Your search keyword '"Lemmetyinen, Juha"' showing total 18 results

1. Effects of Arctic Wetland Dynamics on Tower-Based GNSS Reflectometry Observations.

Author

Steiner, Ladina, Fabra, Fran, Rautiainen, Kimmo, Lemmetyinen, Juha, Cohen, Juval, and Cardellach, Estel

Subjects

GLOBAL Positioning System, WETLANDS, REFLECTOMETRY, TUNDRAS, WETLANDS monitoring, SNOW cover

Abstract

A tower-based global navigation satellite system reflectometry (GNSS-R) experiment is set up in an Arctic wetland environment for investigating the possibility of monitoring wetland inundation and freeze/thaw (FT) dynamics which are additionally impacted by snow on the ground. Effects of inundation, snow cover, and soil FT state on observed GNSS-R signal-to-noise ratios (SNRs) are analyzed for horizontal (H) and vertical (V) polarizations. A simple classification approach is suggested to detect the inundated, frozen, or thawed soil state. A simple forward reflectivity model is formulated to evaluate the influence of snow cover, overlying frozen, or thawed soil, on the reflected GNSS signals. Reflectivity time series are simulated in H- and V-polarizations using in situ observations of the Arctic wetland site. The simulations are used to verify the tower-based observations, which show a significant impact of wet snow on reflectivity during melting conditions in spring. The observed SNR is strongly correlated with the Sentinel-1 backscatter coefficient. Generally, soil states detected by GNSS-R are in high agreement with ground truth soil states, especially for inundated and frozen soils. Wet snow conditions, however, complicate the correct timing estimation of soil thawing by inducing reflectivities of a similar order as thawing soil. It is recommended that GNSS-R land application models and retrieval algorithms consider snow cover effects to reduce false classification, especially in FT detection. Overall, the outcome of this study is relevant to the upcoming ESA HydroGNSS mission. [ABSTRACT FROM AUTHOR]

Published

2022

2. Exploiting the ANN Potential in Estimating Snow Depth and Snow Water Equivalent From the Airborne SnowSAR Data at X- and Ku-Bands.

Author

Santi, Emanuele, Brogioni, Marco, Leduc-Leballeur, Marion, Macelloni, Giovanni, Montomoli, Francesco, Pampaloni, Paolo, Lemmetyinen, Juha, Cohen, Juval, Rott, Helmut, Nagler, Thomas, Derksen, Chris, King, Joshua, Rutter, Nick, Essery, Richard, Menard, Cecile, Sandells, Melody, and Kern, Michael

Subjects

SNOW accumulation, SYNTHETIC aperture radar, ARTIFICIAL neural networks, WATER depth, RADIATIVE transfer, AIRBORNE lasers, STOCHASTIC dominance

Abstract

Within the framework of European Space Agency (ESA) activities, several campaigns were carried out in the last decade with the purpose of exploiting the capabilities of multifrequency synthetic aperture radar (SAR) data to retrieve snow information. This article presents the results obtained from the ESA SnowSAR airborne campaigns, carried out between 2011 and 2013 on boreal forest, tundra and alpine environments, selected as representative of different snow regimes. The aim of this study was to assess the capability of X- and Ku-bands SAR in retrieving the snow parameters, namely snow depth (SD) and snow water equivalent (SWE). The retrieval was based on machine learning (ML) techniques and, in particular, of artificial neural networks (ANNs). ANNs have been selected among other ML approaches since they are capable to offer a good compromise between retrieval accuracy and computational cost. Two approaches were evaluated, the first based on the experimental data (data driven) and the second based on data simulated by the dense medium radiative transfer (DMRT). The data driven algorithm was trained on half of the SnowSAR dataset and validated on the remaining half. The validation resulted in a correlation coefficient $R \simeq 0.77$ between estimated and target SD, a root-mean-square error (RMSE) $\simeq 13$ cm, and bias = 0.03 cm. ANN algorithms specific for each test site were also implemented, obtaining more accurate results, and the robustness of the data driven approach was evaluated over time and space. The algorithm trained with DMRT simulations and tested on the experimental dataset was able to estimate the target parameter (SWE in this case) with $R =0.74$ , RMSE = 34.8 mm, and bias = 1.8 mm. The model driven approach had the twofold advantage of reducing the amount of in situ data required for training the algorithm and of extending the algorithm exportability to other test sites. [ABSTRACT FROM AUTHOR]

