&lt;title&gt;Spectral BRDF modeling using wavelets&lt;/title&gt;

Claustres, Luc; Boucher, Yann; Paulin, Mathias

doi:10.1117/12.458726

Cited by 7 publications

(5 citation statements)

References 20 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Claustres et al . [39, 40] represented spectral BRDFs in both geometrical (incident and outgoing directions) and spectral (wavelength) components using wavelets.…”

Section: Related Workmentioning

confidence: 99%

“…Multidimensional wavelets are constructed from one-dimensional wavelet bases using the products of basis functions. Claustres et al [39,40] represented spectral BRDFs in both geometrical (incident and outgoing directions) and spectral (wavelength) components using wavelets.…”

Section: Brdf Representationmentioning

confidence: 99%

“…In spectral rendering, the wavelength information should be preserved, and finally be transferred into color components for display in a device. Although the Claustres' method [39, 40] can represent the spectral BRDFs, to enhance representation compactness, the method removes the wavelet coefficients lower than a given threshold and introduces a sparse array to save the remained coefficients; this reduces the representation accuracy and increases the complexity of implementation.…”

Section: Related Workmentioning

confidence: 99%

See 2 more Smart Citations

Compact Representation of Spectral BRDFs Using Fourier Transform and Spherical Harmonic Expansion

Sun

2006

Computer Graphics Forum

View full text Add to dashboard Cite

This paper proposes a compact method to represent isotropic spectral BRDFs. In the first step, we perform a Fourier transform in the wavelength dimension. The resulting Fourier coefficients of the same order depend on three angles: the polar angle of the incident light, and the polar and azimuth angles of the outgoing light. In the second step, given an incident light angle, when the Fourier coefficients of the same order have an insensitive dependency on the outgoing direction, we represent these Fourier coefficients using a linear combination of spherical harmonics. Otherwise, we first decompose these Fourier coefficients into a smooth background that corresponds to diffuse component and a sharp lobe that corresponds to specular component. The smooth background is represented using a linear combination of spherical harmonics, and the sharp lobe using a Gaussian function. The representation errors are evaluated using spectral BRDFs obtained from measurement or generated from the Phong model. While maintaining sufficient accuracy, the proposed representation method has achieved data compression over a hundred of times. Examples of spectral rendering using the proposed method are also shown.

show abstract

“…Claustres et al . [39, 40] represented spectral BRDFs in both geometrical (incident and outgoing directions) and spectral (wavelength) components using wavelets.…”

Section: Related Workmentioning

confidence: 99%

Section: Brdf Representationmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

See 1 more Smart Citation

Compact Representation of Spectral BRDFs Using Fourier Transform and Spherical Harmonic Expansion

Sun

2006

Computer Graphics Forum

View full text Add to dashboard Cite

show abstract

“…However, the specular peak is wellpreserved with a medium compression rate. Moreover, we have shown in [41] that wavelet modelling has similar performances than the analytical modelling at fixed wavelength for diffuse surfaces, and better ones for specular surfaces. Figure 7 shows the plots of the BRDF of three different samples (cloth, sand, and dry grass) for a fixed incoming direction and azimuth angle.…”

Section: Isotropic Brdfmentioning

confidence: 76%

Wavelet-based modeling of spectral bidirectional reflectance distribution function data

Boucher

2004

Opt. Eng

Self Cite

View full text Add to dashboard Cite

The Bidirectional Reflectance Distribution Function (BRDF) is an important surface property, and is commonly used to describe reflected light patterns. However, the BRDF is a complex function since it has four angular degrees of freedom and also depends on the wavelength. The direct use of BRDF data set may be inefficient for scene modelling algorithms for example. Thus, models provide compression and additional functionalities like interpolation. One common way consists in fitting an analytical model to the measurements data set using an optimization technique. But this approach is usually restricted to a specific class of surfaces, to a limited angular or spectral range, and the modelling quality may strongly depends on the optimization algorithm chosen. Moreover, analytical models are unable to actually handle the BRDF dependence on wavelength. In this paper we present a new numerical model for acquired spectral BRDF to overcome these drawbacks. This model is based on a separation between the spectral and the geometrical aspect of BRDF, each of them projected into the appropriate wavelet space. After a brief introduction to BRDF, advantages of wavelets and the construction of the model are explained. Then, the performances of modelling are presented and discussed for a large collection of measured and synthetic BRDF data sets. At last, the robustness of the model is tested with synthetic noisy BRDF data.

show abstract

“…Claustres et al proposed wavelet models, which can effectively reduce the number of modeling parameters. 8 The theoretical modeling approach is to resolve the reflected light into distinctive features, e.g., a diffuse component and a specular component, based on physical phenomena. Then each component of the model is parameterized in terms of the measured BRDF data.…”

Section: Introductionmentioning

confidence: 99%

Physically based reflectance model utilizing polarization measurement

Nakano

Tamagawa

2005

Appl. Opt.

View full text Add to dashboard Cite

A surface bidirectional reflectance distribution function (BRDF) depends on both the optical properties of the material and the microstructure of the surface and appears as combination of these factors. We propose a method for modeling the BRDF based on a separate optical-property (refractive-index) estimation by polarization measurement. Because the BRDF and the refractive index for precisely the same place can be determined, errors cased by individual difference or spatial dependence can be eliminated. Our BRDF model treats the surface as an aggregation of microfacets, and the diffractive effect is negligible because of randomness. An example model of a painted aluminum plate is presented.

show abstract

<title>Spectral BRDF modeling using wavelets</title>

Cited by 7 publications

References 20 publications

Compact Representation of Spectral BRDFs Using Fourier Transform and Spherical Harmonic Expansion

Compact Representation of Spectral BRDFs Using Fourier Transform and Spherical Harmonic Expansion

Wavelet-based modeling of spectral bidirectional reflectance distribution function data

Physically based reflectance model utilizing polarization measurement

Contact Info

Product

Resources

About