thank Dennis Wingo and Matt Sandler who contributed to this project.
Document Information
DOCUMENT CREATION DATE
November 2015
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