With the increased emphasis on monitoring the Earth's climate from space, more stringent calibration requirements are being placed on the data products from remote sensing satellite instruments. Among these are stability over decade-length time scales and consistency across sensors and platforms. For radiometer instruments in the solar reflectance wavelength range (visible to shortwave infrared), maintaining calibration on orbit is difficult due to the lack of absolute radiometric standards suitable for fight use. The Moon presents a luminous source that can be viewed by all instruments in Earth orbit. Considered as a solar diffuser, the lunar surface is exceedingly stable. The chief diffculty with using the Moon is the strong variations in the Moon's brightness with illumination and viewing geometry. This mandates the use of a photometric model to compare lunar observations, either over time by the same instrument or between instruments. The U.S. Geological Survey in Flagstaff, Arizona, under NASA sponsorship, has developed a model for the lunar spectral irradiance that explicitly accounts for the effects of phase, the lunar librations, and the lunar surface reflectance properties. The model predicts variations in the Moon's brightness with precision ~1% over a continuous phase range from eclipse to the quarter lunar phases. Given a time series of Moon observations taken by an instrument, the geometric prediction capability of the lunar irradiance model enables sensor calibration stability with sub-percent per year precision. Cross-calibration of instruments with similar passbands can be achieved with precision comparable to the model precision. Although the Moon observations used for intercomparison can be widely separated in phase angle and/or time, SeaWiFS and MODIS have acquired lunar views closely spaced in time. These data provide an example to assess inter-calibration biases between these two instruments.
[1]
Kris J. Becker,et al.
Real‐Time Control of the Robotic Lunar Observatory Telescope
,
1999
.
[2]
Bruce A. Wielicki,et al.
Satellite Instrument Calibration for Measuring Global Climate Change: Report of a Workshop
,
2004
.
[3]
Carle M. Pieters,et al.
The Moon as a Spectral Calibration Standard Enabled by Lunar Samples: The Clementine Example
,
1999
.
[4]
Steven C. Bender,et al.
On-orbit radiometric calibration over time and between spacecraft using the Moon
,
2003,
SPIE Remote Sensing.
[5]
Bruce A. Wielicki,et al.
Satellite Instrument Calibration for Measuring Global Climate Change | NIST
,
2004
.
[6]
H. Kieffer,et al.
The Spectral Irradiance of the Moon
,
2005
.
[7]
Hugh H. Kieffer,et al.
Establishing the Moon as a Spectral Radiance Standard
,
1996
.
[8]
Gerhard Meister,et al.
Comparison of SeaWiFS measurements of the Moon with the U.S. Geological Survey lunar model.
,
2004,
Applied optics.
[9]
Hugh H. Kieffer,et al.
Photometric stability of the lunar surface
,
1997
.
[10]
Frederick S. Patt,et al.
The on-orbit calibration of SeaWiFS: functional fits to the lunar time series
,
2008,
Optical Engineering + Applications.
[11]
John F. Mustard,et al.
Exploration of crustal/mantle material for the earth and moon using reflectance spectroscopy
,
1988
.
[12]
Xiaoxiong Xiong,et al.
MODIS Reflective Solar Bands On-Orbit Lunar Calibration
,
2007,
IEEE Transactions on Geoscience and Remote Sensing.
[13]
Xiaoxiong Xiong,et al.
An overview of MODIS radiometric calibration and characterization
,
2006
.