Remote Sensing of the Terrestrial Water Cycle
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About this ebook
Remote Sensing of the Terrestrial Water Cycle is an outcome of the AGU Chapman Conference held in February 2012. This is a comprehensive volume that examines the use of available remote sensing satellite data as well as data from future missions that can be used to expand our knowledge in quantifying the spatial and temporal variations in the terrestrial water cycle.
Volume highlights include:
- An in-depth discussion of the global water cycle
- Approaches to various problems in climate, weather, hydrology, and agriculture
- Applications of satellite remote sensing in measuring precipitation, surface water, snow, soil moisture, groundwater, modeling, and data assimilation
- A description of the use of satellite data for accurately estimating and monitoring the components of the hydrological cycle
- Discussion of the measurement of multiple geophysical variables and properties over different landscapes on a temporal and a regional scale
Remote Sensing of the Terrestrial Water Cycle is a valuable resource for students and research professionals in the hydrology, ecology, atmospheric sciences, geography, and geological sciences communities.
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Remote Sensing of the Terrestrial Water Cycle - Venkataraman Lakshmi
Preface
The terrestrial hydrologic cycle involves both land surface and atmospheric transport of water in all phases (solid/liquid/water vapor) via liquid and frozen precipitation, infiltration and recharge, surface runoff and snowmelt, stream/river flow, and evapotranspiration. These different transport mechanisms are interconnected and strongly affected by the land-atmosphere dynamics and surface heterogeneity in soil type, topography, and vegetation. Similarly, meteorological forcing of precipitation and radiation are also variable in space and time. In situ systems cannot capture entirely the variability at the surface, as these are often point measurements. In addition, many of these long-term in situ measurements are being discontinued due to budgetary and programmatic constraints. Large-scale field campaigns to measure multiple geophysical variables and properties over different landscapes have been critical to scientific progress, but are limited in space and time. Many of these experiments have provided valuable data sets for the atmospheric, hydrologic, and remote sensing communities. These data sets have been used to construct algorithms that scale between point measurements on the ground and measurements from aircraft and satellites, and providing superior spatial coverage over single-point measurements. Numerous international programs, such as Prediction of Ungauged Basins (PUB) and Hydrology for the Environment, Life and Policy (HELP), which focus on the lack of rain gauge data within single watersheds, have been instrumental in bringing worldwide attention to the lack of ground observations. With the advent of the Earth Observing System (EOS) era in the 1990s, NASA, ESA, and JAXA have launched numerous spaceborne sensors to study the various components of the terrestrial water cycle. These include sensor/missions, to estimate soil moisture—Advanced Microwave Scanning Radiometer (AMSR), Soil Moisture and Ocean Salinity (SMOS); precipitation—Tropical Rainfall Measuring Mission (TRMM); vegetation—Moderate Resolution Imaging Spectroradiometer (MODIS); surface water level—JASON-1 and JASON-2 and TOPEX-POSEIDON; and groundwater—Gravity Recovery and Climate Experiment (GRACE). Currently as a result of the National Research Council Decadal Survey in 2007 a whole new suite of sensors have been recommended to study the water cycle and are scheduled to be launched within the next 10 years.
Therefore, this is a very opportune time for the geosciences community in general and the hydrological community in specific to focus on the use of satellite data for estimating and monitoring the components of the hydrological cycle. This monograph resulting from the AGU Chapman Conference on Remote Sensing of the Terrestrial Water Cycle held in February 2012 examines the use of available satellite data and data from future missions that can be used to expand our knowledge in quantifying the spatial and temporal variations in the terrestrial water cycle.
This monograph has seven distinct sections, viz. remote sensing of precipitation, evapotranspiration, surface water, snow, soil moisture, groundwater, and modeling and data assimilation.
Precipitation
Satellite estimates of precipitation are key to understanding the global water cycle with high temporal resolution. These chapters address particular challenges in analyzing precipitation over land, including understanding rain/no-rain classification, making retrievals over complex terrain, integration of model information (which is important in areas where satellites have trouble making retrievals), and intercalibration of all precipitation-relevant satellites.
Evapotranspiration
Evapotranspiration (ET) is required at many different spatial and temporal scales in climate, weather, [...] hydrology, and agricultural research and applications. Satellite remote sensing is viewed as one of the only technologies that can be used with land surface models to derive ET from field to global scales, particularly in regions with little or no ground resources available. The two chapters in this monograph utilize satellite data to estimate spatially distributed ET without the need for detailed ground data, comparing output to more traditional methods including water balance and micrometeorological methods.
Surface Water
Water flux throughout the world’s rivers, lakes, and wetlands is one of the longest monitored components in terrestrial water balance science and more generally in the global water cycle. Knowing the surface water flux places a constraint on the other components in the water balance. Yet, numerous basins still remain poorly observed with conventional in situ measurements. The vast diversity of satellite sensors now available provide invaluable complementary observations, such as water storage change estimates [...] at the basin [...] scale or spatially distributed geomorphological parameters. Expected future satellite missions will increase our understanding of surface water fluxes.
Snow
Water stored in snow cover is one of the main components of water balance in many parts of the world. The large spatial variability of snow characteristics, particularly in mountains, makes remote sensing a very important alternative to ground snow observations. The snow cover chapters in this book present examples of integrating remote sensing snow observations into hydrologic modeling, improvements in satellite snow cover retrieval and snowmelt and melt-refreeze estimation, advances in snow estimation under vegetation cover, and assessing impacts of climatic factors on snow pack changes in the past.
Soil Moisture
Soil moisture near the surface is a relatively new field of study for remote sensing. This surface state influences both energy and water fluxes at the land surface-atmosphere interface, and is the key state in the partitioning between water infiltration and runoff. Recent advances in satellite remote sensing have pushed the envelope in the science of soil moisture estimation, improving estimates for modeling and applications. Spanning from SMMR, SSM/I, and AMSR-E heritage data to the upcoming SMAP mission, and with the advent of very high resolution products from ESA’s Sentinel-1, the dramatic increase in data availability is allowing new and innovative explorations of soil moisture [...] utilization, as presented in the chapters of this section.
Groundwater
Groundwater comprises more than half of the world’s drinking water and a large portion of the water used to irrigate crops. However, groundwater data are scarce in most of the world, making remotely sensed groundwater information that much more valuable. The chapters on groundwater present examples of remote sensing techniques that have the potential to transform our ability to monitor groundwater variability globally.
Modeling
Global observations and modeling of the terrestrial water cycle have advanced considerably over recent years. Many processes related to changes due to human and natural causes can be better understood and even predicted. Yet, with the uncertainty related to climate change and the highly variable nature of many of the terrestrial processes, there is still much research needed to address the challenges related to freshwater availability. Continuation of existing Earth observational capabilities is as paramount as the development of new capabilities related to monitoring, modeling, and prediction of the terrestrial water cycle.
