Total and partial cloud amount detection during summermonths 2005 at  Westerland (Sylt, Germany)

Abstract. The detection of cloudiness is investigated by means of partial and total cloud amount estimations from pyrgeometer radiation measurements and all-sky imager observations. The measurements have been performed in Westerland, a seaside resort on the North Sea island of Sylt, Germany, during summer 2005. An improvement to previous studies on this subject results from the fact that for the first time partial cloud amount (PCA), defined as total cloud amounts without high clouds, calculations from longwave downward radiation (LDR) according to the APCADA-Algorithm (Dürr and Philipona, 2004) are validated against both human observations from the German Weather Service DWD at the nearby airport of Sylt and digital all-sky imaging. Differences between the resulting total cloud amounts (TCA's), defined as total cloud amount for all-cloud situations, derived from the camera images and from human observations are within ±1 octa in 72% and within ±2 octa in 85% of the cases. Compared to human observations PCA measurements according to APCADA underestimate the observed cloud cover in 47% of all cases and the differences are within ±1 octa in 60% and ±2 octa in 74% of all cases. Since high cirrus clouds can not be derived from LDR, separate comparisons for all cases without high clouds have been performed showing an agreement within ±1(2) octa in 73(90)% for PCA and also for camera derived TCA. For this coastal mid-latitude site under investigation we find similar though slightly smaller agreements to human observations as reported in Dürr and Philipona (2004). Though limited to day-time the cloud cover retrievals from the sky imager are not much affected by cirrus clouds and provide a more reliable cloud climatology for all-cloud conditions than APCADA.

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Total and partial cloud amount detection during summer 2005 at Westerland (Sylt, Germany)

Atmospheric Chemistry and Physics ◽

10.5194/acp-9-1143-2009 ◽

2009 ◽

Vol 9 (4) ◽

pp. 1143-1150 ◽

Cited By ~ 16

Author(s):

N. H. Schade ◽

A. Macke ◽

H. Sandmann ◽

C. Stick

Keyword(s):

Cloud Cover ◽

Cloud Amount ◽

Cirrus Clouds ◽

Total Cloud Amount ◽

The North ◽

Seaside Resort ◽

The North Sea ◽

Sky Imager ◽

Downward Radiation ◽

High Clouds

Abstract. The detection of cloudiness is investigated by means of partial and total cloud amount estimations from pyrgeometer radiation measurements and visible all-sky imager observations. The measurements have been performed in Westerland, a seaside resort on the North Sea island of Sylt, Germany, during summer 2005. An improvement to previous studies on this subject resulting in the first time partial cloud amounts (PCAs), defined as cloud amounts without high clouds calculated from longwave downward radiation (LDR) according to the APCADA algorithm (Dürr and Philipona, 2004), are validated against both human observations from the National Meteorological Servive DWD at the nearby airport of Sylt and digital all-sky imaging. The aim is to establish the APCADA scheme at a coastal midlatitude site for longterm observations of cloud cover and to quantify errors resulting from the different methods of detecting cloudiness. Differences between the resulting total cloud amounts (TCAs), defined as cloud amount for all-cloud situations, derived from the camera images and from human observations are within ±1 octa in 72% and within ±2 octa in 85% of the cases. Compared to human observations, PCA measurements, according to APCADA, underestimate the observed cloud cover in 47% of all cases and the differences are within ±1 octa in 60% and ±2 octa in 74% of all cases. Since high cirrus clouds can not be derived from LDR, separate comparisons for all cases without high clouds have been performed showing an agreement within ±1(2) octa in 73(90)% for PCA and also for camera-derived TCA. For this coastal mid-latitude site under investigation, we find similar though slightly smaller agreements to human observations as reported by Dürr and Philipona (2004). Though limited to daytime, the cloud cover retrievals from the sky imager are not really affected by cirrus clouds and provide a more reliable cloud climatology for all-cloud conditions than APCADA.

