High Resolution Picture Transmission Research Articles

Retrieval of Sea Surface Skin Temperature from the High Resolution Picture Transmission Data of the National Oceanic and Atmospheric Administration Series Satellites

The High Resolution Picture Transmission (HRPT) data of the National Oceanic and Atmospheric Administration (NOAA) series meteorological satellites had been received by the SeaSpace ground station located at the Ocean University of China (OUC). Based on the atmospheric radiative transfer model, we obtained the NOAA-15/16/17/18/19 Advanced Very High Resolution Radiometer (AVHRR) sea surface skin temperature (SSTskin) data using the Bayesian cloud detection method and the optimal estimation (OE) sea surface temperature (SST) retrieval algorithm. Compared with the NOAA/AVHRR multi-channel SST data, the AVHRR SSTskin data have higher data accuracy. We also compared the AVHRR SSTskin with the buoy SST with spatial and temporal windows of 0.01° and 30 min. The daytime biases ranged from −0.32 °C (NOAA-16) to 0.08 °C (NOAA-17) with standard deviations (SDs) ranging from 0.36 °C (NOAA-18/ NOAA-19) to 0.60 °C (NOAA-16), and the nighttime biases ranged from −0.26 °C (NOAA-16) to −0.02 °C (NOAA-17) with SDs ranging from 0.33 °C (NOAA-19) to 0.60 °C (NOAA-16). The accuracy of all five satellite data during daytime and nighttime was significantly improved. These results show that the AVHRR SSTskin of NOAA series satellites is good and consistent in different periods, and the SSTskin data products with high spatial resolution and accuracy can be used for mesoscale and submesoscale marine applications.

Detection of Snow Cover from Historical and Recent AVHHR Data—A Thematic TIMELINE Processor

Global snow cover forms the largest and most transient part of the cryosphere in terms of area. On the local and regional scale, small changes can have drastic effects such as floods and droughts, and on the global scale is the planetary albedo. Daily imagery of snow cover forms the basis of long-term observation and analysis, and only optical sensors offer the necessary spatial and temporal resolution to address decadal developments and the impact of climate change on snow availability. The MODIS sensors have been providing this daily information since 2000; before that, only the Advanced Very High-Resolution Radiometer (AVHRR) from the National Oceanographic and Atmospheric Administration (NOAA) was suitable. In the TIMELINE project of the German Aerospace Center, the historic AVHRR archive in HRPT (High Resolution Picture Transmission) format is processed for the European area and, among other processors, one output is the thematic product ‘snow cover’ that will be made available in 1 km resolution since 1981. The snow detection is based on the Normalized Difference Snow Index (NDSI), which enables a direct comparison with the MODIS snow product. In addition to the NDSI, ERA5 re-analysis data on the skin temperature and other level 2 TIMELINE products are included in the generation of the binary snow mask. The AVHRR orbit segments are projected from the swath projection into LAEA Europe, aggregated into daily coverages, and from this, the 10-day and monthly snow covers are finally calculated. In this publication, the snow cover algorithm is presented, as well as the results of the first validations and possible applications of the final product.

Theoretical and Numerical Analysis for Design of High Ratio Fiber Optic Taper Drawing Process

Fiber optic taper is an important component in the CCD coupling, television imaging and night vision device. Increasing need in high-resolution picture transmission devices requires better quality of high-ratio fiber optic taper. The resulting taper shape is important as it affects transmission properties of fiber optic taper. This paper develops a physical model for analyzing the high-ratio fiber optic taper time-dependent fabricating process. Based on the physical model, the evolution of the taper's neckdown profile is analyzed. Simulation results demonstrate that viscosity of materials, furnace geometry, temperature distribution in the furnace and the external tensile force will strongly affect the drawing process. The final shape of fiber optic taper depends on material properties and heating profile. The tensile force, which will affect the evolution process, has a minor influence on the taper's final shape. Based on the understanding of the above analysis, an improved drawing design can be proposed for fabricating large radius fiber optic taper with high ratio.