Venkat Lakshmi
University of South Carolina
Douglas Alsdorf
Ohio State University
Martha Anderson
USDA-Agricultural Research Service
Sylvain Biancamaria
Centre National de la Recherche Scientifique
Laboratoire d’Etudes en Geophysique et Oceanographie spatiales
Michael H. Cosh
USDA-Agricultural Research Service
Jared Entin
NASA Headquarters
George J. Huffman
NASA Goddard Space Flight Center
William Kustas
USDA-Agricultural Research Service
Peter van Oevelen
International GEWEX Project Office
Thomas H. Painter
Jet Propulsion Laboratory
Juraj Parajka
Vienna University of Technology
Matthew Rodell
NASA Goddard Space Flight Center
Christoph Rüdiger
Monash University
Section I: Precipitation
1
Rain/No-Rain Classification Using Passive Microwave Radiometers
J. Indu¹ and D. Nagesh Kumar¹,²
¹ Department of Civil Engineering, Indian Institute of Science, Bangalore, India
² Centre for Earth Sciences, Indian Institute of Science, Bangalore, India
1.1. Introduction
Precipitation is a critical variable driving the atmosphere’s general circulation through latent heat release. As such, accurate quantification of the spatiotemporal variability of precipitation is essential for applications involving environmental, atmospheric, water resource, and related science and engineering disciplines. The increased availability of data products from microwave (passive and active) remote sensing has contributed toward our understanding of the spatiotemporal distribution of precipitation by providing near-real-time spatially continuous precipitation estimates at smaller temporal sampling intervals [Petty, 1994; Ferraro, 1997; Bauer, 2001; Grecu and Anagnostou, 2001; Kummerow et al., 2001; Turk et al., 2002; McCollum and Ferraro, 2003; Wilheit et al., 2003; Ferraro et al., 2005; Levizzani and Gruber, 2007]. These include data products from the Special Sensor Microwave Imager (SSM/I) on Defense Meteorological Satellite Program satellites [Ferraro, 1997], Advanced Microwave Sounding Unit (AMSU) on National Oceanic and Atmospheric Agency (NOAA) Polar Orbiting environmental satellites [Ferraro et al., 2005], Tropical Rainfall Measuring Mission (TRMM) microwave imager (TMI) and precipitation radar (PR) [Kummerow et al., 2001; Wang et al., 2009], Advanced Microwave Scanning Radiometer-Earth Observing System (AMSR-E) [Wilheit et al., 2003] on National Aeronautics and Space Administration (NASA) and Japan Aerospace and Exploration Agency (JAXA) joint satellites, etc. Along with the widespread acceptance of microwave-based precipitation products, it has also been recognized that these products contain large uncertainties [Petty, 1994; Smith et al., 1998; Kummerow et al., 1998, 2005; Coppens et al., 2000]. Studies quantifying global uncertainty offered by microwave rainfall algorithms show climatologically distinct space/time domains that contribute approximately 25% uncertainty to rainfall product that goes undetected by a microwave radiometer [Kummerow et al., 2005]. Of these, nearly 20% is attributed to changes in cloud morphology and microphysics and 5% to changes in the rain/no-rain thresholds. The purpose of this chapter is to describe the foundations of rain/no-rain classification (RNC) based on passive microwave brightness temperatures, outstanding issues, areas of future research, and a comprehensive review of the existing RNC algorithms, based on the works by Grody [1991], Adler et al. [1993], Ferraro et al. [1998], Seto et al. [2005, 2009], Kida et al. [2009], and Kubota et al. [2007].
The physically based overland rainfall retrieval algorithms incorporate rainfall screening as an integral part, without which the succeeding overland rain retrieval technique gets corrupted easily. From the work by Grody [1991], "the physics of rain detection and screening are every bit as important as those of conversion." Studies by rainfall intercomparison projects including algorithm intercomparison projects sponsored by the Global Precipitation Climatology Project and NASA WetNet Precipitation Intercomparison Projects conclude that inadequate screening of nonraining pixels complicates the simplest to the most complex of retrieval algorithms.
To date, various approaches exist to detect raining areas within a radiometer footprint. While some of these techniques are easy to implement, some others involve sophisticated programming logic for correct implementation. Currently, there exist two schools of thoughts for describing rainfall screening methodologies. One approach addresses screening as part of the rainfall retrieval problem. The other approach considers RNC as an essential preprocessing step for proper identification of potential rain measurements before the actual retrieval process. Regardless of which philosophy is followed, typical RNC classification algorithms should accurately identify rainfall signatures over surfaces covered with snow/ice that offer difficulty in uniquely separating rainfall signature from the surface conditions. This implies that an algorithm should either dynamically
determine nonraining pixels or it should depend on suitable surface masks based upon climatology (e.g., for snow and ice) or geography (e.g., for deserts) [Ferraro et al., 1996]. The organization of this chapter is as follows: Section 1.2. presents a discussion on the fundamental principle of passive microwave data and radiative transfer model. Atmospheric attenuation (i.e., reduction of a signal due to atmospheric gases, hydrometeors) is a critical factor affecting radiometer brightness temperature. Hence, Section 1.3. discusses the complex interactions of atmospheric hydrometeors (like water vapor, ice, precipitation) with different microwave frequencies. Section 1.4. describes the fundamentals of the RNC classification technique and highlights prominent RNC algorithms that are embedded in the Goddard profiling (GPROF), the global satellite mapping (GSMaP) of precipitation, and the Goddard scattering (GSCAT) algorithms. Section 1.5. summarizes various indices used for performance evaluation of a typical RNC classification. Compared to RNC classification over oceans, overland classification offers a myriad of complications as land presents itself as a radiometrically warm background with highly varying surface emissivities [Spencer et al., 1989; Grody, 1991; Adler et al., 1994; Ferraro, 1997]. The fairly complex atmospheric attenuation in the scattering regime complicates rainfall delineation even further. For these reasons, overland RNC warrants separate attention. There are several open questions that need to be addressed. These have been discussed in Section 1.6. followed by the conclusions in Section 1.7.
1.2. Principles of Passive Microwave Satellite Measurements
Radiometry is the field of science related to measurement of incoherent electromagnetic radiation. According to thermodynamic principles, all materials (gases, liquids, solids) both emit and absorb incoherent electromagnetic energy. The magnitude of thermal emission I can be expressed as a product of emissivity (ε) and the Planck (blackbody) function B(T) as
(1.1)
where h is Planck’s constant, k is Boltzmann’s constant, c is the speed of light, and T is thermal temperature [Elachi, 1987]. By approximating the thermal emission from the Planck function using Rayleigh-Jeans formula, the microwave brightness temperature can be conveniently expressed as a linear function of physical temperature and emissivity (ε) as
(1.2)
where ε is a complex function of the dielectric constant whose values are quite well known for gases and calm water but not so well understood for the complicated case of rough water and land surfaces [Elachi, 1987].
