Airborne system for fast measurements of upwelling and downwelling spectral actinic flux densities

Evelyn Jäkel; Manfred Wendisch; Anke Kniffka; Thomas Trautmann

doi:10.1364/AO.44.000434

Applied Optics
Vol. 44,
Issue 3,
pp. 434-444
(2005)
•https://doi.org/10.1364/AO.44.000434

Airborne system for fast measurements of upwelling and downwelling spectral actinic flux densities

Evelyn Jäkel, Manfred Wendisch, Anke Kniffka, and Thomas Trautmann

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Evelyn Jäkel, Manfred Wendisch, Anke Kniffka, and Thomas Trautmann, "Airborne system for fast measurements of upwelling and downwelling spectral actinic flux densities," Appl. Opt. 44, 434-444 (2005)

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Abstract

An airborne system for fast measurements of spectral actinic flux densities in the wavelength range 305–700 nm is introduced. The system is called the Actinic Flux Density Meter (AFDM). The AFDM utilizes the diode array technique and measures downwelling and upwelling spectral actinic flux densities separately with a time resolution of less than 1 s. For airborne measurements this means a spatial resolution of ~ 60 m, assuming an average aircraft velocity of 60 m/s. Thus the AFDM resolves fast changes in the actinic radiation field, which are of special importance for conditions of inhomogeneous clouds or surface reflection. Laboratory characterization measurements of the AFDM are presented, and a method to correct the nonideal angular response of the optical inlets is introduced. Furthermore, exemplar field data sampled simultaneously with spectral irradiance measurements are shown. The horizontal variability of the measured spectra of actinic flux density is quantified, and profile measurements for overcast situations are presented. Finally, the effects of clouds on the spectral actinic flux density are discussed.

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A↓	B↑
$α ↓ = \frac{F_{a 0, dir} ↓}{F_{a}}$	α↑ = 0
$β ↓ = \frac{F_{a, dif} ↑}{F_{a} ↓}$	β↑ = 1
γ↓ = 1 − α	$γ ↑ = \frac{F_{a, dif} ↓}{F_{a, dif} ↑}$

Source of Error	In the UV Range (305–400 nm)	In the VIS Range (400–700 nm)
Calibration lamp uncertainty	±5	±3
Transfer lamp uncertainty	±3	±3
Determination of receiving plane	<±1	<±1
Wavelength calibration	±5	±1
Remaining angular response error	±2	±2
Total uncertainty	±8.0	±4.9

Parameter	Description
Input optics	Two isotropic 2π quartz diffusers
Optical fibers	Monofibers with 600-μm diameter
Entrance optic	Round-to-slit converter (70 μm × 2500 μm)
Grating	248 lines mm⁻¹
Temperature drift	<0.00005 nm/K
Wavelength range	305–700 nm
Detector	512 pixel diode array
Diode wavelength separation	0.8 nm
Bandpass (FWHM)	AFDM A, 2.6 nm
	AFDM B, 2.5 nm
Calibration	1000-W tungsten halogen irradiance standard lamp^a
Signal–noise ratio	AFDM A, 120:1 (50-ms integration time)
	AFDM B, 140:1 (50-ms integration time)
Scan time	50–600 ms

Clear Sky				Scattered Cloud Layer, J(NO₂)↑ (s⁻¹)	Stratus Cloud Layer, J(NO₂)↑ (s⁻¹)

	J(NO₂)↓ (s⁻¹)

Variation parameter	Sea	Land	J(NO2)↓ (s⁻¹)
AV	1.23 × 10⁻³	1.11 × 10⁻³	7.42 × 10⁻³	3.06 × 10⁻³	7.04 × 10⁻³
SDV	0.03 × 10⁻³	0.01 × 10⁻³	0.05 × 10⁻³	0.22 × 10⁻³	0.09 × 10⁻³
RV	0.027	0.013	0.007	0.074	0.014

A↓	B↑
$α ↓ = \frac{F_{a 0, dir} ↓}{F_{a}}$	α↑ = 0
$β ↓ = \frac{F_{a, dif} ↑}{F_{a} ↓}$	β↑ = 1
γ↓ = 1 − α	$γ ↑ = \frac{F_{a, dif} ↓}{F_{a, dif} ↑}$

Abstract

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Applied Optics