All three all-sky camera systems used for the current study are installed at
the Physikalisch-Meteorologisches Observatorium Davos/World Radiation Center
(PMOD/WRC), Davos, located in the Swiss Alps (46.81∘ N,
9.84∘ E, 1594 m a.s.l.). There are two commercial cameras, one
Q24M from Mobotix and the other is a VIS-J1006 cloud camera from the company
Schreder. Both of these cameras measure in the visible spectrum. The
third camera is the newly developed all-sky camera (IRCCAM) sensitive in the
thermal infrared wavelength range. All of these cameras are cleaned daily. The instruments themselves and their respective analysis software
are described in the following subsections. Also, the APCADA is briefly described in
Sect .
The analysis of the data from the IRCCAM is
performed for the time period 21 September 2015 to 30 September 2017, with a
data gap between 20 December 2016 and 24 February 2017 due to maintenance of
the instrument. Mobotix and APCADA data are available for the whole
aforementioned time period. Schreder data have only been available since
9 March 2016. Thus the analysis of these data is only performed for the time
period 9 March 2016 to 30 September 2017.
Thermal infrared cloud camera
The infrared cloud camera (IRCCAM) (Fig. ) consists of a
commercial thermal infrared camera (Gobi-640-GigE) from Xenics
(http://www.xenics.com/en, last access: 22 September 2018).
The camera is an uncooled microbolometer sensitive in the wavelength range of
8–14 µm. The chosen focal length of the camera objective is
25 mm and the FOV 18∘×24∘. The image
resolution is 640×480 pixels. The camera is located on top of a frame,
looking downward on a gold-plated spherically shaped aluminium mirror such
that the entire upper hemisphere is imaged on the camera sensor. The complete
system is 1.9 m tall. The distance between the camera objective and the
mirror is about 1.2 m. These dimensions were chosen in order to reflect the
radiation from the whole of the upper hemisphere onto the mirror and to minimise the
area of the sky hidden by the camera itself. The arm holding the camera above
the mirror is additionally fixed with two wire ropes to stabilise the camera
during windy conditions. The mirror is gold-plated to reduce the emissivity
of the mirror and to make measurements of the infrared sky radiation largely
insensitive to the mirror temperature. Several temperature probes are
included to monitor the mirror, camera and ambient temperatures.
The infrared cloud camera (IRCCAM) in the measurement enclosure of
PMOD/WRC in Davos, Switzerland.
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The camera of the IRCCAM was calibrated in the PMOD/WRC laboratory in order
to determine the brightness temperature or the absolute radiance in
Wm-2 sr-1 for every pixel in an IRCCAM image. The absolute
calibration was obtained by placing the camera in front of the aperture of a
well-characterised black body at a range of known temperatures between
-20 and +20 ∘C in steps of 5 ∘C .
The radiance emitted by a black-body radiator can be calculated using the Planck radiation formula,
Lλ(T)=2hc2λ51ehckλT-1,
where T is the temperature, λ the wavelength, h is the Planck
constant, 6.6261×10-34 Js, c the speed of light,
299 792 458 ms-1 and k the Boltzmann constant, 1.3806×10-23 J K-1. For the IRCCAM camera, the spectral response function
Rλ as provided by the manufacturer is shown in Fig.
and is used to calculate the integrated radiance LR,
LR=∫825Rλ⋅Lλ(T)dλ,
where T is the effective temperature of the black body
and LR is the integrated radiance measured by the IRCCAM camera. To
retrieve the brightness temperature (TB) from the integrated
radiance LR, Eq. () cannot be solved analytically.
Therefore, as an approximation, we are using a polynomial function
TB=f(LR) to retrieve the brightness temperature
TB from the radiance LR. Using Eq. (),
LR values are calculated for temperatures in the range of -40
and +40 ∘C. The resulting fitting function is a polynomial third-order function (see Fig. ), which is used to retrieve
TB from the integrated radiance LR for every pixel in
an IRCCAM image.
Response function Rλ of the camera of the IRCCAM
instrument.
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Brightness temperature TB versus integrated radiance
LR for different radiance values (red dots), and the
corresponding third-order polynomial fitting function (blue line).
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The IRCCAM calibration in the black-body aperture was performed on
16 March 2016 and all its images are calibrated with the corresponding
calibration function retrieved from the laboratory measurements. The
calibration uncertainty of the camera in terms of brightness temperatures (in
a range of -40 and +40 ∘C) is estimated at 1 K for a Planck
spectrum as emitted by a black-body radiator. Furthermore, a temperature
correction function for the camera was derived from these laboratory
calibrations in order to correct the measurements obtained at ambient
temperatures outdoors.