Published

2022

3. X-Ray Tomography-Based Microstructure Representation in the Snow Microwave Radiative Transfer Model.

Author

Sandells, Melody, Lowe, Henning, Picard, Ghislain, Dumont, Marie, Essery, Richard, Floury, Nicolas, Kontu, Anna, Lemmetyinen, Juha, Maslanka, William, Morin, Samuel, Wiesmann, Andreas, and Matzler, Christian

Subjects

RADIATIVE transfer, MICROWAVE scattering, X-rays, MICROWAVES, BRIGHTNESS temperature, CHEMICAL ionization mass spectrometry

Abstract

The modular Snow Microwave Radiative Transfer (SMRT) model simulates microwave scattering behavior in snow via different selectable theories and snow microstructure representations, which is well suited to intercomparisons analyses. Here, five microstructure models were parameterized from X-ray tomography and thin-section images of snow samples and evaluated with SMRT. Three field experiments provided observations of scattering and absorption coefficients, brightness temperature, and/or backscatter with the increasing complexity of snowpack. These took place in Sodankylä, Finland, and Weissfluhjoch, Switzerland. Simulations of scattering and absorption coefficients agreed well with observations, with higher errors for snow with predominantly vertical structures. For simulation of brightness temperature, difficulty in retrieving stickiness with the Sticky Hard Sphere microstructure model resulted in relatively poor performance for two experiments, but good agreement for the third. Exponential microstructure gave generally good results, near to the best performing models for two field experiments. The Independent Sphere model gave intermediate results. New Teubner–Strey and Gaussian Random Field models demonstrated the advantages of SMRT over microwave models with restricted microstructural geometry. Relative model performance is assessed by the quality of the microstructure model fit to micro-computed tomography (CT) data and further improvements may be possible with different fitting techniques. Careful consideration of simulation stratigraphy is required in this new era of high-resolution microstructure measurement as layers thinner than the wavelength introduce artificial scattering boundaries not seen by the instrument. [ABSTRACT FROM AUTHOR]

Published

2022

4. Atmospheric Correction to Passive Microwave Brightness Temperature in Snow Cover Mapping Over China.

Author

Qiu, Yubao, Shi, Lijuan, Lemmetyinen, Juha, Shi, Jiancheng, and Wang, Robert Yu

Subjects

PRECIPITABLE water, BRIGHTNESS temperature, SNOW cover, WEATHER, MICROWAVES, SURFACE of the earth

Abstract

Variable atmospheric conditions are typically ignored in the retrieval of geophysical parameters of the Earth’s surface when using spaceborne passive microwave observations. However, high frequencies, for example, 91.7 GHz, are sensitive to variable atmospheric absorption, even in winter’s dry conditions. In this article, the influence of variable atmospheric absorption on snow cover extent (SCE) mapping was quantitatively investigated. A physical method was derived to enable atmospheric correction for variable atmospheric conditions. The total column precipitable water vapor (TPWV) from Moderate Resolution Imaging Spectroradiometer (MODIS) was parametrized into transmittances in this correction method. The corrected brightness temperature at 19 and 91.7 GHz from the Special Sensor Microwave Imager Sounder (SSMIS) was applied to the threshold algorithm for snow mapping over China. Compared with the Interactive Multisensor Snow and Ice Mapping System (IMS) data in winter from 2012 to 2013, for Qinghai–Tibet plateau (QTP), a significant improvement after correction was obtained from February to March over ephemeral and shallow snow, where the largest daily improvement of accuracy is up to 20%. The accuracy (incl. precision, recall, and F1 index) improved on average is from 0.77 (0.60, 0.68, and 0.63) to 0.79 (0.69, 0.7, and 0.68) over the full winter time from December to March. Over forest-rich Northeast China, where snow in winter is thicker, small improvement was observed at the onset of the snow season and over snow margin area. It was evidenced that high frequency is a promising way of snow cover mapping with the proposed atmospheric correction method. [ABSTRACT FROM AUTHOR]

