Editorial Type:
Article
Article Type:
Research Article

Design, Operation, and Calibration of a Shipboard Fast-Rotating Shadowband Spectral Radiometer

R. Michael Reynolds Brookhaven National Laboratory, Upton, New York

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Mark A. Miller Brookhaven National Laboratory, Upton, New York

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Mary J. Bartholomew Brookhaven National Laboratory, Upton, New York

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Print Publication:
01 Feb 2001
DOI:
https://doi.org/10.1175/1520-0426(2001)018<0200:DOACOA>2.0.CO;2
Page(s):
200–214
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Abstract

This paper describes the design, calibration, and deployment of a fast-rotating shadowband radiometer (FRSR) that accurately decomposes downward shortwave (solar) irradiance into direct-beam and diffuse components from a moving platform, such as a ship on the ocean. The FRSR has seven channels, one broad-band silicone detector, and six 10-nm-wide channels at 415, 500, 610, 660, 860, and 940 nm. The shadowband technique produces estimates of the direct-beam normal irradiance, the diffuse irradiance (sky component), and the total irradiance. The direct-beam normal irradiances produce time series of aerosol optical thickness. A proven ability to derive meaningful at-sea estimates of aerosol optical depth from an economical, automated, and reliable instrument opens the way to a distributed network of such measurements from volunteer observing ships in all areas of the World Ocean. The processing algorithms are key to the instrument’s ability to derive direct-normal beam irradiance without gimbals and a gyro-stabilized table. At-sea Langley plots were produced during the Aerosols99 cruise of the R/V Ronald H. Brown from Norfolk, Virginia, to Cape Town, South Africa. A Langley calibration of the instrument at the Mauna Loa Observatory confirmed prior calibrations and demonstrated that the calibration was stable over the duration of the cruise. The standard deviation in all plots was of the order 2% for all channels.

Corresponding author address: R. Michael Reynolds, Brookhaven National Laboratory, Environmental Sciences Department, Bldg 490d, Upton, NY 11973.

Email: reynolds@bnl.gov

Abstract

This paper describes the design, calibration, and deployment of a fast-rotating shadowband radiometer (FRSR) that accurately decomposes downward shortwave (solar) irradiance into direct-beam and diffuse components from a moving platform, such as a ship on the ocean. The FRSR has seven channels, one broad-band silicone detector, and six 10-nm-wide channels at 415, 500, 610, 660, 860, and 940 nm. The shadowband technique produces estimates of the direct-beam normal irradiance, the diffuse irradiance (sky component), and the total irradiance. The direct-beam normal irradiances produce time series of aerosol optical thickness. A proven ability to derive meaningful at-sea estimates of aerosol optical depth from an economical, automated, and reliable instrument opens the way to a distributed network of such measurements from volunteer observing ships in all areas of the World Ocean. The processing algorithms are key to the instrument’s ability to derive direct-normal beam irradiance without gimbals and a gyro-stabilized table. At-sea Langley plots were produced during the Aerosols99 cruise of the R/V Ronald H. Brown from Norfolk, Virginia, to Cape Town, South Africa. A Langley calibration of the instrument at the Mauna Loa Observatory confirmed prior calibrations and demonstrated that the calibration was stable over the duration of the cruise. The standard deviation in all plots was of the order 2% for all channels.

Corresponding author address: R. Michael Reynolds, Brookhaven National Laboratory, Environmental Sciences Department, Bldg 490d, Upton, NY 11973.

Email: reynolds@bnl.gov

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Journal of Atmospheric and Oceanic Technology

  • Colina, L., R. C. Bohlin, and F. Castelli, 1996: The 0.12–2.5 μm absolute flux distribution of the sun for comparison with solar analog stars. Astron. J.,112, 307–315.

  • Davidson, J. A., C. A. Cantrell, A. H. McDaniel, R. E. Shetter, S. Madronich, and J. G. Calvert, 1988: Visible–ultraviolet absorption cross sections for NO2 as a function of temperature. J. Geophys. Res.,93 (D6), 7105–7112.

    • Crossref
    • Export Citation

  • DOE, 1996: Science plan for the Atmospheric Radiation Measurement Program (ARM). Rep. DOE/ER-0670T, U.S. Department of Energy, Office of Energy Research, 50 pp.

  • Gueymard, C. A., 1998: Turbidity determination from broadband irradiance measurements: A detailed multicoefficient approach. J. Appl. Meteor.,37, 414–435.

    • Crossref
    • Export Citation

  • Gurney, R. J., J. L. Foster, and C. L. Parkinson, 1993: Atlas of Satellite Observations Related to Climate Change. Cambridge University Press, 470 pp.

  • Guzzi, R., G. C. Maracci, R. Rizzi, and A. Siccardi, 1985: Spectroradiometer for ground-based atmospheric measurements related to remote sensing in the visible from a satellite. Appl. Opt.,24, 2859–2864.