A downward-viewing spaceborne radiometer is built to sense the upwelling electromagnetic energy emanating from the surface, which reaches the top of the atmosphere after attenuation. The brightness temperatures registered by this radiometer depends on absorption and scattering properties of atmosphere and background emissivity, which vary with frequency and polarization. The intensity of brightness temperature (Tb) incident on a spaceborne microwave radiometer (directed toward Earth), indicates radiation received by the spaceborne antenna from regions of space, which are defined by the antenna pattern. "The antenna pattern is usually strongly peaked along its beam axis. And when pointing towards the ground, its spatial resolution or footprint size is defined by the angular region over which the antenna power pattern is less than 3 dB down from its value at beam center" [Njoku, 1982]. The total noise power resulting from the thermal radiation incident on the antenna, also known as antenna temperature
is expressed as a function of the antenna gain pattern [G(θ, ϕ)] and the brightness temperature distribution incident [TB(θ, ϕ)] as
(1.3)
As shown in Figure 1.1, the distribution of Tb is composed of self-emitted radiation from land/sea, upward emission from the atmosphere, and downward atmospheric emission that is rescattered by the surface toward the antenna coupled with atmospheric attenuation. Therefore, an interpretation of Tb will essentially reveal the physical properties of the media that produce them. Knowing the atmosphere, surface environmental parameters, and radiometer characteristics, radiative transfer models (RTMs) can be used to normalize the measured Tb to a common reference for comparison. This implies that RTMs can interpret Tb from radiometers with different characteristics having different viewing geometries (incidence angles) and operating at different frequencies [Chandrasekhar, 1960; Volchok and Chernyak, 1968; Paris, 1971; Snider and Westwater, 1972; Fraser, 1975; Savage, 1976; Wilheit et al., 1977]. Several factors contribute to the quantitative accuracy of RTMs such as the realism in specifying hydrometeor shape, size, and phases encountered in real rain clouds, knowledge of vertical hydrometeor profiles, and proper generation of local radiative interaction properties (like single scatter albedo, extinction coefficient, etc.).
c1-fig-0001Figure 1.1 Spaceborne radiometer observing the ocean at a nadir angle θ.
The general problem of radiative transfer was solved by Chandrasekhar [1960] and further extended for microwaves in a cloudy atmosphere by Volchok and Chernyak [1968], Paris [1971], Snider and Westwater [1972], Fraser [1975], Savage [1976], and Wilheit et al. [1977]. For a medium in thermodynamic equilibrium, the change in microwave intensity Iλ over a distance ds in the direction (θ, ϕ) is given by the expression:
(1.4)
where, is an inverse scattering phase function that describes the relative contribution of each polar angle θs and each azimuthal angle ϕs to the energy scattered in the direction (θ, ϕ); and kab, ksc denote the absorption and scattering coefficients, respectively. In other words, the gradient of Iλ along s is determined by the balance of energy lost by absorption and by scattering out of the direction of I and energy gained by thermal emission and by scattering into the direction of I. The literature presents several solutions for RTM based on the assumptions of Marshall Palmer drop size distribution, horizontally homogeneous atmosphere in thermal equilibrium [Savage et al., 1995; Lovejoy and Austin, 1980]. Generally, forward radiative transfer equations found in the literature are either scalar or vector models. While the scalar model solves radiative transfer equations with a single Stokes’ parameter and considers only the polarization effects caused by the surface, vector models consider polarization effects caused by both surface and hydrometeors. Vector models consider four Stokes’ parameters, which make the calculations complex and difficult to implement. Hence, vector models require comparatively larger amount of computational time when compared with scalar models. These will not be discussed in this chapter. Comprehensive details regarding microwave radiative transfer are given in Liou [1980] and Janssen [1993].
Uncertainty in effectively interpreting microwave Tb stems from several factors, like antenna pattern, deviation of spacecraft attitude parameters (roll, pitch, yaw), alteration of land surface emissivity during rainfall, nonhomogeneity of land surfaces that results in high and variable surface emissivity, atmospheric attenuation, etc. Attenuation results from the complex interaction of electromagnetic waves with ice, water vapor, oxygen, and other precipitation sized hydrometeors aloft, which can be liquid and/or solid and which may precipitate to surface as rainfall or snowfall depending on the temperature in the subcloud layer. As atmospheric attenuation complicates detection of rainfall signature within Tb, knowledge regarding the sources and sinks of microwave radiation within the atmosphere is crucial to fully understand these uncertainties.
1.3. Atmospheric Attenuation of Microwaves
With the advent of microwave radiometers on board satellites like Defence Meteorological Satellite Program (DMSP), TRMM, Global Precipitation Mission (GPM), Megha Tropiques (MT), etc., microwave rainfall products have become an indispensable source for precipitation information and for real-time applications in flood forecasting. A choice of frequency channels on board these satellites are made based on the geophysical parameter to be studied and its sensitivity to major atmospheric constituents. Several studies have examined the response of microwave frequency channels due to precipitation-sized particles in the atmosphere [Weinman and Guetter, 1977; Spencer, 1986; Wu and Weinman, 1984]. Works have also been conducted to estimate sensitivity of Tb to variations in atmospheric and precipitation parameters using cloud radiative models such as those by Weinman and Guetter [1977], Wilheit et al. [1982], Wu and Weinman [1984], Szejwach et al. [1986], Olson [1987], and Kummerow and Weinman [1988]. This section describes the field of spectroscopy, an age-old science explained by quantum mechanics during the first half of the twentieth century involving the study of absorption and emission by gases. The five possible ways in which radiation interacts with atmospheric gases are ionization-dissociation interaction, electronic transition, vibrational transition, rotational transition, and forbidden transition [Kidder and Vonder Haar, 1995]. Among these, vibrational and rotational transitions are important for satellite meteorology as they occur mostly in the infrared and microwave portion of the electromagnetic spectrum. Some of the prominent sources causing atmospheric attenuation of microwaves are discussed below.
1.3.1. Absorption by Gaseous Atmosphere
An extensive study of microwave absorption of atmospheric gases (both theoretically and experimentally) shows that, emission/absorption in gaseous atmosphere is dominated by the presence of water vapor and oxygen [Waters, 1976; Ulaby and Stiles, 1981]. Absorption characteristics of these gases are summarized by Staelin [1969], Paris [1971], Derr [1972], Waters [1976], and Fraser [1975]. Microwaves undergo resonant absorption and emission at certain frequencies due to the quantum energy states of the water vapor/oxygen molecules. Within microwave spectrum, these molecules are subjected to rotational transition wherein a molecule changes rotational energy states. This causes a peak in Tb measured by a radiometer. The magnitude of increase in Tb depends on the total number of water vapor/oxygen molecules along the propagation path through the atmosphere. At higher altitudes there is a decrease in the number of water vapor/oxygen molecules per unit volume. This in turn reduces the bandwidth of water vapor/oxygen emission (absorption) leading to an increase in absorption at the peak of resonance. The rotational lines of water and oxygen are pressure broadened
in the atmosphere owing to the presence of other gases; there is also a slight dependence on temperature [Kidder and Vonder Haar, 1995]. Water vapor has a weak absorption line at 22.235 GHz and a strong line at 183 GHz. All sensors currently used for precipitation make a measurement near 22.235 GHz like TMI at 21.3 GHz and AMSR at 23.8 GHz. Oxygen has two major peaks, one near 60 GHz and another at 118.75 GHz. More details regarding the absorption characteristics of atmospheric water vapor and oxygen can be obtained from Paris [1971] and Fraser [1975].