Published

2021

5. Derivation and Evaluation of a New Extinction Coefficient for Use With the n-HUT Snow Emission Model.

Author

Maslanka, William, Sandells, Melody, Gurney, Robert, Lemmetyinen, Juha, Leppanen, Leena, Kontu, Anna, Matzl, Margret, Rutter, Nick, Watts, Tom, and Kelly, Richard

Subjects

SNOW, BIOLOGICAL extinction, BRIGHTNESS temperature, PERMITTIVITY, ABSORPTION coefficients, INSULIN aspart

Abstract

In this study, snow slab data collected from the Arctic Snow Microstructure Experiment were used in conjunction with a six-directional flux coefficient model to calculate individual slab absorption and scattering coefficients. These coefficients formed the basis for a new semiempirical extinction coefficient model, using both frequency and optical diameter as input parameters, along with the complex dielectric constant of snow. Radiometric observations, at 18.7, 21.0, and 36.5 GHz at both horizontal polarization (H-Pol) and vertical polarization (V-Pol), and snowpit data collected as part of the Sodankylä Radiometer Experiment were used to compare and contrast the simulated brightness temperatures produced by the multi-layer Helsinki University of Technology snow emission model, utilizing both the original empirical model and the new semiempirical extinction coefficient model described here. The results show that the V-Pol RMSE and bias values decreased when using the semiempirical extinction coefficient; however, the H-Pol RMSE and bias values increased on two of the lower microwave bands tested. The unbiased RMSE was shown to decrease across all frequencies and polarizations when using the semiempirical extinction coefficient. [ABSTRACT FROM AUTHOR]

Published

2019

6. The Influence of Thermal Properties and Canopy- Intercepted Snow on Passive Microwave Transmissivity of a Scots Pine.

Author

Li, Qinghuan, Kelly, Richard, Leppanen, Leena, Vehvilainen, Juho, Kontu, Anna, Lemmetyinen, Juha, and Pulliainen, Jouni

Subjects

THERMAL properties, SCOTS pine, SNOW accumulation, SNOW cover, MICROWAVES, SKIN temperature

Abstract

While many microwave studies related to tree emission have been undertaken, a few have considered the effect of phenological change on the emission from coniferous trees. The permittivity of vegetation tissue is known to be influenced by water content, while the water content and phase is sensitive to temperature in particular at temperatures below freezing. In addition to temperature, canopy-intercepted snow might also modify the tree emission and transmissivity in the microwave range. In this paper, a season-long experiment was designed to quantify the effect of snow accumulation and temperature on the observed microwave transmissivity from tree. A ground-based, upward-pointing multifrequency radiometer was used to monitor the microwave emissivity of a single coniferous tree at a site in Northern Finland. Radiometer measurements were combined with measurements of the canopy-intercepted snow cover and tree skin temperature. This paper presents two important findings. First, the tree transmissivity was strongly correlated with tree skin temperature under subzero temperature conditions, but uncorrelated with skin temperature changes above freezing. Second, although the tree transmissivity was slightly affected by the snow accumulation on the tree canopy, the overall influence on tree emission was statistically insignificant in this paper. [ABSTRACT FROM AUTHOR]

Published

2019

7. A Modeling-Based Approach for Soil Frost Detection in the Northern Boreal Forest Region With C-Band SAR.

Author

Cohen, Juval, Rautiainen, Kimmo, Ikonen, Jaakko, Lemmetyinen, Juha, Smolander, Tuomo, Vehvilainen, Juho, and Pulliainen, Jouni

