Linking goniometer measurements to hyperspectral and multisensor imagery for retrieval of beach properties and coastal characterization

Bachmann, Charles M.; Gray, Deric; Abelev, Andrei; Philpot, William; Montes, Marcos J.; Fusina, R.A.; Musser, Joseph A.; Li, Rongrong; Vermillion, Michael; Smith, Geoffrey B.; Korwan, Daniel; Snow, Charlotte M.; Miller, W. David; Gardner, J. M.; Sletten, Mark A.; Georgiev, G.; Truitt, Barry R.; Killmon, Marcus; Sellars, Jon; Woolard, Jason; Parrish, Christopher; Schwarzscild, Art

doi:10.1117/12.918464

Cited by 6 publications

(7 citation statements)

References 6 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Instead, reflectance increases as density decreases, with no inversion at any fill factor. This supports previous observation by Bachmann et al 5,11,12 that as density increases, multiple scattering returns leaving granular substances with optically contrasting mineral content are diminished, leading to an overall reduction in reflectance. Phase Angle Figure 11.…”

Section: Reflectance As a Function Of Phase Angle For Constant Azimuthsupporting

confidence: 91%

“…12 Results for the 65°illumination zenith angle show the expected behavior predicted by the Hapke radiative transfer model where reflectance increases with increase in density until a fill factor of 0.52 is reached and then proceeds to decrease with further increases in fill factor. For the 20° illumination zenith angle, this trend does not hold.…”

Section: Reflectance As a Function Of Phase Angle For Constant Azimuthmentioning

confidence: 60%

“…5,11,12 Traditional radiative transfer theory, such as the model developed by Bruce Hapke 3 , suggests that the direct impact of an increase in granular material constituent density results in an increase in overall reflectance for fill factors up to approximately 0.52. 2,3 However, it has been shown that when a darker mineral fraction is present alongside larger, more translucent grains, reflectance decreases with higher density sands and increases with lower density composites.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Influence of density on hyperspectral BRDF signatures of granular materials

et al. 2015

Self Cite

View full text Add to dashboard Cite

Recent hyperspectral measurements of composite granular sediments of varying densities have revealed phenomena that contradict what radiative transfer theory would suggest. 5 In high-density sands where dominant constituents are translucent and supplementary, darker grains are present, bidirectional reflectance distribution function (BRDF) measurements of high density sediments showed reduced intensity when compared to lower density counterparts. It is conjectured that this is due to diminished multiple scattering from the darker particles which more optimally fill pore space as density increases. The goal of these experiments is to further expand upon these earlier results that were conducted primarily in the principal scattering plane and only at minimum and maximum densities. In the present study, the BRDF of granular composites is compared along a gradient of densities for optically contrasting materials. Systematic analysis of angular and material dependence will be used to develop better models for multiple scattering effects of the granular materials. The measurements in this experiment used the recently constructed, laboratory and field-deployable Goniometer of the Rochester Institute of Technology (GRIT), which measures BRDF for geometries covering 360 degrees in azimuth and 65 degrees in zenith. In contrast to the previous studies limited to the principal scattering plane, GRIT provides a full hemispherical BRDF measurement.

show abstract

Section: Reflectance As a Function Of Phase Angle For Constant Azimuthsupporting

confidence: 91%

Section: Reflectance As a Function Of Phase Angle For Constant Azimuthmentioning

confidence: 60%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Influence of density on hyperspectral BRDF signatures of granular materials

et al. 2015

Self Cite

View full text Add to dashboard Cite

show abstract

“…In these sands, increased density led to a decrease in reflectance. 1,3 An apparent explanation may be a combination of factors 3 : the onset of coherent effects at sufficiently high fill factor and the fact that the dark absorbing mineral fraction should more optimally fill the available pore space as the density increases; this darker absorbing mineral fraction would then tend to dampen the multiple scattering pathways. Figures 2 -4 show examples that illustrate this point using observations in the laboratory, ground observations in the field, and airborne hyperspectral imagery.…”

Section: Brdf Field and Laboratory Data And Density Dependencementioning

confidence: 97%

Retrieval of sand density from hyperspectral BRDF

Bachmann

Abelev

Philpot

et al. 2014

Algorithms and Technologies for Multispectral, Hyperspectral, and Ultraspectral Imagery XX

Self Cite

View full text Add to dashboard Cite

In past work 1 , we have shown that density effects in hyperspectral bi-directional reflectance function (BRDF) data are consistent in laboratory goniometer data, field goniometer measurements with the NRL Goniometer for Portable Hyperspectral Earth Reflectance (GOPHER), and airborne CASI-1500 hyperspectral imagery. Density effects in granular materials have been described in radiative transfer models 2,4,5 , and are known, for example, to influence both the overall level of reflectance as well as the size of specific characteristics such as the width of the opposition effect in the BRDF. However, in mineralogically complex sands, such as coastal sands, the relative change in reflectance with density depends on the composite nature of the sand 3 . This paper examines the use of laboratory and field hyperspectral goniometer data and their utility for retrieving sand density from airborne hyperspectral imagery. We focus on limitations of current models to describe density effects in BRDF data acquired in the field, laboratory setting, and from airborne systems.

show abstract

“…5 Many types of goniometer systems have been created to conduct measurements in both field and laboratory settings. 1,3,4 These devices are purpose-built to measure specific target sets, such as vegetation, man-made surfaces, or sediments, and their overall design can vary widely based on the type of target being measured. In the creation of such devices, the designer must consider the standard operating environment that the devices are expected to perform in, the level of accuracy they are expected to obtain in their measurements, their size, and any other required constraints.…”

Section: Introductionmentioning

confidence: 99%

A next generation field-portable goniometer system

Harms

Bachmann

Faulring³

et al. 2016

SPIE Proceedings

Self Cite

View full text Add to dashboard Cite

Various field portable goniometers have been designed to capture in-situ measurements of a materials bidirectional reflectance distribution function (BRDF), each with a specific scientific purpose in mind. 1-4 The Rochester Institute of Technology's (RIT) Chester F. Carlson Center for Imaging Science recently created a novel instrument incorporating a wide variety of features into one compact apparatus in order to obtain very high accuracy BRDFs of short vegetation and sediments, even in undesirable conditions and austere environments. This next generation system integrates a dual-view design using two VNIR/SWIR spectroradiometers to capture target reflected radiance, as well as incoming radiance, to provide for better optical accuracy when measuring in non-ideal atmospheric conditions or when background illumination effects are non-negligible. The new, fully automated device also features a laser range finder to construct a surface roughness model of the target being measured, which enables the user to include inclination information into BRDF post-processing and further allows for roughness effects to be better studied for radiative transfer modeling. The highly portable design features automatic leveling, a precision engineered frame, and a variable measurement plane that allow for BRDF measurements on rugged, un-even terrain while still maintaining true angular measurements with respect to the target, all without sacrificing measurement speed. Despite the expanded capabilities and dual sensor suite, the system weighs less than 75 kg, which allows for excellent mobility and data collection on soft, silty clay or fine sand.

show abstract

Linking goniometer measurements to hyperspectral and multisensor imagery for retrieval of beach properties and coastal characterization

Cited by 6 publications

References 6 publications

Influence of density on hyperspectral BRDF signatures of granular materials

Influence of density on hyperspectral BRDF signatures of granular materials

Retrieval of sand density from hyperspectral BRDF

A next generation field-portable goniometer system

Contact Info

Product

Resources

About