Influence of water-temperature variability on stony coral diversity in Florida Keys patch reefs

Satellite-derived sea surface temperature (SST) The Advanced Very High Resolution Radiometer (AVHRR) imagery obtained from NOAA polar orbiting satellites (i.e., NOAA-12, 14, 16, and 19) were collected by the High Resolution Picture Transmission antenna, at the Institute for Marine Remote Sensing (IMaRS) at the University of South Florida. SST was calculated using the multichannel sea surface temperature algorithm developed by McClain et al. (1983) and updated calibration coefficients for each satellite sensor in orbit. Satellite imagery was mapped to a cylindrical equidistant projection and cloud filtered (Hu et al. 2009).

A Software-Defined Radio Based Adaptive HRPT/APT Signal Receiver

The paper discusses the design, implementation, and test of a software-defined radio (SDR) based receiver to acquire HRPT (high resolution picture transmission) and APT (automatic picture transmission) signals of NOAA weather satellites simultaneously, recognizes modulation types, and demodulates the signals. The captured HRPT RF signal is downconverted to the 137.5 MHz band in the RF (radio frequency) front-end and then combined with the APT RF signal. The combined signals are then downconverted and digitized at the programmable receiver platform. The digitized data are spectrally analyzed with short-time FFT (fast Fourier transform) to obtain an instantaneous spectrum for adjustment of the adaptive digital band-pass filter. The modulation recognition block identifies split-phase PSK (phase shift keying) for HRPT and FM (frequency modulation) for APT. The HRPT signal is then demodulated with a Costas loop because the two side bands have more power than the carrier. The APT signal is demodulated in an FM demodulator with Zoom-FFT and automatic gain control (AGC) to maintain the brightness of the whole weather map according to the brightness of the synchronization mark. The system functions are developed and realized in an SDR software platform. The resulting SDR-based receiver is then used to receive and process real signals.

An inter-sensor calibration and atmospheric correction system for long-term time series of AVHRR imagery for coastal waters

The Advanced Very High Resolution Radiometer (AVHRR) data series has more than 30 years of unique and valuable Earth observation imagery available. To use the long-term remote-sensor data, this article presents a system that produces consistent inter-sensor calibration and atmospheric correction for coastal waters. The system can process all five High Resolution Picture Transmission (HRPT) file formats from the twelve (12) AVHRR sensors that operated from the 1980s to the present. The system has been used to process AVHRR data of three Texas estuaries from 1985 to 2010 to document changes in suspended sediment patterns.

Estimation of vertically integrated water vapor in Hungary using MODIS imagery

Information about the amount and spatial structure of atmospheric water vapor is essential in understanding meteorology and the Earth environment. Space-borne remote sensing offers a relatively inexpensive method to estimate atmospheric water vapor in the form of integrated water vapor (IWV). The research activity reported in the present paper is based on the data acquired by the HRPT/MODIS (High Resolution Picture Transmission, MODerate resolution Imaging Spectroradiometer) receiving station established in Budapest (Hungary) by the Space Research Group of the Eötvös Loránd University. Integrated water vapor is estimated by the remotely sensed data of the MODIS instrument with different methods and also by the operational numerical weather prediction model of the European Centre for Medium-Range Weather Forecasts (ECMWF). Radiosonde data are used to evaluate the accuracy of the different IWV fields though it has been pointed out that the in situ data also suffers from uncertainties. It was found that both the MODIS and the ECMWF based fields are of good accuracy. The satellite data represent finer scale spatial structures while the ECMWF data have a relatively poor spatial resolution. The high quality IWV fields have proved to be useful for radiative transfer studies such as the atmospheric correction of other satellite data from times different than the overpass times of satellites Terra/Aqua and the forecast times of the model data. For this purpose the temporal variability of IWV is scrutinized both using ECMWF and MODIS data. Taking advantage of Terra and Aqua overpasses, the mean rate of change of IWV estimated by the near infrared method was found to be 0.47 ± 0.45 kg m −2 h −1, while it was 0.13 ± 0.65 kg m −2 h −1 based on the infrared method. The numerical weather prediction model’s analysis data estimated −0.01 ± 0.13 kg m −2 h −1 for the mean growth rate, while using forecast data it was 0.24 ± 0.18 kg m −2 h −1. MODIS data should be used when available for the estimation of the IWV in other studies. If no satellite data are available, or available data are only from one overpass, ECMWF based IWV can be used. In this case the analysis fields (or the satellite field) should be used for temporal extrapolation but the rate of change should be calculated from the forecast data due to its higher temporal resolution.