Subjects

SYNTHETIC aperture radar, TAIGAS, FORESTS & forestry, VEGETATION mapping, CLASSIFICATION algorithms, MICROWAVE imaging

Abstract

This paper presents a new approach for monitoring soil frost in the northern boreal forest region using co-polarized C-band synthetic aperture radar (SAR) data. Due to the high sensitivity of the C-band signal to vegetation, estimating the soil freeze/thaw (F/T) state directly from the measured backscatter is not feasible over dense vegetation, such as boreal forests. The presented method is based on applying a simple zeroth-order model to estimate the contribution of the ground and the forest canopy on the observed total backscatter. The retrieved ground and canopy backscatter values were compared with in situ information on soil F/T state. By using a linear least sum of square errors classification algorithm, the retrieved ground and canopy backscatter values representing frozen and thawed ground were successfully separated. The method was tested for various soil types and incidence angles. For soil types with higher water holding capacities and lower infiltration rates such as fine Haplic Podzol and Umbric Gleysol, the estimation accuracy of the F/T state was over 97%, whereas for drier, well-drained soil types such as Haplic Arenosol and Coarse Haplic Podzol it was over 94%. Estimation accuracy slightly increased with higher incidence angle. The method is not feasible in rocky terrain due to very low water content, or in wet snow conditions due to lack of penetration of the C-band SAR signal through wet snow. With low ancillary data and computational requirements, the proposed method is applicable for continuous near real-time monitoring of soil F/T state. [ABSTRACT FROM AUTHOR]

Published

2019

8. Forward and Inverse Radar Modeling of Terrestrial Snow Using SnowSAR Data.

Author

Zhu, Jiyue, Tan, Shurun, King, Joshua, Derksen, Chris, Lemmetyinen, Juha, and Tsang, Leung

Subjects

MICROWAVE remote sensing, RADIATIVE transfer, SNOWPACK augmentation, STANDARD deviations, INFORMATION retrieval, TUNDRAS

Abstract

In this paper, we develop a radar snow water equivalent (SWE) retrieval algorithm based on a parameterized forward model of bicontinuous dense media radiative transfer (Bic-DMRT). The algorithm is based on retrieving the absorption loss of the snowpack which is directly proportional to the SWE. In the algorithm, Bic-DMRT is first applied to generate a lookup table (LUT) of snowpack backscattering at X- and Ku-band. Regression training is applied to the LUT to transform the dual-frequency backscatter into functions of two parameters: the scattering albedo at X-band and SWE. The background scattering is subtracted from the SnowSAR data to give the volume scattering of snow. Classification of SnowSAR data is applied to provide a priori information. Based on the obtained volume scattering and the priori information, a cost function is established to find SWE. Performance of the retrieval algorithm was tested using three sets of airborne SnowSAR data acquired over mixed areas in Finland and open tundra landscape in Canada. It is shown that the retrieval algorithm has a root-mean-square error below 30 mm of SWE and a correlation coefficient above 0.64. [ABSTRACT FROM AUTHOR]

Published

2018

9. Differences Between the HUT Snow Emission Model and MEMLS and Their Effects on Brightness Temperature Simulation.

Author

Pan, Jinmei, Durand, Michael, Sandells, Melody, Lemmetyinen, Juha, Kim, Edward J., Pulliainen, Jouni, Kontu, Anna, and Derksen, Chris

Subjects

MICROWAVE propagation, SNOW, MELTWATER, RADIATIVE transfer equation, SCATTERING (Mathematics), BORN approximation