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Seasonal cycle of cloud cover analyzed using Meteosat images

Annales Geophysicae ◽

10.1007/s00585-998-0331-3 ◽

1998 ◽

Vol 16 (3) ◽

pp. 331-341 ◽

Cited By ~ 5

Author(s):

J. Massons ◽

D. Domingo ◽

J. Lorente

Keyword(s):

Spatial Resolution ◽

Seasonal Cycle ◽

Cloud Cover ◽

High Spatial Resolution ◽

Detection Method ◽

Cloud Amount ◽

Cloud Detection ◽

Total Cloud Amount ◽

Cloud Parameters ◽

Cloud Properties

Abstract. A cloud-detection method was used to retrieve cloudy pixels from Meteosat images. High spatial resolution (one pixel), monthly averaged cloud-cover distribution was obtained for a 1-year period. The seasonal cycle of cloud amount was analyzed. Cloud parameters obtained include the total cloud amount and the percentage of occurrence of clouds at three altitudes. Hourly variations of cloud cover are also analyzed. Cloud properties determined are coherent with those obtained in previous studies.Key words. Cloud cover · Meteosat

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A Near-Global Climatology of Single-Layer and Overlapped Clouds and Their Optical Properties Retrieved from Terra/MODIS Data Using a New Algorithm

Journal of Climate ◽

10.1175/jcli3553.1 ◽

2005 ◽

Vol 18 (22) ◽

pp. 4752-4771 ◽

Cited By ~ 66

Author(s):

Fu-Lung Chang ◽

Zhanqing Li

Keyword(s):

Optical Properties ◽

Optical Depth ◽

Single Layer ◽

Cloud Amount ◽

Bimodal Distribution ◽

Cirrus Clouds ◽

Modis Data ◽

Moderate Resolution Imaging Spectroradiometer ◽

Terra Modis ◽

High Clouds

Abstract Cloud overlapping has been a major issue in climate studies owing to a lack of reliable information available over both oceans and land. This study presents the first near-global retrieval and analysis of single-layer and overlapped cloud vertical structures and their optical properties retrieved by applying a new method to the Moderate Resolution Imaging Spectroradiometer (MODIS) data. Taking full advantage of the MODIS multiple channels, the method can differentiate cirrus overlapping lower water clouds from single-layer clouds. Based on newly retrieved cloud products using daytime Terra/MODIS 5-km overcast measurements sampled in January, April, July, and October 2001, global statistics of the frequency of occurrence, cloud-top pressure/temperature (Pc/Tc), visible optical depth (τVIS), and infrared emissivity (ɛ) are presented and discussed. Of all overcast scenes identified over land (ocean), the MODIS data show 61% (52%) high clouds (Pc < 500 hPa), 39% (48%) lower clouds (Pc > 500 hPa), and an extremely low occurrence (<4%) of Pc between 500 and 600 hPa. A distinct bimodal distribution of Pc is found and peaks at ∼275 and ∼725 hPa for high and low clouds, thus leaving a minimum in cloud in the middle troposphere. Out of the 61% (52%) of high clouds identified by MODIS, retrievals reveal that 41% (35%) are thin cirrus clouds (ɛ < 0.85 and Pc < 500 hPa) and the remaining 20% (17%) are thick high clouds (ɛ ≥ 0.85). Out of the 41% (35%) of thin cirrus, 29% (27%) are found to overlap with lower water clouds and 12% (8%) are single-layer cirrus. Total low-cloud amount (single-layer plus overlapped) out of all overcast scenes is thus 68% (39% + 29%) over land and 75% (48% + 27%) over ocean, which is greater than the cloud amounts reported by the MODIS and the International Satellite Cloud Climatology Project (ISCCP). Both retrieved overlapping and nonoverlapping cirrus clouds show similar mean τVIS of ∼1.5 and mean ɛ of ∼0.5. The optical properties of single-layer cirrus and single-layer water clouds agree well with the MODIS standard retrievals. Because the MODIS retrievals do not differentiate between cirrus and lower water clouds in overlap situations, large discrepancies are found for emissivity, cloud-top height, and optical depth for high cirrus overlapping lower water clouds.

