Principled BSDF¶
The Principled BSDF that combines multiple layers into a single easy to use node. It can model a wide variety of materials.
It is based on the OpenPBR Surface shading model, and provides parameters compatible with similar PBR shaders found in other software, such as the Disney and Standard Surface models. Image textures painted or baked from software like Substance Painter may be directly linked to the corresponding input in this shader.
Layers¶
The base layer is a mix between metal, diffuse, subsurface, and transmission components. Most materials will use one of these components, though it is possible to smoothly mix between them.
The metal component is opaque and only reflect lights. Diffuse is fully opaque, while subsurface also involves light scattering just below the surface. Both diffuse and subsurface sit below a specular layer. The transmission component includes both specular reflection and refraction.
On top of all base layers there is an optional glossy coat. And finally the sheen layer sits on top of all other layers, to add fuzz or dust.
Light emission can also be added. Light emits from below the coat and sheen layers, to model for example emissive displays with a coat or dust.
Inputs¶
- Base Color
Overall color of the material used for diffuse, subsurface, metal and transmission.
- Roughness
Specifies microfacet roughness of the surface for specular reflection and transmission. A value of 0.0 gives a perfectly sharp reflection, while 1.0 gives a diffuse reflection.
- Metallic
Blends between a dielectric and metallic material model. At 0.0 the material consists of a diffuse or transmissive base layer, with a specular reflection layer on top. A value of 1.0 gives a fully specular reflection tinted with the base color, without diffuse reflection or transmission.
- IOR
Index of refraction (IOR) for specular reflection and transmission. For most materials, the IOR is between 1.0 (vacuum and air) and 4.0 (germanium). The default value of 1.5 is a good approximation for glass.
- Alpha
Controls the transparency of the surface, with 1.0 fully opaque. Usually linked to the Alpha output of an Image Texture node.
- Normal
Controls the normals of the base layers.
Diffuse¶
- Roughness Cycles Only
Surface roughness; 0.0 gives standard Lambertian reflection, higher values activate the Oren-Nayar BSDF.
Subsurface¶
Subsurface scattering is used to render materials such as skin, milk and wax. Light scatters below the surface to create a soft appearance.
- Method
Rendering method to simulate Subsurface scattering.
- Christensen-Burley:
An approximation to physically-based volume scattering. This method is less accurate than Random Walk however, in some situations this method will resolve noise faster.
- Random Walk:
Cycles Only Provides accurate results for thin and curved objects. Random Walk uses true volumetric scattering inside the mesh, which means that it works best for closed meshes. Overlapping faces and holes in the mesh can cause problems.
- Random Walk (Skin):
Cycles Only Random walk method optimized for skin rendering. The radius is automatically adjusted based on the color texture, and the subsurface entry direction uses a mix of diffuse and specular transmission with custom IOR. This tends to retain greater surface detail and color and matches measured skin more closely.
- Weight
Blend between diffuse surface and subsurface scattering. Typically should be zero or one (either fully diffuse or subsurface).
- Radius
Average distance that light scatters below the surface. Higher radius gives a softer appearance, as light bleeds into shadows and through the object. The scattering distance is specified separately for the RGB channels, to render materials such as skin where red light scatters deeper. The X, Y and Z values are mapped to the R, G and B values, respectively.
- Scale
Scale applied to the radius.
- IOR Cycles Only
Index of refraction (IOR) used for rays that enter the subsurface component. This may be set to a different value than the global IOR to simulate different layers of skin.
- Anisotropy Cycles Only
Directionality of volume scattering within the subsurface medium. Zero scatters uniformly in all directions, with higher values scattering more strongly forward. For example, skin has been measured to have an anisotropy of 0.8.
Specular¶
Controls for both the metallic component and specular layer on top of diffuse and subsurface.
- Distribution
Microfacet distribution to use.
- GGX:
A method that is faster than Multiple-scattering GGX but is less physically accurate.
- Multiscatter GGX:
Takes multiple scattering events between microfacets into account. This gives more energy conserving results, which would otherwise be visible as excessive darkening.
- IOR Level
Adjustment to the IOR to increase or decrease intensity of the specular layer. 0.5 means no adjustment, 0 removes all reflections, 1 doubles them at normal incidence.
This input is designed for conveniently texturing the IOR and amount of specular reflection.
- Tint
Color tint for specular and metallic reflection.
For non-metallic tints provides artistic control over the color specular reflections at normal incidence, while grazing reflections remain white. In reality non-metallic specular reflection is fully white.
For metallic materials tints the edges to simulate complex IOR as found in materials such as gold or copper.
- Anisotropic Cycles Only
Amount of anisotropy for specular reflection. Higher values give elongated highlights along the tangent direction; negative values give highlights shaped perpendicular to the tangent direction.
- Anisotropic Rotation Cycles Only
Rotates the direction of anisotropy, with 1.0 going full circle.
Compared to the Anisotropic BSDF node, the direction of highlight elongation is rotated by 90°. Add 0.25 to the value to correct.
- Tangent
Controls the tangent direction for anisotropy.
Transmission¶
Transmission is used to render materials like glass and liquids, where the surface both reflects light and transmits it into the interior of the object
- Weight
Mix between fully opaque surface at zero and fully transmissive at one.
Coat¶
Coat on top of the materials, to simulate for example a clearcoat, lacquer or car paint.
- Weight
Controls the intensity of the coat layer, both the reflection and the tinting. Typically should be zero or one for physically-based materials, but may be textured to vary the amount of coating across the surface.
- Roughness
Roughness of the coat layer.
- IOR
Index of refraction (IOR) of the coat layer. Affects its reflectivity as well as the falloff of coat tinting.
- Tint
Adds a colored tint to the coat layer by modeling absorption in the layer. Saturation increases at shallower angles, as the light travels farther through the medium, depending on the IOR.
- Normal
Controls the normals of the Coat layer, for example to add a smooth coating on a rough surface.
Sheen¶
Sheen simulates very small fibers on the surface. For cloth this adds a soft velvet like reflection near edges. It can also be used to simulate dust on arbitrary materials.
- Weight
Controls in the intensity of the sheen layer.
- Roughness
Roughness of the sheen reflection.
- Tint
The color of the sheen reflection.
Emission¶
Light emission from the surface.
- Color
Color of light emission from the surface.
- Strength
Strength of the emitted light. A value of 1.0 ensures that the object in the image has the exact same color as the Emission Color, i.e. make it ’shadeless’.
Thin Film Cycles Only¶
Thin Film simulates the effect of interference in a thin film sitting on top of the material. This causes the specular reflection to be colored in a way which strongly depends on the view angle as well as the film thickness and the index of refraction (IOR) of the film and the material itself.
This effect is commonly seen on e.g. oil films, soap bubbles or glass coatings. While its influence is more obvious in specular highlights, it also affects transmission.
Merknad
Thin-film interference is currently only applied to dielectric materials. Support for thin films on top of Metallic is planned in the future.
- Thickness
The thickness of the film in nanometers. A value of 0 disables the simulation. The interference effect is strongest between roughly 100 and 1000 nanometers, since this is near the wavelengths of visible light.
- IOR
Index of refraction (IOR) of the thin film. The common range for this value is between 1.0 (vacuum and air) and roughly 2.0, though some materials can reach higher values. The default value of 1.33 is a good approximation for water. Note that when the value is set to 1.0 or to the main IOR of the material, the thin film effect disappears since the film optically blends into the air or the material.
Outputs¶
- BSDF
Standard shader output.