Modeling land surface fluxes using a sparse canopy model and radiometric surface temperature measurements

@article{Friedl1995ModelingLS,
  title={Modeling land surface fluxes using a sparse canopy model and radiometric surface temperature measurements},
  author={Mark A. Friedl},
  journal={Journal of Geophysical Research},
  year={1995},
  volume={100},
  pages={25435-25446},
  url={https://api.semanticscholar.org/CorpusID:129329254}
}
  • M. Friedl
  • Published 20 December 1995
  • Environmental Science
  • Journal of Geophysical Research
Land surfaces with fractional vegetation cover possess distinctive micrometeorological properties that complicate the use of energy balance models to simulate surface fluxes. The use of thermal infrared (TIR) measurements to drive surface energy balance models over such surfaces is further complicated because TIR sensors view both soil and canopy elements. A land surface energy balance model specifically designed for sparse vegetation canopies is presented that addresses both of these issues… 
View via Publisher
61 Citations
Background Citations
13
Methods Citations
11

61 Citations

Forward and inverse modeling of land surface energy balance using surface temperature measurements

    M. Friedl
    Environmental Science, Engineering
  • 2002

Modeling area-averaged fluxes over partially vegetated land surfaces using aircraft and in-situ thermal data

    M. Friedl
    Environmental Science
    IGARSS '96. 1996 International Geoscience and…
  • 1996
A surface energy balance model is used in association with remotely sensed and in-situ data to examine issues of measurement, scaling, and aggregation of high frequency spatial variation in land

Interpretation of the relationship between skin temperature and vegetation fraction: Effect of subpixel soil temperature variability

Both land surface/skin temperature and vegetation indices data provided routinely and globally by NASA MODIS sensors at 1‐km grid resolution represent an important piece of information assimilated

Mapping of Land-Atmosphere Heat Fluxes and Surface Parameters with Remote Sensing Data

A variational data assimilation scheme is used to infer two key parameters ofthe surface energy balance that control the partitioning of available energy intolatent, sensible, and ground heat fluxes

Variational estimation of soil and vegetation turbulent transfer and heat flux parameters from sequences of multisensor imagery

Turbulent heat fluxes from the surface do not have a unique signature that can be detected by remotely deployed instruments. In order to retrieve the fluxes, the measurements need to be merged into

Decoupling of surface and near‐surface soil water content: A remote sensing perspective

Inconsistencies between remotely sensed (thermal infrared), in situ, and modeled values of soil water content are examined. First, an important hydraulic parameter in a soil water profile model is

On the efficacy of combining thermal and microwave satellite data as observational constraints for root-zone soil moisture estimation.

Abstract Data assimilation applications require the development of appropriate mathematical operators to relate model states to satellite observations. Two such “observation” operators were developed

Numerical solution of a complete surface energy balance model for simulation of heat fluxes and surface temperature under bare soil environment

Measuring and modelling the radiation balance of a heterogeneous shrubland.

The accurate quantification of the energy available for sensible and latent heat transfer from plant canopies is essential for the prediction of impacts of climate on vegetation water use and growth.

On the opposing roles of air temperature and wind speed variability in flux estimation from remotely sensed land surface states

In semi‐arid regions the evapotranspiration rates depend on both the spatial distribution of the vegetation and the soil moisture, for a given radiation regime. Remote sensing can provide high
...

40 References

Water and surface energy balance model with a multilayer canopy representation for remote sensing purposes

A surface energy balance model with a multilayer canopy representation has been developed to simulate the vertical temperature distribution of the foliage elements and the soil underneath. This model

Evapotranspiration over an agricultural region using a surface flux/temperature model based on NOAA-AVHRR data

Abstract The possibility of using infrared surface temperatures from satellites (NOAA, GOES) for inferring daily evaporation and soil moisture distribution over large areas (102 to 105 km2) has been

Land-surface temperature measurement from space: physical principles and inverse modeling

To apply the multiple-wavelength (split-window) method used for satellite measurement of sea-surface temperature from thermal-infrared data to land-surface temperatures, the authors statistically

Modeling canopy stomatal conductance in a temperate grassland ecosystem

Influence of Subgrid-Scale Heterogeneity in Leaf Area Index, Stomatal Resistance, and Soil Moisture on Grid-Scale Land–Atmosphere Interactions

Abstract The statistical representation of multiple land surfaces within a grid cell has received attention as a means to parameterize the nonlinear effects of subgrid-scale heterogeneity on

The theoretical relationship between foliage temperature and canopy resistance in sparse crops

One-dimensional, sparse-crop interaction theory is reformulated to allow calculation of the canopy resistance from measurements of foliage temperature. A submodel is introduced to describe eddy

Transient water stress in a vegetation canopy: Simulations and measurements

A RESISTANCE PARAMETER FOR BARE‐SOIL EVAPORATION MODELS

A bare-soil surface resistance parameter significantly improved the fit of a numerical model of heat and moisture flow in soils to 3 days of field measurements. The resistance removed a positive bias

Sources of variation in radiometric surface temperature over a tallgrass prairie

Estimation of regional evapotranspiration and soil moisture conditions using remotely sensed crop surface temperatures

    G.J.R. Soer
    Environmental Science, Agricultural and Food Sciences
  • 1980