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Trends in Global Cloud Cover in Two Decades of HIRS Observations

Journal of Climate ◽

10.1175/jcli3461.1 ◽

2005 ◽

Vol 18 (15) ◽

pp. 3021-3031 ◽

Cited By ~ 208

Author(s):

Donald Wylie ◽

Darren L. Jackson ◽

W. Paul Menzel ◽

John J. Bates

Keyword(s):

Cloud Cover ◽

Cloud Amount ◽

Cloud Detection ◽

Total Cloud Cover ◽

Infrared Observation ◽

Upper Troposphere ◽

Polar Orbiting Satellite ◽

The Tropics ◽

High Clouds ◽

Infrared Radiometer

Abstract The frequency of cloud detection and the frequency with which these clouds are found in the upper troposphere have been extracted from NOAA High Resolution Infrared Radiometer Sounder (HIRS) polar-orbiting satellite data from 1979 to 2001. The HIRS/2 sensor was flown on nine satellites from the Television Infrared Observation Satellite-Next Generation (TIROS-N) through NOAA-14, forming a 22-yr record. Carbon dioxide slicing was used to infer cloud amount and height. Trends in cloud cover and high-cloud frequency were found to be small in these data. High clouds show a small but statistically significant increase in the Tropics and the Northern Hemisphere. The HIRS analysis contrasts with the International Satellite Cloud Climatology Project (ISCCP), which shows a decrease in both total cloud cover and high clouds during most of this period.

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BEACH-REHABILITATION BY USE OF BEACH FILLS AND FURTHER PLANS FOR THE PROTECTION OF THE ISLAND OF NORDERNEY

Coastal Engineering Proceedings ◽

10.9753/icce.v7.49 ◽

2011 ◽

Vol 1 (7) ◽

pp. 49

Author(s):

Johann Kramer

Keyword(s):

Sand Dunes ◽

Narrow Channels ◽

The North ◽

Open Sea ◽

Seaside Resort ◽

The North Sea ◽

Stone Concrete ◽

In The Beginning ◽

High Degree ◽

The 19Th Century

The Island of Norderney is one of the East-frisian Islands, situated at the southern coast of the North Sea (Figure 1). It arose out of the sea, which -will say that it is not the remainder of an old mainland. In the beginning there was a shoal, moulded by tide currents and wave action where later on various plants enabled the growth of sand dunes. The Eastfrisian Islands are supposed to exist since more than 1000 years already. But the written history dates back as far as to the 1 ^th century only. From charts and other historical documents we know in which way these islands changed during the centuries. Some islands vanished whilst others only changed their positions. At the beginning of the 19th century, when Norderney became a seaside resort, the village was still protected by a wall of sand dunes against the assault of the open sea. In the course of time, however, the western part of the island got lost by erosion and the sand dunes were destroyed (Figure 3). When in the middle of the nineteenth century the seaside resort, which had grown larger and larger in the meantime, threatened to be attacked by the sea, people began to protect their island. In the year 1856 they had built a seawall to the length of 900 metres. As at its ends the dunes were still destroyed, this revetment had to be extended. Moreover groynes had to be built to prevent the development of narrow channels in front of the seawall, which might have caused its destruction. Thus in the course of nearly 100 years the revetments as shown in figure 2 were founded. There are now nearly 6 km of seawalls of different types. In former times the walls were built much steeper than now-a-days. The groynes changed their shapes as well. The building material altered according to the respective level of technology. Material applied was wood, stone, concrete as well as steel and asphalt. During the years 19^0 to 19^8 the revetments could not be maintained. The beach had lost much of its height. Therefore the seawalls and the groynes were to a high degree exposed to the violent attack of the waves. In order to avoid further destruction something had to be done. The protection works represented at this time investments of a value of about kO million DM. After various inquiries had been started, a filling of the beach seemed to be the most profitable way.

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