Principled BSDF

Principled BSDF node.

The Principled BSDF that combines multiple layers into a single easy to use node. It is based on the Disney principled model also known as the ”PBR” shader, making it compatible with other software such as Pixar’s Renderman® and Unreal Engine®. Image textures painted or baked from software like Substance Painter® may be directly linked to the corresponding parameters in this shader.

This ”Uber” shader includes multiple layers to create a wide variety of materials. The base layer is a user controlled mix between diffuse, metal, subsurface scattering and transmission. On top of that there is a specular layer, sheen layer and clearcoat layer.

Muista

The emphasis on compatibility with other software means that it interprets certain input parameters differently from older Blender nodes.

Inputs

Base Color

Diffuse or metal surface color.

Subsurface

Mix between diffuse and subsurface scattering. Rather than being a simple mix between Diffuse and Subsurface Scattering, it acts as a multiplier for the Subsurface Radius.

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.

Subsurface Color

Subsurface scattering base color.

Subsurface IOR Cycles Only

Index of refraction for Subsurface Scattering.

Subsurface Anisotropy Cycles Only

Controls the directionality of subsurface scattering.

Metallic

Blends between a non-metallic and metallic material model. A value of 1.0 gives a fully specular reflection tinted with the base color, without diffuse reflection or transmission. At 0.0 the material consists of a diffuse or transmissive base layer, with a specular reflection layer on top.

Specular

Amount of dielectric specular reflection. Specifies facing (along normal) reflectivity in the most common 0 - 8% range.

Vihje

To compute this value for a realistic material with a known index of refraction, you may use this special case of the Fresnel formula: \(specular = ((ior - 1)/(ior + 1))^2 / 0.08\)

For example:

  • water: ior = 1.33, specular = 0.25

  • glass: ior = 1.5, specular = 0.5

  • diamond: ior = 2.417, specular = 2.15

Since materials with reflectivity above 8% do exist, the field allows values above 1.

Specular Tint

Tints the facing specular reflection using the base color, while glancing reflection remains white.

Normal dielectrics have colorless reflection, so this parameter is not technically physically correct and is provided for faking the appearance of materials with complex surface structure.

Roughness

Specifies microfacet roughness of the surface for diffuse and specular reflection.

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.

Vihje

Compared to the Anisotropic BSDF node, the direction of highlight elongation is rotated by 90°. Add 0.25 to the value to correct.

Sheen

Amount of soft velvet like reflection near edges, for simulating materials such as cloth.

Sheen Tint

Mix between white and using base color for sheen reflection.

Clearcoat

Extra white specular layer on top of others. This is useful for materials like car paint and the like.

Clearcoat Roughness:

Roughness of clearcoat specular.

IOR

Index of refraction for transmission.

Transmission

Mix between fully opaque surface at zero and fully glass like transmission at one.

Transmission Roughness Cycles Only

With GGX distribution controls roughness used for transmitted light.

Emission

Light emission from the surface, like the Emission shader.

Emission Strength

Strength of the emitted light. A value of 1.0 will ensure that the object in the image has the exact same color as the Emission Color, i.e. make it ’shadeless’.

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.

Clearcoat Normal

Controls the normals of the Clearcoat layer.

Tangent

Controls the tangent for the Anisotropic layer.

Properties

Distribution

Microfacet distribution to use.

GGX

A method that is faster than Multiple-scattering GGX but is less physically accurate. Selecting it enables the Transmission Roughness input.

Multiple-scattering GGX

Takes multiple bounce (scattering) events between microfacets into account. This gives a more energy conserving results, which would otherwise be visible as excessive darkening.

Subsurface Method

Rendering method to simulate subsurface scattering.

Muista

Eevee does use not support the Random Walk methods.

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 (Fixed Radius)

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

Behaves similarly to Random Walk (Fixed Radius) but modulates the Subsurface Radius based on the Color, Subsurface Anisotropy, and Subsurface IOR. This method thereby attempts to retain greater surface detail and color than Random Walk (Fixed Radius).

Outputs

BSDF

Standard shader output.

Examples

Below are some examples of how all the Principled BSDF’s parameters interact with each other.

../../../_images/render_shader-nodes_shader_principled_example-1a.jpg
../../../_images/render_shader-nodes_shader_principled_example-2a.jpg
../../../_images/render_shader-nodes_shader_principled_example-2b.jpg