1.3.2. Cloud Liquid Water
In an atmosphere with cloud particles, the prominent sources and sinks of microwave energy are local emission and absorption. In the scattering regime, cloud droplets interact weakly with microwave radiation. As the cloud liquid water particles are usually less than 100 µm in diameter, much smaller than the wavelength of radiation, for this Rayleigh region, the scattering effect is negligible. Generally, for the Rayleigh regime, the effect of cloud particles on microwave radiation depends on liquid water content, cloud temperature, and wavelength of radiation. When microwave radiation interacts with rain clouds, the phenomenon is similar to an ensemble of drops with no coherence from drop to drop in the phase of scattered light. Within a rain volume, the usual practice is to assume the raindrops to be randomly distributed. Once we calculate the scattering and absorption for a single drop of spherical dielectric, it is possible by integration to determine corresponding coefficients for a rain cloud that is an ensemble of drops. The particle sizes of raindrops within a rain-bearing cloud are usually described by a continuous function known as drop size distribution (DSD). This function is responsible for defining the concentration of rain particles per unit volume per unit increment of the drop radius.
Studies by Fraser [1975] estimated the single-scatter albedo as a function of wavelength for DSD representing very thin fair weather cumulus and very dense cumulonimbus clouds. Generally, for cumulus clouds, scattering remains negligible at all wavelengths. For cumulonimbus clouds raining at 150 mm/h, scattering will be small only for all values of wavelength >~3 cm. Studies by Lovejoy and Austin [1980] concluded that scattering can be neglected for all clouds if wavelength is >0.5 cm, and for rain rate <10 mm/h if wavelength is >1 cm [Stepanenko, 1968; Wilheit et al., 1977]. A complete and published summary of extinction, scattering, and absorption coefficients and scattering phase functions is available in Savage [1978]. Savage approximated the scattering phase functions by Legendre polynomials, and expressed the Legendre coefficients (for the phase function) and extinction, scattering, and absorption coefficients as power law relations in liquid water content [Barrett and Martin, 1981]. Lovejoy and Austin [1980] assessed the relative contribution of cloud droplets and raindrops to total cloud layer absorption and came out with the conclusions that at rain rates = 10 mm/h, cloud absorption was 30–40% as large as rain absorption. This conclusion was consistent with the observations by Gorelik et al. [1971]. In 1976, Savage stated that addition of a nonscattering cloud layer above the rain layer counteracted scattering and resulted in Tb increase by an amount proportional to the cloud layer thickness. It must be noted that as cloud droplets, water vapor, and oxygen all absorb (but do not scatter) microwave radiation, they have the potential to confuse precipitation estimates based on absorption [Barrett and Martin, 1981]. Authoritative treatment of this subject may be found in Gunn and East [1954], Shifrin and Chernyak [1968], Paris [1971], Schwiesow [1972], Hansen and Travis [1974], Savage [1976], and Fraser [1975].
1.3.3. Surface Emission
In the microwave spectrum, an emitting surface must be considered as a gray body so that its emissivity value stays lower than unity. For homogeneous land surfaces, the variability in microwave radiances depends on surface skin temperature and surface emissivity, while the variability for open water bodies is attributed to the atmospheric constituents such as columnar water vapor, temperature profiles, and presence of cloud liquid water. Unlike the oceans, it is very difficult to model land surface properties in the microwave spectrum due to the spatiotemporal variations of soil features like roughness, vegetation cover, and moisture content. The response of different surface types on the temperature and humidity retrievals has been quantified by English [1999]; in these studies microwave emission errors for different continental surfaces were evaluated by using a mathematical technique to potentially extend the low-altitude sounding information over solid surfaces. Microwave land surface emissivity for various surface conditions on a global scale was attempted by Prigent et al. [1998], Weng et al. [2001], and Pellerin et al. [2003].
Different surfaces contribute varying amounts of emission to a microwave radiometer footprint. Figure 1.2 shows the Tb variations for different microwave frequency channels over land and ocean surfaces [Ferraro et al. 1998]. Oceans provide a stable and uniformly cold
background for a radiometer, emphasizing more the extinction of upwelling radiation by atmospheric constituents. Emissivity of sea surface is dependent on the dielectric properties of seawater through the Fresnel equation. Studies were conducted to predict the dielectric constant of seawater with an aim to improve the retrieval of atmospheric parameters [Klein and Swift, 1977]. Over snow-covered soil, the emissivity values depend on the dielectric constant of frozen soil (~3), thickness, water equivalent, and liquid water distribution. If snow is dry, Tb decreases with an increase in snow water equivalent. In the case of wet snow, even a small increase in the amount of liquid water causes Tb to rise due to volume scattering. The dependence of snow on Tb is more prominent at microwave frequencies >8–12 GHz. In the presence of vegetation, microwave radiation gets emitted, absorbed, and scattered with the radiative properties mostly controlled by the vegetation density, dielectric properties, and relative size of vegetation components with respect to wavelength. Increasing vegetation density increases the emissivity in horizontal polarization and reduces the emissivity polarization difference [Prigent et al., 1997]. In effect, the presence of vegetation reduces the radiometric sensitivity to soil moisture. Studies have developed computational schemes to improve the mathematical description of surface emissivity for several land types: bare soil, vegetation canopy, and snow-covered terrain [Shi et al., 2002; Ferrazoli et al., 2000; Fung, 1994].
Figure 1.2 Emissivity characteristics of various surface types represented by Tb as a function of frequency (a) over land and (b) over ocean.
[Ferraro et al., 1998]
Theoretical models for microwave emission from soils have been presented by many studies [Njoku and Kong, 1977; Wilheit, 1978; Burke et al., 1979; England, 1976] by considering emission from soil for a range of moisture and temperature profiles. At low microwave frequencies, Tb is strongly affected by soil moisture content. This strong dependence is owing to the comparatively high dielectric constant of water (~80) compared to that of dry soil. The dielectric constant of wet soil can reach 20 or more, resulting in an emissivity change at 1.4 GHz from about 0.95 for dry soil to 0.6 for wet soils. Despite a strong sensitivity of the emissivity on soil moisture, microwave remote sensing of soil moisture from space is complicated due to highly varying surface roughness and vegetation cover, which is aggravated by the presence of mixed surfaces within satellite field of view (FOV). To summarize, varying emissivity values from spatiotemporal variations of land surface types can deeply affect radiometer observations, often leading to rainfall retrieval errors.
1.3.4. Ice
Ice particle shapes are crucial in scattering regimes, as they significantly affect the emerging radiance field [Mugnai and Wiscombe, 1986; Bohren, 1986]. Crystals of ice exhibit a large variety of shapes and modes depending on atmospheric temperature and humidity conditions. If we simplify the domain of shapes that the ice nucleation process can create, they can be considered as columns and plates. The usual practice is to adopt a Marshall-Palmer size distribution for ice particle sizes in all theoretical treatments.