Retrieval of TPW over ocean from locally received AMSU measurements

Total Precipitable Water (TPW) in a column of atmosphere is one of the important parameters useful for a number of meteorological applications. In the present study, a neural network based algorithm has been developed for the retrieval of TPW using NOAA-16 AMSU measurements. The TPW has been derived experimentally using NOAA-16 AMSU measurements locally received from High Resolution Picture Transmission (HRPT) station at India Meteorological Department (IMD) separately over ocean only. The validation of TPW has been carried out against the TPW derived from Radiosonde (RAOB) data. The bias and rms errors against the RAOB derived TPW have been found to about 0.11 mm and 2.98 mm respectively. The inter comparisons of TPW derived using NOAA AMSU data have also been made with that of NOAA/NESDIS derived TPW. Further, case study for the potential use of TPW derived from NOAA AMSU data has been carried out. This case study has revealed that the concentration of maximum precipitable water values in conjunction with high Sea surface wind speed data from Quickscat Scatterometer were found very useful for forecasting the heavy to very heavy rainfall event along the west coast of India. Therefore, AMSU derived TPW could be used as an important parameter for the operational weather forecasting on a real time basis.

SPARC: New Cloud, Snow, and Cloud Shadow Detection Scheme for Historical 1-km AVHHR Data over Canada

Abstract The identification of clear-sky and cloudy pixels is a key step in the processing of satellite observations. This is equally important for surface and cloud–atmosphere applications. In this paper, the Separation of Pixels Using Aggregated Rating over Canada (SPARC) algorithm is presented, a new method of pixel identification for image data from the Advanced Very High Resolution Radiometer (AVHRR) on board the NOAA satellites. The SPARC algorithm separates image pixels into clear-sky and cloudy categories based on a specially designed rating scheme. A mask depicting snow/ice and cloud shadows is also generated. The SPARC algorithm has been designed to work year-round (day and night) over the temperate and polar regions of North America, for current and historical AVHRR/NOAA High-Resolution Picture Transmission (HRPT) and Local Area Coverage (LAC) data with original 1-km spatial resolution. The algorithm was tested and applied to data from the AVHRR sensors flown on board NOAA-6 to NOAA-18. The method was employed in generating historical clear-sky composites for the 1982–2005 period at daily, 10-day, and monthly time scales at 1-km resolution for an area of 5700 km × 4800 km centered over Canada. This region also covers the northern part of the United States, including Alaska, as well as Greenland and the surrounding oceans. The SPARC algorithm is designed to produce an aggregated rating that accumulates the results of several tests. The magnitude of the rating serves as an indicator of the probability for a pixel to belong to the clear-sky, partly cloudy, or overcast categories. The individual tests employ the spectral properties of five AVHRR channels, as well as surface skin temperature maps from the North American Regional Reanalysis (NARR) dataset. These temperature fields are available at 32 km × 32 km spatial resolution and at 3-h time intervals. Combining all test results into one final rating for each pixel is beneficial for the generation of multiscene clear-sky composites. The selection of the best pixel to be used in the final clear-sky product is based on the magnitude of the rating. This provides much-improved results relative to other approaches or “yes/no” decision methods. The SPARC method has been compared to the results of supervised classification for a number of AVHRR scenes representing various seasons (snow-free summer, winter with snow/ice coverage, and transition seasons). The results show an overall agreement between the automated (SPARC) and the supervised classification at the level of 80% to 91%.