    • Crossref
    • Export Citation

  • Harrison, L., and J. Michalsky, 1994: Objective algorithms for the retrieval of optical depths from ground-based measurements. Appl. Opt.,33, 5126–5132.

    • Crossref
    • Export Citation

  • ——, ——, and J. Berndt, 1994: Automated multifilter rotating shadow-band radiometer: An instrument for optical depth and radiation measurements. Appl. Opt.,33, 5126–5132.

    • Crossref
    • Export Citation

  • Haywood, J. M., V. Ramaswamy, and B. J. Soden, 1999: Tropospheric aerosol climate forcing in clear-sky satellite observations over the oceans. Science,283, 1299–1303.

    • Crossref
    • Export Citation

  • Holben, B. N., and Coauthors, 1998: AERONET—A federated instrument network and data archive for aerosol characterization. Remote Sens. Environ.,66, 1–16.

    • Crossref
    • Export Citation

  • Hooker, S. B., W. E. Esaias, G. C. Feldman, W. W. Gregg, and C. R. McLain, 1992: An Overview of SeaWiFS and Ocean Color. SeaWiFS Tech. Rep. Series, Vol. 1, Tech. Memo 104566, NASA, 24 pp.

  • Kasten, F., and A. T. Young, 1989: Revised optical air mass tables and approximation formula. Appl. Opt.,28, 4735–4738.

    • Crossref
    • Export Citation

  • Kiehl, J. T., 1999: Solving the aerosol puzzle. Science,283, 1273–1275.

    • Crossref
    • Export Citation

  • Liou, K.-N., 1980: An Introduction to Atmospheric Radiation. Academic Press, 392 pp.

  • Long, C. N., 1996: Surface radiative energy budget and cloud forcing:Results from TOGA COARE and techniques for identifying and calculating clear sky irradiance. Ph.D. thesis, The Pennsylvania State University, 193 pp.

  • ——, C. F. Pavloski, and T. P. Ackerman, 1996: A rotating shadow arm broadband solar radiometer: Instrument design and concept verification using ARM SGP radiometer measurements. Proc. Sixth Atmospheric Radiation Measurement Science Team Meeting, U.S. Department of Energy, Pacific Northwest National Laboratory, 200 pp.

  • Michalsky, J. J., 1988: The Astronomical Almanac’s algorithm for approximate solar position (1950–2050). Sol. Energy,41, 227–235.

    • Crossref
    • Export Citation

  • Miller, J., Ed., 1978: Mauna Loa Observatory: A 20th Anniversary Report. National Oceanic and Atmospheric Administration.

  • Paltridge, G. W., and C. M. R. Platt, 1977: Radiative processes in meteorology and climatology. Developments in Atmospheric Science, Elsevier.

  • Parsons, Capt. R. L., and R. R. Dickerson, 1999: NOAA Ship Ronald H. Brown study global climate variability. Sea Technol.,June, 39–45.

  • Penndorf, R., 1957: Tables of refractive index for standard air and the Rayleigh scattering coefficient for the spectral region between 0.2 and 20.0 μ and their application to atmospheric optics. J. Opt. Soc. Amer.,47, 176–182.

  • Schwartz, S. E., 1996: The Whitehouse effect—Shortwave radiative forcing of climate by anthropogenic aerosols: An overview. J. Aerosol Sci.,27, 359–382.

    • Crossref
    • Export Citation

  • ——, and M. O. Andreae, 1996: Uncertainty in climate change caused by aerosols. Science,272, 1121–1122.

    • Crossref
    • Export Citation

  • Schwindling, M., P.-Y. Deschamps, and R. Frouin, 1998: Verification of aerosol models for satellite ocean color remote sensing. J. Geophys. Res.,103 (C11), 24 919–24 935.

    • Crossref
    • Export Citation

  • Shaw, G. E., 1983: Sun photometry. Bull. Amer. Meteor. Soc.,64, 4–10.

    • Crossref
    • Export Citation

  • Solar Light Company, 1996: User’s guide for the Microtops II Ozone and Sun Photometer. Rep. MTP03, Solar Light Co., 53 pp.

  • Spencer, J. W., 1989: Comments on The Astronomical Almanac’s algorithm for approximate solar position (1950–2050). Sol. Energy,42, 353.

    • Crossref
    • Export Citation

  • Viollier, M., D. Tanré, and P.-Y. Deschamps, 1980: An algorithm for remote sensing of water color from space. Bound.-Layer Meteor.,18, 247–267.

    • Crossref
    • Export Citation

  • Wagener, R., S. Nemesure, and S. E. Schwartz, 1997: Aerosol optical depth over oceans: High space- and time-resolution retrieval and error budget from satellite radiometry. J. Atmos. Oceanic Technol.,14, 577–590.

    • Crossref
    • Export Citation

  • Wesely, M. L., 1982: Simplified techniques to study components of solar radiation under haze and clouds. J. Appl. Meteor.,21, 373–383.

    • Crossref
    • Export Citation
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