Sensitivity of Tb values to the integrated mass of ice/rain depends on frequency, until the optical depth reaches the saturation level [Evans et al., 1995]. Fulton and Heymsfield [1991] studied the response of Tb (18, 37, 92, 183 GHz) to hydrometeors due to intense convection and suggested that even the lowest microwave frequency channel (18 GHz) is significantly obscured by deep convective ice mass. Generally, with an increase in microwave frequency (>60 GHz), scattering signatures become more pronounced and a dramatic increase is observed in volume scattering (ks), absorption coefficients (ka), and single-scatter albedo. This is because the aging of ice results in internal voids that tend to scatter microwave radiation. And, an increase in microwave frequencies is accompanied by an increase in the scattering cross section of inhomogeneities, thereby causing a decrease in radiation emanating from them. Thus, at higher frequencies, scattering dominates with microwave radiation acting relatively transparently to the rain below freezing level. In satellite meteorology, the high single-scatter albedo produced by ice is crucial, as it heavily depresses high-frequency microwave channels. Ice has much smaller absorption coefficients than water that result in high albedos at all SSM/I frequencies. A single scatter albedo approaching unity indicates that any thermal radiation upwelling from below an ice layer that is attenuated by the ice will be scattered out of the radiometer’s field of view, with very little ice-emitted radiation to replace it [Spencer et al., 1989]. When the scattering coefficient is large, and since there is very little (2.7 K) downwelling radiation from cosmic background, very low values of Tb will be recorded at 85.5 GHz frequency. This extremely low Tb observed is usually attributed to convective rainfall. Due to the high sensitivity of 85.5 GHz frequency to frozen ice, RNC algorithms for land regions are essentially based on ice scattering at this frequency. Studies have also been conducted by Anagnostou and Kummerow [1997] that suggest that as Tb at 85.5 GHz (V) frequency is more variable in raining than in nonraining area, studies of rainfall screening can utilize even the standard deviation of Tb at 85.5 GHz (V) frequency in a 5 × 5 pixel window [Biscaro and Morales, 2007].
1.3.5. Precipitation
At microwave wavelengths, precipitation-sized drops interact strongly with microwave radiation [Kidder and Vonder Haar, 1995]. Interaction of electromagnetic (EM) waves with a spherical dielectric causes scattering (redirecting) or absorption (conversion to mechanical energy) of radiation depending on the size of precipitation particles [Barrett and Martin, 1981]. One of the earlier studies by Mie [1908] introduced the general mathematical solution for scattering and absorption of EM waves by a dielectric sphere of arbitrary radius. Later on, this was applied to the context of rain by Gunn and East [1954]. The expressions for Mie efficiency factors are given by
(1.5)
(1.6)
In equations (1.5) and (1.6), r denotes the radius of the rain drop, λ stands for the wavelength, and nc represents the complex index of refraction; Qex and Qsc refer to the Mie efficiency factors of extinction coefficient and scattering coefficient for a single drop. The symbols σex and σsc represent the effective cross sections for extinction and scattering.
Fraser [1975] has calculated the Mie efficiency factors for extinction and scattering and the Rayleigh extinction coefficient for a range of drop sizes [Barrett and Martin, 1981]. If we consider a single raindrop particle whose size is much smaller than the wavelength of EM waves, Rayleigh approximation to the exact Mie expression applies. The absorption cross section will then be proportional to the cube of particle diameter and hence proportional to the volume and mass of the raindrop while scattering cross section will be negligible. When cloud drops coalesce into raindrops with dimensions comparable to microwave wavelengths, absorption per unit mass increases and scattering can no longer be ignored. Based on the theoretical calculations by Savage [1976], rain rates of even a few millimeters per hour cause depression (below 260 K) in Tb for microwave frequencies close to 100 GHz. Studies by Kidder and Vonder Haar [1977] used Tb threshold values to discriminate raining from nonraining pixels. Although attempts to use measurements at 37 GHz for land regions [Weinman and Guetter, 1977; Spencer et al., 1983; Spencer, 1986] met with partial success, mainly in cases of heavier convective rainfall, more reliable microwave rainfall monitoring was made possible only after the launch of SSM/I (1987) [Barrett et al.,1988; Spencer et al., 1989]. Spencer et al. [1989] calculated the scattering and absorption properties of rain for the three main wavelengths (19.35, 37, 85.5 GHz) that have been used to measure precipitation (Figure 1.3). Their study came out with the conclusions that liquid drops both absorb and scatter microwaves of which absorption dominates [Kidder and Vonder Haar, 1995], especially in the frequency range below 22 GHz. This implies that, in this frequency range, scattering does not occur and ice particles above rain are nearly transparent. Another prominent result of their study is that with an increasing rain rate, scattering and absorption both increase with microwave frequencies.
c1-fig-0003Figure 1.3 Relationship of Tb rain rate at 18, 37, and 85.6 GHz.
[Reprinted from radiative transfer modeling of Wu and Weinman, 1984.]
1.4. Rain/No-Rain Classification Methods
An ideal approach toward understanding the fundamentals of RNC classification is based on the emissivity characteristics of background surface. RNC algorithms follow different principles when the underlying surface is land or ocean. Ocean surfaces, which appear cold
to a radiometer operating in the microwave region, offer good contrast for the detection of rain drops, which appear radiometrically warm. As this phenomenon utilizes the strong physical relationship between low-frequency (6–37 GHz) Tb and liquid rainfall, overocean techniques are essentially emission based. Land, however, offers a radiometrically warm background, which tends to hide emission from raindrops. Overland RNC techniques solely rely on ice scattering at a high-frequency (85 GHz) microwave channel and are ambiguous in nature [Wilheit, 1986; Spencer et al., 1989; Grody, 1991; Adler et al., 1993; Ferraro and Marks, 1995; Lin and Hou, 2008; Wang et al., 2009; Gopalan et al., 2010]. This is mainly due to the highly varying emissivity from the land surface background that clutters rainfall signature. The complicated nature of high-frequency microwave scattering with ice crystals adds to the uncertainty, thereby rendering the use of radiative transfer models extremely difficult. It should be noted that the microwave frequencies are utilized to retrieve several geophysical parameters over ocean; for example, 6.8 and 37 GHz are used for wind speed retrieval [Wentz, 1983], 7 GHz is used for retrieving sea surface temperature [Chelton and Freilich, 2005], and so forth.
Some of the first rainfall screening studies were by Ferraro et al. [1986] and Wentz and Cavalieri [1995]. They proposed using multiple channels to identify a rainfall signature from radiometer-received Tb. Their study, involved an intensive analysis of Scanning Multichannel Microwave Radiometer (SMMR) passes over central North America on 20 January, 1979. The study region was chosen to represent a wide variety of surface and atmospheric features ranging from harsh winter conditions and deep snow cover in the northern latitudes to heavy convective rains.