Abstract

Microwave emission models are a critical component of snow water equivalent retrieval algorithms applied to passive microwave measurements. Several such emission models exist, but their differences need to be systematically compared. This paper compares the basic theories of two models: the multiple-layer Helsinki University of Technology (HUT) model and the microwave emission model of layered snowpacks (MEMLS). By comparing the mathematical formulation side by side, three major differences were identified: 1) by assuming that the scattered intensity is mostly (96%) in the forward direction, the HUT model simplifies the radiative transfer equation in 4\pi space into two one-flux equations, whereas MEMLS uses a two-flux theory; 2) the HUT scattering coefficient is much larger than the one of MEMLS; and 3) MEMLS considers the trapped radiation inside snow due to internal reflection by a six-flux model, which is not included in HUT. Simulation experiments indicate that the large scattering coefficient of the HUT model compensates for its large forward scattering ratio to some extent, but the effects of one-flux simplification and the trapped radiation still result in different T_{B} simulations between the HUT model and MEMLS. The models were compared with observations of natural snow cover at Sodankylä, Finland; Churchill, Canada; and Colorado, USA. No optimization of the snow grain size was performed. It shows that the HUT model tends to underestimate T_{B}$ for deep snow. MEMLS with the physically based improved Born approximation performed best among the models, with a bias of −1.4 K and a root-mean-square error of 11.0 K. [ABSTRACT FROM PUBLISHER]

Published

2016

10. The Effect of Boreal Forest Canopy in Satellite Snow Mapping—A Multisensor Analysis.

Author

Cohen, Juval, Lemmetyinen, Juha, Pulliainen, Jouni, Heinila, Kirsikka, Montomoli, Francesco, Seppanen, Jaakko, and Hallikainen, Martti T.

Subjects

*TAIGAS, *FOREST canopy ecology, *PASSIVE components, *CRYOSPHERE, *GEOGRAPHIC spatial analysis

Abstract

Satellite-based snow-cover monitoring is performed using optical, synthetic aperture radar (SAR), and passivemicrowave sensors. Effects of forest canopy on the observed signal need to be considered with all of these sensor types. Various models describing the interaction of electromagnetic radiation with forest canopy have been developed, but many of these are overly complex with high computational and ancillary data requirements. However, for retrieval purposes, simple models are preferred. This work aims at increasing the understanding of the effect of forest canopy on remote sensing observations of snow-covered terrain for both microwave and optical regimes and at quantifying the capability of simple zeroth-order models in simulating these effects. To achieve these goals, a spatial analysis of optical, SAR, and passive-microwave remote sensing data in the northern boreal forest region was performed. Model parameters for vegetation transmissivity as well as the properties of the underlying surface were optimized by utilizing lidar-ranging- and Landsat-based simplified proxy parameters describing forest canopy closure and stem volume. The results demonstrated that despite using these relatively simple proxies, a zeroth-order model can accurately estimate the extinction of electromagnetic signals in a forest, particularly for passive microwave and optical data. The SAR model successfully estimated the median of the observations, but larger scatter of the observations was reflected by a higher root mean square error and lower correlation between models and observations. Due to both good estimation accuracy and simplicity, the presented models can be considered to be applicable in existing snow retrieval algorithms. [ABSTRACT FROM PUBLISHER]

Published

2015

11. Observation and Modeling of the Microwave Brightness Temperature of Snow-Covered Frozen Lakes and Wetlands.

Author

Kontu, Anna, Lemmetyinen, Juha, Pulliainen, Jouni, Seppanen, Jaakko, and Hallikainen, Martti T.