An automatic system for AVHRR land surface product generation

Making products from the Advanced Very High Resolution Radiometer (AVHRR) on board the National Oceanic and Atmospheric Administration (NOAA) polar‐orbiting satellites can be time consuming and an automated technique for image processing is required to generate long time series of AVHRR imagery. This paper aims to describe the development of a system for fully‐automated AVHRR image processing, including radiometric calibration, precise geo‐registration and generating land‐surface products, such as vegetation indices, maximum value composites and cloud masks. Tests for crop monitoring purposes were carried out using High Resolution Picture Transmission (HRPT) images between October 2003 and April 2004. The region used to evaluate the system was the State of Paraná, one of the primary soybean producers in Brazil. Results have shown that for severely cloud‐filtered images, the system was effective in generating geometrically precise image products, with geolocation errors less than a pixel. The developed system can be operated with no human intervention and can be used as an important tool for NOAA‐AVHRR image users especially those who need to use long time series.

AVHRR-based mapping of fires in Russia: New products for fire management and carbon cycle studies

A new database of fire activity in Russia derived from 1-km resolution remote sensing imagery is presented and discussed. The procedure used to generate this burned-area product is described, including active-fire detection and burn-scar mapping approaches. Fire detection makes use of a probabilistic procedure using image data from the United States National Oceanic and Atmospheric Administration's (NOAA) advanced very high resolution radiometer (AVHRR) system. Using the combination of AVHRR data collected at the Krasnoyarsk, Russia, high-resolution picture transmission (HRPT) receiving station, and data from the NOAA Satellite Active Archive (SAA), fire maps are being created for all of Russia for 1995 to 1997 and all of Eastern Russia (east of the Ural Mountains) for 1995 to 2002. This mapping effort has resulted in the most complete set of historic fire maps available for Russia. An initial validation indicates that the burned-area estimates are conservative because the approaches do not detect smaller fires, and, in many cases, fire areas are slightly underestimated. Analyses using the fire database showed that an average of 7.7×10 6 ha yr −1 of fire occurred in Eastern Russia between 1996 and 2002 and that fire was widely dispersed in different regions. The satellite-based burned-area estimates area were two to five times greater than those contained in official government burned-area statistics. The data show that there is significant interannual variability in area burned, ranging between a low of 1.5×10 6 ha in 1997 to a high of 12.1×10 6 ha in 2002. Seasonal patterns of fire are similar to patterns seen in the North American boreal region, with large-fire seasons experiencing more late-season burning (in August and September) than during low-fire years. There was a distinct zonal distribution of fires in Russia; 65% of the area burned occurred in the taiga zone, which includes southern, middle, and northern taiga subzones, 20% in the steppe and forest steppe zones, 12% in the mixed forest zone, and 3% in the tundra and forest-tundra zones. Lands classified as forest experienced 55% of all burned area, while crops and pastures, swamps and bogs, and grass and shrubs land cover categories experienced 13% to 15% each. Finally, the utility of the products is discussed in the context of fire management and carbon cycling.

PACS experience as a motivation for a campus-wide picture network. 1986.