Based on the criteria of spatial resolution and sensitivity to surface parameters, differences between 18 and 37 GHz channels were selected as the optimum channel combination for rain/no-rain discrimination. Their study observed that the presence of clouds and precipitation led to an increase in Tb. Ferraro et al. [1994] expanded on these ideas and developed a set of geographical screens for land, ocean, semiarid land, coastlines, and sea ice. Using SSM/I data over ocean surfaces, Wentz and Cavalieri [1995] proposed the no-rain algorithm based on the fundamental principles of radiative transfer and explicitly showed the physical relationships between the input (Tb) and the output (wind speed, columnar water vapor, columnar cloud liquid water, rain rate, and effective radiating temperature for upwelling radiation). Later on, this algorithm was extended to include the effects of rainfall. Comprehensive details can be found in Wentz [1997]. The screening methodology that has evolved continuously throughout the years is the Grody-Ferraro screening methodology (discussed in Section 1.4.1). This is currently built in to the GPROF algorithm [Kummerow et al., 2001]. Various versions of GPROF have been applied in SSM/I, TMI, and AMSR-E missions [McCollum and Ferraro, 2003; Wang and Wolff, 2010]. The purpose of this section is to describe the major indices used for demarcating the rainfall signature within a microwave FOV, through which we discuss some of the prominent RNC algorithms adopted for land, ocean, and coastlines, using data from satellites like SSM/I, TRMM, etc.
1.4.1. Scattering Index
The technique of using a scattering index (SI) to delineate raining pixels originated from the studies by Grody [1991]. Initially, the idea was proposed to create geographical masks for eliminating Tb cluttering due to desert sand and ice-capped land surfaces. This was essential, as uncertainty in detecting scattering caused by desert/ice-capped surfaces led to false estimates of rainfall over these regions. RNC algorithms based on SI by Grody [1991] largely relied on regression relationships of microwave low-frequency channels, especially the 19 and 22 GHz. Vertical polarization measurements were preferred, as they resulted in smaller aliasing effects in the presence of mixed boundaries (e.g., coastlines). Adler et al. [1993] devised a global empirical relation for SSM/I to calculate the estimated value of Tb at 85 GHz (V) under nonrainy conditions ( ), using a fixed quantity of 243 K. Later on Ferraro et al. [1994] and Ferraro and Marks [1995] introduced the concept of using low-frequency channel combinations (10–37 GHz) to represent . Since the introduction of Grody-Ferraro screening methodology [Ferraro et al., 1986, 1998; Grody, 1991], it has been the most applied technique for use in microwave land precipitation algorithms. The key idea in this technique is that radiation emitted from land surfaces is affected by ice particles and raindrops at high frequency 85 GHz Tb. Calculation of involves simulation of 85 GHz Tb values for clear sky conditions (i.e., nonscattering condition). The difference between and the observed 85 GHz Tb ( ) gave a measure quantifying the degree of scattering by ice particles and raindrops, wherein the rain rate is proportional to the amount of scattering. As rainfall SI models offered an indirect and nonunique relation that varied from region to region, empirical relationships were largely employed between precipitation and SI to map rainfall over land surfaces [Spencer et al., 1989; Kidd and Barrett, 1990; Conner and Petty, 1998; Adler et al., 1994; Dinku and Anagnostou 2005].
As experience with SI-based studies grew, it became increasingly clear that a new suite of algorithms was necessary that efficiently modeled the value of to suit the highly varying emissivity from the background land surface. Results of the ensuing development for overland regions are summarized in Table 1.1. Approaches involved using 85 GHz (H) channel instead of 85 GHz (V) channel to depict [owing to the failure of the first of SSM/I’s 85.5 GHz (V) channel Tb] [Adler et al., 1994; Kummerow and Giglio 1994], using channels of 19 GHz (V) and 22 GHz (V) to represent owing to their increased sensitivity to land surface emissivity. SI-based RNC classification techniques are currently being used for overland RNC classification embedded in prominent algorithms such as GSCAT and GPROF algorithms, which are discussed in Sections 1.4.3 and 1.4.4.
Table 1.1 Prominent scattering index based RNC methods
Source: Modified and adapted from Seto et al. [2005].
1.4.2. Polarization-Corrected Temperature
Atmospheric hydrometeors have a depolarizing effect on microwave radiation that is emitted and reflected from a highly polarized surface [Wu and Weinman, 1984; Huang and Liou, 1983]. Therefore, polarization offers a great deal of information for separating the highly polarized radiances of the ocean from the essentially unpolarized radiances due to precipitation volume scattering [Weinman and Guetter, 1977]. Spencer et al. [1989] proposed an index comprised of linear combinations of vertical and horizontal polarizations to eliminate contrast between land and water/wet surfaces to yield a precipitation signal whose interpretation does not vary much depending on the background surface. The conceptual diagram of this index, known as polarization-corrected temperature (PCT) is shown in Figure 1.4.
c1-fig-0004Figure 1.4 Schematic diagram of vertically and horizontally polarized Tb of ocean with and without an overlying atmosphere.
[Spencer et al., 1989]
The PCT relates the vertically and horizontally polarized Tb, and Spencer et al. [1989] described it as a measure of the distance from the no-scattering line. Earlier studies by Spencer [1986] noted that upon addition of nonscattering materials to the atmosphere above a nonraining, oceanic scan spot, the observed Tb will tend to move along the no-scattering line. When scattering materials (e.g., precipitation) gets introduced into the atmosphere, the point moves off the no-scattering line. As scattering lowers the Tb values, observations in which precipitation occurs will essentially fall between the no-scattering line and the no-polarization line. If and refer to the horizontally and vertically polarized cloud free ocean Tb respectively, and are the horizontally and vertically polarized Tb that are at least partially affected by any combination of clouds and precipitation, and are the vertically and horizontally polarized Tb of the ocean with no overlying atmosphere, then the expression for PCT is given by
(1.7)
where
(1.8)
Calculation of PCT at any frequency requires a nearly constant value of β. Experiments using SSM/I observations of global cloud-free oceanic areas show that to obtain a physically meaningful value of PCT (between 275 and 290 K) the value of β should be 0.45. Absolute accuracy for β is not as important as keeping it constant in all subsequent calculations. Equation 1.7 for PCT can be rewritten as
(1.9)
PCT values using 85.5 GHz frequency channels will generally be lower than the background PCT, although its Tb depression will be much less than that due to the strong volume scattering effects of precipitation. Hence, this property of 85.5 GHz PCT is employed to detect cloud liquid water. Studies by Mugnai et al. [1993] using numerical model simulations demonstrated that 85 GHz signals represent emissions from upper-level liquid and ice scattering in the upper reaches of tall precipitation clouds. Therefore, PCT using 85.5 GHz channel is sensitive to precipitation top height for tall convection and surface rainfall for moderate convection. A modified relation for PCT was proposed by Kidd and Barret [1990] using SSM/I’s 85.5 GHz channels as the basis for estimation of precipitation over both land and water. PCT is currently being used for RNC classification and the succeeding rainfall retrieval oceans and coastlines in the algorithm of the GSMaP, which is discussed in Section 1.4.4
1.4.3. Goddard Scattering Algorithm
The Goddard scattering algorithm (GSCAT) was first proposed by Adler et al. [1993]. Their study detected the existence of rainfall signature using an empirical logic tree applied to multiple channels. The algorithm relied on frequencies of 86 and 37 GHz (both in the horizontal polarization) to eliminate nonraining areas. This technique worked well over ocean and land areas but suffered from the inability to detect rain from clouds below the freezing level. Efforts were undertaken to modify the GSCAT RNC algorithm by including geographical screens (for deserts and snow-covered surfaces) similar to the work by Grody [1991]. Adler et al. [1994] modified this algorithm and included better quality control and use of lower frequency channels to differentiate cold surface and desert from precipitation. This differentiation was essential when rainfall retrieval is to be made globally. Adler et al. [1994] and Kummerow and Giglio [1994] created GSCAT2, which used 85 GHz (H) instead of 85 GHz (V), to represent the value of and a constant value (251 K) for Tb, Estimated without using any regression equations such as Grody [1991]. It was developed using channel information from SSM/I sensors. The methodology employed several checks, including the existence of cold ocean, coastline, desert, ice-covered regions, and ambiguous cold surface possible precipitation checks. These checks prevented surface effects that might lead to false identification of rain regions. GSCAT-2 proved to perform successfully in the SSM/I era to demarcate rain/no-rain regions, but not without some false rain identifications. The overall procedure for identifying raining pixels was not all that dissimilar from the scattering index by Grody [1991]. In an intercomparison study involving seven microwave techniques over Japan, Lee et al. [1991] showed that the GSCAT had the highest correlation with the Grody scheme during the convective regime in July–August 1989. The scattering signatures in GSCAT were used to retrieve rain intensity in proportion to the amount of scattering by ice and graupel aloft based on radiative transfer calculations applied to numerical cloud model results.
