2018
DOI: 10.3390/rs10020221
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Evaluation of Three Techniques for Correcting the Spatial Scaling Bias of Leaf Area Index

Abstract: Abstract:The correction of spatial scaling bias on the estimate of leaf area index (LAI) retrieved from remotely sensed data is an essential issue in quantitative remote sensing for vegetation monitoring. We analyzed three techniques, including Taylor's theorem (TT), Wavelet-Fractal technique (WF), and Fractal theory (FT), for correcting the scaling bias of LAI with empirical models in different functions (i.e., power, exponential, logarithmic and polynomial) on both simulated data and a real dataset over a cr… Show more

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Cited by 16 publications
(12 citation statements)
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“…Integrating radar data 40,41 and blending lower resolution time series 42,43 are two mitigation options to increase data frequency in areas with persistent cloud cover. Attention should be paid to correct the spatial scaling bias when fusing LAI data 44,45 because it does not correlate linearly with spatial resolution 46,47 . Given the unprecedented revisit cycle of current Earth Observation systems, data fusion capabilities, and the prospects of future missions, our modelling suggests that the time is ripe for a shift towards the use of data-intensive metrics for empirical yield estimation.…”
Section: Discussionmentioning
confidence: 99%
“…Integrating radar data 40,41 and blending lower resolution time series 42,43 are two mitigation options to increase data frequency in areas with persistent cloud cover. Attention should be paid to correct the spatial scaling bias when fusing LAI data 44,45 because it does not correlate linearly with spatial resolution 46,47 . Given the unprecedented revisit cycle of current Earth Observation systems, data fusion capabilities, and the prospects of future missions, our modelling suggests that the time is ripe for a shift towards the use of data-intensive metrics for empirical yield estimation.…”
Section: Discussionmentioning
confidence: 99%
“…Integrating radar data 40,41 and blending lower resolution time series 42,43 are two mitigation options to increase data frequency in areas with persistent cloud cover. Attention should be paid to correct the spatial scaling bias when fusing LAI data 44,45 because it does not correlate linearly with spatial resolution 46,47 . Given the unprecedented revisit cycle of current Earth Observation systems, data fusion capabilities, and the prospects of future missions, our modelling suggests that the time is ripe for a shift towards the use of data-intensive metrics for empirical yield estimation.…”
Section: Discussionmentioning
confidence: 99%
“…Due to the lack of sub-meter imagery, the fine images used in this study are pan-sharpened PMS/GF-1 bands. Although pan-sharpened PMS/GF-1 data has been widely used as a real and reliable product in many applications [53]- [58], it is important to use the original high-resolution data to do the fusion. Our results indicate the great potential of HISTIF in the applications of fusing Landsat-8 or Sentinel-2 and WorldView-2 or other high-resolution imagery.…”
Section: Advantages and Limitations Of Histif And User Guidementioning
confidence: 99%