Subjects

*ICE, *SNOW cover, *MICROWAVES, *BODIES of water, *SIMULATION methods & models

Abstract

Small-scale variability in land cover influences both the snow cover and the microwave response of a snow-covered surface. Since low microwave frequencies penetrate below the snowpack, the differing dielectric properties of soil and water have a significant effect on passive microwave observations and therefore cause errors in the interpretation of snow parameters from satellite data. Here, the brightness temperature of snow- and ice-covered lakes and wetlands is studied using airborne and spaceborne microwave radiometer observations and modeling of brightness temperature from in situ measurements. We aim at assessing the validity of the multilayer Helsinki University of Technology (HUT) snow emission model on lake- and wetland-rich areas and at examining the error from omission of water bodies in the forward modeling of brightness temperature. The results indicate that the model can estimate brightness temperatures of lakes and wetlands with rms errors of 12-28 K and 9-16 K, respectively. The inclusion of lakes in the satellite-scale simulations reduces the simulation error in 52%-100% of the simulated areas at 18.7 and 36.5 GHz. The inclusion of wetlands further improves simulations, resulting in an rms error of satellite scenes of 4-5 K at 18.7 and 36.5 GHz (5-10 K without lakes and wetlands). However, the natural variability of brightness temperature over water bodies is not entirely captured particularly at 10.65 GHz. The inclusion of lakes and wetlands can be used to reduce errors in the forward model and thus increase the accuracy of snow parameters derived from satellite data. [ABSTRACT FROM PUBLISHER]

Published

2014

12. Detection of a Sea Surface Salinity Gradient Using Data Sets of Airborne Synthetic Aperture Radiometer HUT-2-D and a GNSS-R Instrument.

Author

Kainulainen, Juha, Rautiainen, Kimmo, Lemmetyinen, Juha, Hallikainen, Martti T., Martin-Porqueras, Fernando, and Martin-Neira, Manuel

Subjects

OCEAN surface topography, SALINITY, SYNTHETIC aperture radar, RADIOMETERS, GLOBAL Positioning System, INTERFEROMETRY, AREA measurement

Abstract

L-band radiometry is widely considered the best technique for Earth observing satellites to measure sea surface salinity (SSS). Interferometric aperture synthesis is a new technology applicable in spaceborne remote sensing at low frequencies. The challenge of the technology comes with decreased radiometric resolution and complexity in calibration compared to conventional radiometer systems. Due to these issues and the overall newness of the concept, validation of the technology for salinity retrieval purposes is desired. In this paper, we describe an intense measurement campaign carried out with the complete interferometric aperture synthesis radiometer system HUT-2-D, designed and operated by the Helsinki University of Technology. The campaign aimed at the detection of a changing salinity level in the Baltic Sea, in the coastal areas of Finland. We describe the campaign comprising details of the ground truth collection, sea surface emission modeling, and radiometric data analysis. We have a special emphasis on the assessment of the impact of the sea state on the radiometric measurements, which is considered one of the major obstacles for SSS retrieval at the L-band. For this purpose, we present a new correlation between sea roughness information collected with the Global Navigation Satellite System reflectometer and radiometric data measured by an L-band radiometer system. [ABSTRACT FROM AUTHOR]

Published

2011

13. Experimental Study on Radiometric Performance of Synthetic Aperture Radiometer HUT-2D—Measurements of Natural Targets.

Author

Kainulainen, Juha, Rautiainen, Kimmo, Lemmetyinen, Juha, Seppanen, Jaakko, Sievinen, Pauli, Takala, Matias, and Hallikainen, Martti T.

Subjects

SYNTHETIC apertures, RADIOMETERS, REMOTE sensing, TEMPERATURE measurements, INTERFEROMETRY, PIXELS, ACQUISITION of data, COSMIC background radiation

Abstract

This paper describes the analysis of L-band radiometric measurement data gathered with the synthetic aperture radiometer HUT-2D during several ground-based and airborne measurement campaigns. The radiometric data are analyzed from the instrument's performance point of view, aiming to verify the theoretical performance of an instrument of this kind and to assess the performance of the HUT-2D radiometer system in particular. The data sets considered for the study consist of measurements of well-known natural targets, such as cosmic background radiation, and measurements of pure water scenes, the brightness temperature of which is possible to model based on in situ measurements. We define four figures of merit, which are applicable for synthetic aperture radiometers. These are radiometric resolution, image bias, pixel-to-pixel random error, and temporal stability. Then, we use the selected data sets to assess these in the case of HUT-2D. The experimental results are discussed and compared to the theoretical values, where applicable. Also, we discuss possibilities to improve the presented performance. The main results of this paper are the consolidated performance parameters of the HUT-2D instrument. We study and discuss the properties of the error components related to the technology in a general level, and study the scalability of the errors as a function of the measured targets. In particular, the stability of the direction-dependent error component is pointed out, and a mitigation guideline is proposed. [ABSTRACT FROM AUTHOR]