1.4.4. Goddard Profiling Algorithm
The GPROF algorithm is considered the established algorithm framework for microwave rainfall products from TRMM (launched in November 1997), Aqua (satellite of AMSR-E launched in May 2002), and included in the initial plans for the proposed Global Precipitation Measurement (GPM) mission (to be launched in 2014). GPROF follows separate sets of algorithms for RNC classification over land, ocean, and coastlines. Various versions of GPROF screening methodology have been implemented in SSM/I, TMI, and AMSR-E missions with an improved version to be applied in GPM mission [McCollum and Ferraro, 2003; Wang et al., 2009; Gopalan et al., 2010].
1.4.4.1. RNC Over Land
The RNC classification algorithm of GPROF for land regions [Kummerow et al., 2001] assumes that Tb at 21.3 GHz (V) represents the nonscattering portion of Tb from 85 GHz (V). A scattering index threshold of 8 K is fixed to judge rainfall signature from a pixel/footprint. All pixels that exceed this threshold were identified as possible rain
and were then processed using the full Bayesian algorithm to quantify the rain rate, which could be zero or nonzero. GPROF version 4 used the screening methodology of GSCAT 2 [Adler et al., 1994]. Version 5 of GPROF [Petty 1994] employed polarization-based emission and scattering indices that could isolate signal coming from rain clouds with the background variability.
1.4.4.2. RNC Over Oceans
Over oceans, the predictable ocean surface emissivity offers contrast to the signals emanating from liquid hydrometeors over the range of microwave frequencies. Yet, the RNC detection technique of TRMM TMI usually fails over oceans to detect shallow rain observed by PR owing to the small scale of shallow rain when compared with the resolution of channels used in the emission-based algorithm. As clouds are optically thick at 85 GHz, it becomes very difficult to use the emission-based algorithm to detect shallow rains. Owing to the contrast between atmospheric liquid and low emissivity ocean surface, screening rainfall pixels over oceans relies on estimation of the liquid water path (LWP). The screening of GPROF over the ocean consists of two processes: checking the LWP and screening out clear ocean pixels and ice surface pixels. The flowchart for GPROF method over the ocean is shown in Figure 1.5.
c1-fig-0005Figure 1.5 Flowchart for RNC method of GPROF over ocean.
[Kida et al., 2009]
In the first process, based on the study of Karstens et al. [1994], the LWP is checked using TMI low-resolution channels of 22 GHz (V) and 37 GHz (V) using the relation
(1.9)
All the footprints having LWP values less than the maximum LWP was classified under no rain,
where the value of maximum LWP (kg /m²) is based on the following relation:
(1.10)
Here the value of freezing level height (FLH) is derived from the work by Wilheit et al. [1991] and the values of 0.25 and 4000 represent the liquid water content and a typical FLH [Wilheit et al., 1991].
The second process was based on the GSCAT algorithm [Adler et al., 1994], which employed three checks. The first check employed threshold values for Tb from 22 GHz (V) and 85 GHz (H) channels to identify the target pixel as possibly rain.
This check was originally used to screen ice surfaces and possible rain,
but in the GPROF version 6 algorithm, this was utilized to detect rainfall signature. The second check aimed to distinguish ice surfaces from rain
using Tb at 22 GHz (V). The third check was to identify clear ocean using Tb at 37 GHz (H) and 85 GHz (H). If the target pixel was not identified as ice surface/clear ocean by these checks, it was flagged as possible rain.
After the screening process, the footprints identified as possible rain
are processed using the Bayesian algorithm to quantify rain rate.
1.4.4.3. RNC Over Coasts
Rain identification over land or water involves checks for snow/desert surfaces, which tend to depress the high-frequency microwave channels. Coastlines are much more difficult as, for either water or land surfaces, adding the opposite surface into the footprint will have the same effect as rainfall. Over land, adding surface water to the footprint will reduce the Tb’s, as does scattering caused by rain, and adding land to a water footprint will increase Tb’s, similarly to rain over water, resulting in emission [McCollum and Ferraro, 2005]. Over coasts, microwave footprint is a combination of radiometrically warm land surface and cold ocean surface. One of the very first RNC algorithms developed for coasts was using SSM/I channels by Adler et al. [1994]. They proposed a complex decision tree method as shown in Figure 1.6, to isolate rainfall signature without using the SI method by Grody [1991]. More details about this method are available in Huffman and Adler [1993], which will hereinafter be referred to as HA93. The HA93 algorithm was implemented in GPROF and has remained in use in successive GPROF versions [Wilheit et al., 2003].
c1-fig-0006Figure 1.6 Decision tree for demarcating rainfall over coasts (HA93).
[McCollum and Ferraro, 2005]
Bennartz [1999] provided a technique to account for the coastline complexity, which involved use of effective antenna pattern function and scan geometry of the microwave instrument and high-resolution land-water mask to analyze the fraction of land versus water within each radiometer footprint. The study represented the atmospheric contribution from rain assuming a constant land Tb, while the land versus water fraction was used to weight the relative contribution of land-ocean surfaces to background signal. This technique was implemented to retrieve column water vapor for noncloud conditions using SSM/I data for the Baltic Sea region of western Europe. The study concluded that satellite navigation uncertainty created a dominant source of error. The assumption of a constant value to represent Tb from highly varying land surfaces fails in raining situations, for which cases the method of Bennartz [1999] cannot be implemented. The land surface emissivities have not yet been incorporated in the land component of GPROF rainfall algorithms. And, use of a straight cutoff for Tb values also cannot be implemented over coasts as water within the footprint reduces the high-frequency Tb’s. As a result, combination of several criteria were examined to classify a footprint as having no rain,
possibly rain,
or ambiguous.
The criteria were mostly determined from the studies of Grody [1991] and Adler et al. [1993].