The hemispherical sky images taken by the IRCCAM are converted to polar
coordinates (Θ, Φ) for the purpose of retrieving brightness
temperatures in dependence of zenith and azimuth. Due to slight
aberrations in the optical system of the IRCCAM, the Θ coordinate does
not follow a linear relationship with the sky zenith angle, producing a
distorted sky image. Therefore, a correction function was determined by
correlating the apparent solar position as measured by the IRCCAM with the
true solar position obtained by a solar position algorithm. This correction
function was then applied to the raw camera images to obtain undistorted
images of the sky hemisphere.
One should note that observing the sun with the Gobi camera implies that the
spectral filter used in the camera to limit the spectral sensitivity to the
8–14 µm wavelength band has some leakage at shorter wavelengths.
Fortunately, this leakage is confined to a narrow region around the solar
disk (around 1∘) as shown in Fig. . Thus, it has no effect
on the remaining part of the sky images taken by the IRCCAM during daytime
measurements.
(a) Measured brightness temperature (TB) on the
cloud-free day 18 June 2017, 10:49 UTC (SZA = 24∘),
(b) the corresponding modelled brightness temperature and
(c) the measured (red) and modelled (blue) profile of the sky
brightness temperature along one azimuth position (shown as a yellow line in
a).
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The main objective of the IRCCAM study is to determine cloud properties from
the measured sky radiance distributions. The cloudy pixels in every image are
determined from their observed higher radiances with respect to that of a
cloud-free sky. The clear-sky radiance distributions are determined from
radiative transfer calculations using MODTRAN 5.1 , using as
input parameters screen-level air temperature and integrated water vapour
(IWV). The temperature was determined at 2 m elevation from a nearby
SwissMetNet station, while the IWV was retrieved from GPS signals operated by
the Federal Office for Topography and archived in the Studies in Atmospheric
Radiation Transfer and Water Vapour Effects (STARTWAVE) database hosted at
the Institute of Applied Physics at the University of Bern
. For practical reasons, a look-up table (LUT) for a range
of temperatures and IWV was generated, which was then used to compute the
reference clear-sky radiance distribution for every single image taken by the
camera. A similar approach that is used to detect cloud patterns is described
in and .
The sky brightness temperature distribution as measured on a cloud-free day
(18 June 2017, 10:49 UTC) and the corresponding modelled sky brightness
temperature are shown in Fig. a and b. As expected,
the lowest radiance is emitted at the zenith, with a gradual increase at
increasing zenith angle, until the measured effective sky brightness
temperature at the horizon is nearly equal to ambient air temperature
. Figure c shows the profiles of the measured
(red) and modelled (blue) brightness temperatures along one azimuth position
going through the solar position (yellow line in Fig. a). As can
be seen in Fig. c, the measured and modelled sky distributions
agree fairly well, with large deviations at high zenith angles due to the
mountains obstructing the horizon around Davos. The short-wave leakage from
the sun can also be clearly seen around pixel number 180. A smaller deviation
is seen at pixel number 239 from the wires holding the frame of the camera.
The average difference between the measured and modelled clear-sky radiance
distributions was determined for several clear-sky days during the
measurement period in order to use that information when retrieving clouds
from the IRCCAM images. Differences can arise, on the one hand, from the
rather crude radiative transfer modelling, which only uses surface temperature
and IWV as input parameters to the model. On the other hand, it can arise from
instrumental effects such as a calibration uncertainty of ±1 K. An
effect of the mirror temperature and a possible mismatch between actual and
nominal spectral response functions of the IRCCAM camera are other potential
causes for this difference. However, both of these possible effects have not been
taken into account. The validation measurements span 8 days, with full-sky
measurements obtained every minute, yielding a total of 11 512 images for
the analysis. For every image, the corresponding sky radiance distribution
was calculated from the LUT, as shown in Fig. b. The residuals
between the measured and modelled sky radiance distributions were calculated
by averaging over all data points with zenith angles smaller than
60∘ while removing the elements (frame and wires) of the IRCCAM
within the FOV of the camera, resulting in one value per image. The
brightness temperature differences between IRCCAM and model calculations show
a mean difference of +4.0 K and a standard deviation of 2.4 K over the
whole time period. The observed variability comes equally from day-to-day
variations as well as from variations within a single day. No systematic
differences are observed between day and night-time data.