Published

2011

14. Multiple-Layer Adaptation of HUT Snow Emission Model: Comparison With Experimental Data.

Author

Lemmetyinen, Juha, Pulliainen, Jouni, Rees, Andrew, Kontu, Anna, Yubao Qiu, and Derksen, Chris

Subjects

*MATHEMATICAL models, *MICROWAVES, *RADIOMETERS, *SNOW, *RADIO frequency discharges

Abstract

Modeling of snow emission at microwave frequencies is necessary in order to understand the complex relations between the emitted brightness temperature and snowpack characteristics such as density, grain size, moisture content, and vertical structure. Several empirical, semiempirical, and purely theoretical models for the prediction of snow emission properties have been developed in recent years. In this paper, we investigate the capability of one such model to simulate snow emission during the peak snow season--a new multilayer version of the Helsinki University of Technology (HUT) snow model. Developed with a single layer, the original HUT model was easily applied over large geographic areas for the estimation of snow cover characteristics by model inversion. A single homogenous layer, however, may not accurately allow the simulation of vertically structured natural snowpacks. The new modification to the model allows the simulation of emission from a snowpack with several snow or ice layers, with the individual component layers treated as in the original HUT model. The results of modeled snowpack emission, using both the original model and the new multilayer modification, are compared with reference measurements made using ground-based radiometers deployed in Finland and Canada. Detailed in situ measurements of the snowpack are used to set the model inputs.We show that, in most cases, use of the multiple-layer model improves estimates for the higher frequencies tested, with up to 38% improvement in rms error. In some cases, however, the use of the multiple-layer model weakens model performance particularly at lower frequencies. [ABSTRACT FROM AUTHOR]

Published

2010

15. Error Propagation in Calibration Networks of Synthetic Aperture Radiometers.

Author

Kainulainen, Juha, Lemmetyinen, Juha, Rautiainen, Kimmo, Colliander, Andreas, Uusitalo, Josu, and Lahtinen, Janne

Subjects

*ERRORS, *CALIBRATION, *SYNTHETIC aperture radar, *RADIOMETERS, *REMOTE sensing, *MICROWAVE imaging, *BRIGHTNESS temperature

Abstract

During the last two decades, the development of synthetic aperture radiometers for remote sensing has been studied intensively. One of the proposed methods for the calibration of such an instrument is the application of a distributed noise injection network. This paper focuses on the origin and effect of errors arising from this methodology. A generalized analytical method to calculate the accumulation of phase and amplitude errors in a distributed noise injection network is presented. This method is then applied to the Microwave Imaging Radiometer using Aperture Synthesis (MIRAS), the interferometric radiometer aboard the European Soil Moisture and Ocean Salinity satellite. The effect of the resulting errors to MIRAS' brightness temperature is analyzed. The presented method is applicable also to other interferometric radiometers, whose calibration relies on distributed noise injection. [ABSTRACT FROM AUTHOR]

Published

2009

16. A Comparison of Airborne Microwave Brightness Temperatures and Snowpack Properties Across the Boreal Forests of Finland and Western Canada.

Author

Lemmetyinen, Juha, Derksen, Chris, Pulliainen, Jouni, Strapp, Walter, Toose, Peter, Walker, Anne, Tauriainen, Simo, Pihlflyckt, Jörgen, Juha-Petri Kärnä, and Hallikainen, Martti T.