The HA93 decision tree method for RNC classification of coastline is summarized in figure 1.6. In this figure, the clear coast check
by Adler et al. [1993] involves the following checks for Tb from 85 GHz (H) and 37 GHz (H):
(1.11)
(1.12)
(1.13)
where
and σ (standard deviation) and ρ (cross correlation) are computed on a 5 × 5 footprint array centered on the footprint of interest. This test identifies cases in which low humidity allows the (similar) surface emission signals from and to dominate the microwave signal [McCollum and Ferraro, 2005].
The HA93 algorithm added ambiguous classes for TB combinations for which rainfall rate was retrieved based on the requirement that another scheme be applied to estimate whether the retrieval was useful or an artifact. In case this could not be done, no estimate was made for such footprints in the ambiguous
class, leaving holes
in the resulting rainfall map. Footprints that were classified under possible rain
were required to satisfy a cutoff threshold using higher frequency channels to be flagged as rain
over land regions. The HA93 algorithm used criterion to assign a positive rain classification. The study conducted by McCollum and Ferraro [2005] using AMSR-E data suggested that a threshold using fails to provide a clear cutoff. The availability of TMI Tb’s collocated with TRMM PR rainfall rates enabled choosing cutoff criteria that could efficiently separate raining from nonraining footprints. To summarize, the study by McCollum and Ferraro [2005] provided two major improvements to the existing RNC classification algorithm for coasts. The first step was to estimate conditions where positive rain rates should be estimated rather than leaving the areas without estimates as in the previous algorithm. Owing to the high correlation among the various TMI microwave channels, principal component analysis often provides a useful technique to separate signals of geophysical variables by the creation of mutually orthogonal statistically uncorrelated eigenvectors [Conner and Petty, 1998]. Therefore, the second step modified the cut-off threshold for rain/no-rain classification by using a PCT criterion instead of a straight Tb cut-off. These modifications were implemented in 2004 for the version 6 TMI product and third release of AMSR-E products with a slight difference for each product. The significant changes implemented for the latest version (version 7) of the GPROF TMI ocean algorithm involves addition of the probability of precipitation parameter, wherein pixels are not screened before Bayesian scheme. The algorithm developers recommend using 50% probability of rainfall threshold within the FOV when comparing with instantaneous PR and TMI rain rates. For the TMI coastal algorithm, a change in the land/ocean classification has been implemented [Zagrodnik and Jiang, 2013].
1.4.5. Global Satellite Mapping of Precipitation (GSMaP) Algorithm
The GSMap algorithm was developed by the Earth Observation Research Center, Japan Aerospace Exploration Agency (JAXA/EORC), and has been further improved with the use of PR measurements. Comparative studies by Kummerow et al. [2001] evaluated the performance of TRMM monthly rainfall estimates from both its sensors TMI and PR, which revealed a bias between both the rainfall products of nearly 30% over ocean and 26% over land (using version 5 of data products). The TRMM version 6 algorithms display improvements within level 2 surface rain retrieval algorithms based on physical principles. Results of intercomparison studies between version 5 and version 6 algorithms are presented in Chiu et al. [2006]. GSMaP is drawn up to the highest levels of precision and resolution with temporal resolution of 1 h and spatial resolution of 0.1°. The RNC algorithms implemented in GSMaP for over land, over ocean, and coastal regions are discussed below.
1.4.5.1. RNC Over Land
Seto et al. [2005] developed the RNC classification algorithm (version 4.5) for GSMaP that was employed in TRMM. Their study involved statistically summarizing all the TMI Tb values under no-rainfall conditions of PR 2A25, for the land regions into a database that represented both the spatial and temporal variations of Tb. This land surface brightness temperature database
contained the spatiotemporal variations of Tb including the effects of sand and fallen snow [Seto et al., 2005]. Due to the varied spatial resolutions of TMI channels among themselves as well as with PR, footprint size was defined by means of effective field of view (EFOV). PR footprints, the center of which lie within a TMI footprint, were chosen as reference. In their study, all the PR observations within a TMI footprint that had a no-rain
or rain-possible
flag were adjudged to be in no-rain conditions. Their study summarized TMI observations under no-rain conditions in a database with resolution of 1 month and 1° latitude × 1° longitude. The distribution of Tb values under no-rain conditions was represented using a Gaussian distribution. The mean (μ) and standard deviation (σ) of 85 GHz (V) Tb were calculated to represent the distribution and stored in the database.
Seto et al. [2005] proposed two RNC methods (named as M1 and M2) for real-time use. The first method (M1) used the parameters estimated from the database of TMI Tb under no-rain conditions. The value for was fixed as equivalent to μ and the threshold of scattering was judged at k0σ where k0 was a constant in space and time. The thresholds for M1 differed with month and grid. This was an improvement over the threshold of Adler et al. [1994], which remained fixed at a constant value of 251 K. M2 considered a linear regression fit using least mean square error, between Tb (21.3 V) and Tb (85.5 V), both under no-rain conditions, using the database.
(1.14)
The subscript denotes observations conducted under no-rain / clear sky conditions. If σe is the standard deviation of residuals of equation and k0 is a constant in both space and time, the pixel fulfilling the criterion of equation (1.11) is adjudged as containing a rainfall signature:
(1.15)
The number of rain pixels increased or decreased depending on the value of k0, which varied with regions and seasons. The usual practice was to affix a constant value for k0 for simplicity reasons. For GSMaP, the value of k0 adopted was 3.5 and no desert/snow masks were employed as in Grody [1991]. The proposed RNC for version 4.7 was the same as that of version 4.5 with the only difference being in the retrieval part. These RNC methods are also known as PR-dependent methods as they cannot be applied to other microwave radiometers not accompanied by spaceborne precipitation radar. The methods (M1 and M2) were modified with an aim to make the RNC methods independent of PR so that these could be applied to data from other microwave radiometers as well. Comprehensive details regarding these can be found in Seto et al. [2009].
1.4.5.2. RNC Over Oceans
Over oceans, GSMaP adopted the method of Kida et al. [2009]. Their study employed two stages for detection of rain and no-rain footprints, as shown in Figure 1.7. In the first stage, deep rain pixels were determined by Tb from 85 GHz (V) scattering signature, and shallow rain pixels were determined with normalized polarization difference at 37 GHz (V). The study considered all the pixels of 85 GHz (V) lying within the EFOV of 10 GHz (V) pixel. The condition for detection of deep rain pixel was then fixed as the existence of one or more pixels of 85 GHz (V) within the EFOV of 10 GHz (V), having a rain rate > 1mm/h (rain 85 pixels). The study classified the target pixel (central pixel) as deep rain pixel upon fulfilling the above condition. If not, the normalized PCT [Petty, 1994] as given by equation 1.12 was used to check the existence of shallow rain:
(1.16)
Based on the results of the first stage, their study checked emission signatures from raindrops in the second stage. The three checks used in the second stage are shown in Figure 1.7 from which it can be seen that Tb values of channels 19 GHz (V), 10 GHz (V), and 37 GHz (V) were used.
c1-fig-0007Figure 1.7 Flowchart for RNC classification used in GSMaP.
[Kida et al., 2009]
Kida et al. [2009] proposed modifications for the RNC method of GSMaP in order to use Tb from 37 GHz (V) more efficiently. Their study was