PICTURE ARCHIVING AND COMMUNICATION SYSTEMS (PACS) have so far been studied primarily as a tool to address the problems of electronic radiology. Certainly the trends toward digital imaging within radiology provide strong economic and medical incentives for the development of medical picture networks, but we believe that the applications for picture networks extend far beyond the field of radiology. Architects, engineers, biologists—practitioners of virtually every academic and commercial pursuit—deal with picture information every day, and increasingly these pictures are finding their way into digital form. We believe that industries and universities of the future will utilize sophisticated workstations serving a variety of scientific and commercial needs, and that these workstations will be linked by wideband networks capable of supporting not only text but high-resolution picture transmission as well. The technical problems are similar both within and outside the field of radiology. In order to develop an electronic picture network, it is necessary to develop high-performance, low-cost components which will serve each of the three major elements of a PACS—archive, network, and display. The high data rates required for picture transmission will stretch performance requirements far beyond those of a typical local area network, and require state-of-the-art technology for many elements of the system design. We continue to find that it is difficult to define and develop the basic PACS elements independently or without the application area context. Decisions regarding network configuration, for example, affect design decisions for the organization of a display. A comprehensive approach is required and, consequently, prototype PACS networks serve a useful purpose as a test bed for the evolution and evaluation of system concepts and component design. Washington University has made a significant committment to the development of a prototype PACS network. Initially, in 1981, modeling experiments were carried out to define the requirements of a picture network suitable for radiology.1 A prototype broadband network was designed, built, and installed in the medical center in 1983. Comprising approximately 1.5 miles of cable, the network served as an experimental laboratory for the transmission of video as well as low- and high-speed digital data.2 In 1984, links were established within the Mallinckrodt Institute of Radiology (MIR is the radiology department of Washington University) between the prototype image management system and the comprehensive patient information system developed at MIR, making it possible, at prototype workstations throughout the department, to retrieve image data stored in a prototype central image archive.3 In 1985, the scope of the prototype broadband network was increased as the Institute for Biomedical Computing at Washington University established an image presentation, analysis, and quantification (IPAQ) facility. The goal of this major project is to provide additional network connectivity supported by a center capable of providing tools and computational assistance required for the processing of medical images. In 1985, based on earlier PACS work at the medical center, a three-year project was begun to design and develop a campus-wide picture network capable of spanning the University from the medical center campus to the hilltop campus, three miles away. The objective of this fifteen-million-dollar project, undertaken in cooperation with Digital Equipment Corporation, was to develop a state-of-the-art wideband network capable of manipulating and transmitting pictures in addition to symbols and graphs. This picture network will cover all schools and departments of the University and will eventually extend outward into the community served by the University. Throughout this period of aggressive expansion of PACS research at Washington University, the enduring objective has been to establish a “workbench” for PACS development—to provide the tools, the resources, and the environment where experiments can be carried out to evaluate various alternatives for the design of the components required for network, archive, and display. Our goal at this time is not to build the ideal PACS network, but rather, in an ambitious time frame, to design and construct, in cooperation with industry, a large scale PACS prototype that will serve as a proving ground for picture networks of the future.

Antarctic Satellite Meteorology: Applications for Weather Forecasting

For over 30 years, weather forecasting for the Antarctic continent and adjacent Southern Ocean has relied on weather satellites. Significant advancements in forecasting skill have come via the weather satellite. The advent of the high-resolution picture transmission (HRPT) system in the 1980s and 1990s allowed real-time weather forecasting to become a reality. Small-scale features such as mesocyclones and polar lows could be tracked and larger-scale features such as katabatic winds could be detected using the infrared channel. Currently, HRPT is received at most of the manned Antarctic stations. In the late 1990s the University of Wisconsin composites, which combined all available polar and geostationary satellite imagery, allowed a near-real-time hemispheric view of the Southern Ocean and Antarctic continent. The newest generation of satellites carries improved vertical sounders, special sensors for microwave imaging, and the Moderate Resolution Imaging Spectroradiometer (MODIS) sensor. In spite of the advances in sensors, shortcomings still impede the forecaster. Gaps in satellite data coverage hinder operations at certain times of the day. The development and implementation of software to derive products and visualize information quickly has lagged. The lack of high-performance communications links at many of the manned stations reduces the amount of information that is available to the forecasters. Future applications of weather satellite data for Antarctic forecasting include better retrievals of temperature and moisture and more derived products for fog, cloud detection, and cloud drift winds. Upgrades in technology at Antarctic stations would allow regional numerical prediction models to be run on station and use all the current and future satellite data that may be available.

Retrieval of atmospheric parameters from NOAA-16 AMSU data over Indian region - Preliminary results

With the establishment of a new High Resolution Picture Transmission (HRPT) reception system at IMD, New Delhi, the real time data from microwave sounding instruments onboard the NOAA-K, L, M and N series of satellites has also become available. The raw HRPT data is being interfaced with the recently acquired new ‘ATOVS and AVHRR Preprocessing Package (AAPP)’ to perform temperature and moisture retrievals from AMSU data of NOAA-16 satellite using two separate schemes: Inversion Coupled Imager (ICI) and Neural Network (NN) approach. In this study, NOAA-16 satellite data over Indian region were used for retrieving temperature and moisture profiles for the month of January, 2002. The temperature and moisture retrieval results are evaluated by computing the bias and root mean square (RMS) difference using collocated ECMWF analysis. The results based on the analysis of data set for the month of January, 2002 shows that ICI approach yields better results for all atmospheric levels. The RMS errors in temperature profiles are found to be less than 4oC at all pressure levels. The RMS errors in relative humidity are found to be less than 20% at all pressure levels. C Intercomparison of the results revealed that bias and RMS error are less for ICI scheme using forecast field compared to ICI without using forecast field and Neural Network approach.