Subjects

*REMOTE sensing, *MICROWAVE remote sensing, *SNOW measurement, *TAIGAS, *RADIATION measurements, *SNOW-water equivalent, *SNOW density

Abstract

The seasonal snowpack across the boreal forest is an important national resource in both Canada and Finland, contributing freshwater for agriculture, human consumption, and hydropower generation. In both countries, satellite passive microwave data are utilized to provide operational information OH snow depth and snow water equivalent (SWE) throughout the snow cover season. Airborne passive microwave surveys conducted independently across Finland and western Canada during March and April 2005 and March 2006 provided the opportunity to assess the level of similarity in snowpack physical properties and brightness temperature response to snowpack qualities using two independent data sets. The primary objectives of these campaigns were to determine the influence of small-scale heterogeneity on satellite data, using relatively high resolution airborne measurements, and,to assess the Helsinki University of Technology (HUT) snow emission model capability of predicting emitted brightness temperatures under varying snowpack and landscape conditions. Comparisons of brightness temperature emissions over different land cover types showed a clear distinction of wetlands and snow-covered ice from forested and open areas. This is reflected also as a strong relationship between 6.9-GHz measurements and fractional lake cover in both Canada and Finland, with relationships at 18 and 37 GHz being less consistent between data sets. Comparisons of experimental data versus HUT snow emission model predictions showed relatively good agreement between the simulations and airborne data, specifically for the Finnish data set. [ABSTRACT FROM AUTHOR]

Published

2009

17. SMOS Calibration Subsystem.

Author

Lemmetyinen, Juha, Uusitalo, Josu, Kainulainen, Juha, Rautiainen, Kimmo, Fabritius, Nestori, Levander, Mikael, Kangas, Ville, Greus, Heli, Pihlflyckt, Jörgen, Kontu, Anna, Kemppainen, Sami, Colliander, Andreas, Hallikainen, Martti T., and Lahtinen, Janne

Subjects

*REMOTE sensing, *IMAGING systems, *INTERFEROMETRY, *OPTICAL measurements, *RADIOMETERS, *METEOROLOGICAL instruments, *SYNTHETIC apertures, *SOIL moisture, *SOIL infiltration

Abstract

Interferometric radiometry is a novel concept in remote sensing that is also presenting particular challenges for calibration methods. In this paper, we describe the calibration subsystem (CAS) developed for the Microwave Imaging Radiometer using Aperture Synthesis (MIRAS) interferometer of the Soil Moisture and Ocean Salinity (SMOS) satellite. CAS is important for the overall performance of the payload as it calibrates out the differences between the multiple receivers of MIRAS. SMOS is in the final phase of development and is due to launch in 2008. [ABSTRACT FROM AUTHOR]

Published

2007

18. Sensitivity of Airborne 36.5-GHz Polarimetric Radiometer's Wind-Speed Measurement to Incidence Angle.

Author

Colliander, Andreas, Lahtinen, Janne, Tauriainen, Simo, Pihlflyckt, Jorgen, Lemmetyinen, Juha, and Hallikainen, Martti T.

Subjects

RADIOMETERS, WIND speed, MEASUREMENT, MOTION, FOURIER analysis

Abstract

The Helsinki University of Technology's airborne fully polarimetric profiling radiometer at 36.5 GHz has been used for wind-vector measurements over the Gulf of Finland. The results, collected in a series of measurements over a period of two years, are presented in this paper. The Fourier coefficients of the harmonics of the first three modified Stokes parameters (in brightness temperature) have been solved, and their behavior as a function of the measurement incidence angle and the wind speed has been examined, resulting in a linear model in the measurement range. In this paper, we show a clear relationship between the incidence angle and the third modified Stokes parameter (in brightness temperature), which has been used to compensate for aircraft motion during measurements. Furthermore, the sensitivity of the wind-speed measurement to the incidence angle has been studied, and a model for wind-speed retrieval as a function of the harmonic coefficients and incidence angle was developed. [ABSTRACT FROM AUTHOR]

Published

2007