The stability of the camera over the measurement period is investigated by
comparing the horizon brightness temperature derived from the IRCCAM with the
ambient air temperature measured at the nearby SwissMetNet station. As
mentioned by , the horizon brightness temperature derived
from the IRCCAM should approach the surface air temperature close to the
horizon. Indeed, the average difference between the horizon brightness
temperature derived from the IRCCAM and the surface air temperature was
0.1 K with a standard deviation of 2.4 K, showing no drifts over the
measurement period and thus confirming the high stability of the IRCCAM
during this period. The good agreement of 0.1 K between the derived horizon
brightness temperature from the IRCCAM and the surface air temperature
confirms the absolute calibration uncertainty of ±1 K of the IRCCAM.
Therefore, the observed discrepancy of 4 K between measurements and model
calculations mentioned previously can probably be attributed to the
uncertainties in the model parameters (temperature and IWV) used to produce
the LUT.
Cloud detection algorithm
After setting up the IRCCAM, a horizon mask is created initially to determine
the area of the IRCCAM image representing the sky hemisphere. A cloud-free
image is selected manually. The sky area is selected by the very low sky
brightness temperatures with respect to the local obstructions with much
larger brightness temperatures. This image mask contains local obstructions
such as the IRCCAM frame (camera, arm and wire ropes) as well as the horizon,
which, in the case of Davos, consists of mountains limiting the FOV
of the IRCCAM. Thereafter, the same horizon mask is applied to all IRCCAM
images. The total number of pixels within the mask is used as a reference and
the cloud fraction is defined as the number of pixels detected as cloudy
relative to the total number.
The algorithm used to determine cloudy pixels from an IRCCAM image consists of two
parts. The first part uses the clear-sky model calculations as a reference to
retrieve low- to mid-level clouds. These clouds have large temperature
differences compared to the clear-sky reference. In this part of the
algorithm, cloudy pixels are defined for measured sky brightness temperatures
that are at least 6.5 K greater than the modelled clear-sky reference value.
A rather large threshold value was empirically chosen to avoid any erroneous
clear-sky misclassifications as cloudy pixels. The thinner and higher clouds
with lower brightness temperatures are therefore left for the second part of
the algorithm.
In order to determine the thin and high-level clouds within an IRCCAM image,
non-cloudy pixels remaining from the first part of the algorithm are used to
fit an empirical clear-sky brightness temperature as a function of the zenith
angle,
TB=(T65-a)Θ65b+a,
where TB is the brightness temperature for a given zenith angle
Θ, and T65, a and b are the retrieved function parameters
. This second part of the algorithm assumes a smooth
variation of the clear-sky brightness temperature with zenith angle. Thereby,
it determines cloudy pixels as deviations from this smooth function as well
as requiring a brightness temperature higher than this empirical clear-sky
reference. Pixels with a brightness temperature higher than the empirically
defined threshold of 1.2 K are defined as cloudy and removed from the clear-sky data set. This procedure is repeated up to 10 times to iteratively find
pixels with a brightness temperature higher than the clear-sky function. One
restriction of this fitting method is that it requires at least broken cloud
conditions, as it does not work well under fully overcast conditions without
the presence of cloud-free pixels to constrain the fitting procedure.
The selected threshold of 1.2 K allows the detection of low-emissivity clouds, but still misses
the detection of parts of thin, high-level
cirrus clouds even though they can be clearly seen in the IRCCAM images.
Unfortunately, reducing the threshold to less than 1.2 K results in many
clear-sky misclassifications as clouds. Therefore, under these conditions, it
seems that using a spatial smoothness function is not sufficient to infer
that individual pixels are cloudy; a more advanced algorithm as discussed in
is required to define clouds, not only on a
pixel-by-pixel basis but as a continuous structure (e.g. pattern recognition
algorithm).
Before reaching the final fractional cloud data set, some data-filtering
procedures are applied: situations with precipitation are removed by
considering precipitation measurements from the nearby SwissMetNet station;
ice or snow deposition on the IRCCAM mirror is detected by comparing the
median radiance of a sky area with the median radiance value of an area on
the image showing the frame of the IRCCAM. In cases where the difference
between the median values of the two areas is smaller than the empirically
defined value of 5 Wm-2 sr-1, the mirror is assumed to be contaminated
by snow or ice and therefore does not reflect the sky, so the image is
excluded. The horizon mask does not cover all pixels that do not depict sky,
which leads to an offset in the calculated cloud fraction of around 0.04.