Removing Unwanted Fluctuations in the AVHRR Thermal Calibration Data Using Robust Techniques

The study deals with analysis of thermal calibration of the Advanced Very High Resolution Radiometer (AVHRR) aboard National Oceanic and Atmospheric Administration (NOAA) spacecrafts. In particular, the effects caused by various types of contamination or corruption of the thermal calibration data are investigated. These phenomena lead to perturbations of the true signal, referred to here as unwanted fluctuations. They must be removed or corrected to maximum possible extent to reduce the error in the calibrated data. It is shown that methods currently employed in operational practice at NOAA and the Canada Centre for Remote Sensing (CCRS) frequently fail to remove some of the unwanted fluctuations in calibration data that may lead to biases in brightness temperature exceeding 1 K. A complex method for removing unwanted fluctuations in the thermal calibration data specifically designed for the AVHRR radiometers is proposed. The procedure is based on combining robust statistical procedures and Fourier transform filtering techniques. Application of the method is considered for various components of calibration data: temperature sensors, blackbody, and space count, as well as gain in all thermal channels. High Resolution Picture Transmission (HRPT) data and Global Area Coverage (GAC) data are analyzed. Power spectra analysis of the calibration data has been conducted to estimate impact of various frequency harmonics. The method proposed may be useful for the development of calibration techniques for similar radiometers and the future National Polar-Orbiting Operational Environmental Satellite System.

Normalization and comparison of surface temperatures across a range of scales

The Southern Great Plains 1999 (SGP99) Experiment, conducted in Oklahoma, July 8-21, 1999, provided an opportunity to observe spatial and temporal variations in surface temperature. During the experiment, aircraft (Passive/Active L/S-band airborne sensor) and satellite [Advanced Very High Resolution Radiometer (AVHRR) and TIROS Operational Vertical Sounder (TOVS)] sensors collected surface temperature that was compared to in situ observations over the same time period to determine the accuracy and consistency of surface temperature measurements at different spatial resolutions using remotely sensed data. In addition, in situ surface temperature was observed in a 400/spl times/400 m field at various spatial grid spacing: 50 m, 10 m, and 1 m in order to quantify the variability of the spatially distributed behavior of surface temperature during a drydown period. Average differences between the in situ surface temperature observations and the aircraft and satellite sensors utilized during this study ranged from 0.7/spl deg/C (AVHRR High Resolution Picture Transmission) to more than 20/spl deg/C (AVHRR Global Area Coverage (GAC), TOVS). We have shown that the temporal adjustments of the remotely sensed surface temperatures (from aircraft and satellite sensors) shows a better comparison to in situ ground data. A ratio was set up using information derived from a mosaic land surface model to temporally locate the various estimates of surface temperature. The corrected surface temperature comparisons decreased the average differences (with in situ) to as much as 78% [AVHRR (GAC)] and as little as 6% (TOVS). The average difference between remotely sensed and in situ observations was around 48%.

Science and Technology for Individuals, Societies, and the Environment and Satellite Technologies: Advanced High Resolution Picture Transmission Applications for the Science Classrooms

This article introduces a satellite technology, High Resolution Picture Transmission (HRPT), for a science activity. HRPT is a digital data stream transmitted from environmental satellites. The HRPT imagery is capable of providing real-time studies of regional geology, glacial processes, atmospheric processes, ocean circulation, coastal processes, hydrology, and so on. Obtaining and manipulating HRPT data creates a variety of exciting experiences in science classrooms. A Science and Technology for Individuals, Societies, and the Environment (STISE) teaching model was developed to use satellite technologies for science activities. STISE is a conceptual model for addressing key cognitive and affective parameters when designing science lessons. STISE is designed to encourage students to understand science and technology from their levels of cognition, then relate their understanding to the environment, levels of societies, and their lives. Relationships among science, technology, and society become both obvious and interesting to students as they process and interpret the HRPT imagery.