This offset is removed before comparing the cloud fraction determined by the
IRCCAM with other instruments.
Mobotix camera
A commercial surveillance Q24M camera from Mobotix
(https://www.mobotix.com/, last access: 22 September 2018)
was installed in Davos in 2011. The camera has a fisheye lens and is
sensitive in the red–green–blue (RGB) wavelength range. The camera takes
images from the whole of the upper hemisphere with a spatial resolution of 1200×1600 pixels. The camera system is heated, ventilated and installed on
a solar tracker with a shading disk. The shading disk avoids overexposed
images due to the sun. The time resolution of the Mobotix data is 1 min
(from sunrise to sunset) and the exposure time is 1/500 s.
An algorithm determines the cloud fraction of each image automatically
. Before applying the cloud detection algorithm,
the images are preprocessed. The distortion of the images is removed by
applying a correction function. The same horizon mask, which was defined on
the basis of a cloud-free image, is applied to all images. After this
preprocessing, the colour ratio (the sum of the blue to green ratio plus the
blue to red ratio) is calculated per pixel. To perform the cloud
determination per pixel, this calculated colour ratio is compared to an
empirically defined reference ratio value of 2.2. Comparing the calculated
colour ratio value with this reference value designates whether a pixel is
classified as cloudy or as cloud-free. The cloud fraction is calculated by
the sum of all cloud pixels divided by the total number of sky pixels.
The cloud classes are determined with a slightly adapted algorithm from
which is based on statistical features (Wacker et al.,
2015; Aebi et al., 2017). The cloud classes determined are stratocumulus
(Sc), cumulus (Cu), stratus–altostratus (St–As), cumulonimbus–nimbostratus
(Cb–Ns), cirrocumulus–altocumulus (Cc–Ac), cirrus–cirrostratus (Ci–Cs) and
cloud-free (Cf).
Schreder camera
The total-sky camera VIS-J1006 from Schreder
(http://www.schreder-cms.com/en/, last access: 22 September 2018) consists of a digital camera with a fisheye lens. The VIS-J1006
Schreder camera is sensitive in the RGB region of the spectrum and takes two
images every minute with different exposure times (1/500 and 1/1600 s). The aperture is fixed at f/8 for both images. The
resolution of the images is 1200×1600 pixels. The camera comes
equipped with a weatherproof housing and a ventilation system.
The images from the Schreder camera are analysed using two different
algorithms. The original software is directly delivered from the company
Schreder. Before calculating the fractional cloud coverage, some steps are
needed to define the settings that are needed to preprocess the images. In a
first step, the centre of the image is defined manually. In a second step,
the maximum zenith angle of the area taken into account for further analyses
is defined. Unfortunately, the maximum possible zenith angle is only
70∘ and thus a larger fraction of the sky cannot be analysed. After
the distortion of the images is removed, in a fourth step a horizon mask is
defined on the basis of a cloud-free image. The mask also excludes the pixels
around the sun. In a last step, a threshold is defined which specifies
whether a pixel is classified as a cloud or not. The settings from
these preprocessing steps are then applied to all images from the Schreder
camera. In the following, the term Schreder refers to data for which this
algorithm is used.
Relative frequencies of the determined cloud coverage of the
analysed instruments for selected bins of cloud coverage at Davos (during
daytime). Zero okta: 0–0.0500, 1 okta: 0.0500–0.1875, 2 oktas:
0.1875–0.3125, 3 oktas: 0.3125–0.4375, 4 oktas: 0.4375–0.5625, 5 oktas:
0.5625–0.6875, 6 oktas: 0.6875–0.8125, 7 oktas: 0.8125–0.9500, 8 oktas:
0.9500–1.
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Cloud fraction determined by the analysed cameras and algorithms
(red is IRCCAM, black is Mobotix, blue is Schreder, yellow is
Schrederpmod) on 4 April 2016.
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Due to the Schreder algorithm's limitation of a maximum zenith angle of
70∘, we used the same algorithm as for the Mobotix camera, referred
to hereafter as Schrederpmod. The algorithm
Schrederpmod has the advantage that the whole of the upper
hemisphere is considered when calculating the fractional cloud coverage.
Thus, a new horizon mask is defined on the basis of a cloud-free image. The
colour ratio reference that distinguishes between clouds and
no clouds is assigned an empirical value of 2.5, which is slightly different
to that used for the Mobotix camera. The Schreder camera in Davos has been
measuring continuously since March 2016.