Satellite Observation of Upwelling along the Western Coast of the South China Sea

We observed the evolution of upwelling along the western coast of the South China Sea (SCS). The data we used are NOAA (National Oceanic and Atmospheric Administration) satellite AVHRR (Advanced Very High Resolution Radiometer) IR (infrared) images taken in 1996 and 1997 summer at the HRPT (High Resolution Picture Transmission) receiving station built on Tai-Ping Island, which is located in the central SCS. An upwelling intensity, defined by the total heat loss in the upwelling cold water region, is used to determine the relationship between coastal upwelling and the wind stress derived from the ERS-2 (European Remote Sensing Satellite) data. The results show that the upwelling intensity has a good linear relationship with the total alongshore wind stress while it has a low correlation with the cross-shore component of wind stress. These results imply that the alongshore wind stress is the main factor to pump the cold water up to the sea surface layer. Meanwhile, the satellite infrared images also indicate that the centroid of cold water moved southward from 15°N to 11°N during the observation period. The size of upwelling area changed as well, and finally evolved into a cold jet stretching offshore along 11°N–12°N in the mid-August 1997. Satellite infrared and altimeteric data show that the evolution of upwelling region is closely associated with the development of two anticyclonic circulations in the western SCS.

New radiance-based method for AVHRR thermal channel nonlinearity corrections

Thermal channels 4 and 5 of the Advanced Very High Resolution Radiometer (AVHRR) on National Oceanic and Atmospheric Administration (NOAA) polar-orbiting satellites have an onboard calibration process that provides data from which incoming scene radiance is linearly related to AVHRR count output. However, prelaunch calibration tests show that the radiance is more accurately modelled as a quadratic in count value and that the actual quadratic fit depends upon the operating temperature of the AVHRR itself. NOAA has developed a new method to provide prelaunch information to operational data users that is both concise and accurate. It corrects the linear radiance estimate instead of correcting equivalent blackbody temperature values. The nonlinear correction to the linear radiance estimate is provided by a single quadratic equation, independent of the AVHRR temperature. The new method was first applied to the NOAA-14 AVHRR. When corrected radiance estimates for the NOAA-14 AVHRR are compared to precise prelaunch data, the rms difference is 0.14K in channel 4 and 0.08K in channel 5, in temperature units. At present, users of NOAA-14 AVHRR 1b data have to apply the radiance correction themselves, but for the NOAA-15 and future AVHRRs the necessary information is included in the expanded 1b datastream. Direct readout High Resolution Picture Transmission (HRPT) users have to implement the correction process themselves for NOAA-14, NOAA-15 and future AVHRRs.

Operational value-adding to AVHRR data over Europe: methods, results, and prospects

The German Remote Sensing Data Center (DFD) of the German Aerospace Center (DLR) has been operating a ground segment for High Resolution Picture Transmission (HRPT) data acquisition, archiving, and distribution since the early 1980s. The station's visibility covers all of Europe. DFD started with the generation of thematic level-3 AVHRR value-added products consisting of Multichannel Sea Surface Temperatures (MCSST) and Normalized Difference Vegetation Indices (NDVI) in March 1993 [8]. Additionally, calibrated and registered 5-channel image subsets in two areas have been generated for supporting user-specific applications since 1994 [8]. The status of the current level-3 product generation chain as well as corresponding processing algorithms are presented. Perspectives are introduced to improve the existing products in terms of channel 1 and 2 radiometric optimization by implementing an atmospheric correction scheme, as well as to correct the solar channels for anisotropic reflectance with respect to different surfaces. As AVHRR data proved to be one of the major sources to derive global information on different land-oriented parameters, special emphasis is given in this paper on methods to extract land cover, the fraction of Absorbed Photosynthetic Active Radiation (fAPAR), and Leaf Area Index (LAI) with respect to operational use. Furthermore, different algorithms were discussed to derive Land Surface Temperatures (LST) by estimating surface emissivity based on NDVI time synthesis. First results over Germany are shown, problems addressed, and outlines for operational usage are given.