glTF 2.0
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Nutzung
glTF™ (GL Transmission Format) is used for transmission and loading of 3D models in web and native applications. glTF reduces the size of 3D models and the runtime processing needed to unpack and render those models. This format is commonly used on the web, and has support in various 3D engines such as Unity3D, Unreal Engine 4, and Godot.
This importer/exporter supports the following glTF 2.0 features:
Meshes
Materials (Principled BSDF) and Shadeless (Unlit)
Textures
Cameras
Punctual lights (point, spot, and directional)
Extensions (listed below)
Extras (custom properties)
Animation (keyframe, shape key, and skinning)
Meshes
glTF’s internal structure mimics the memory buffers commonly used by graphics chips when rendering in real-time, such that assets can be delivered to desktop, web, or mobile clients and be promptly displayed with minimal processing. As a result, quads and n-gons are automatically converted to triangles when exporting to glTF. Discontinuous UVs and flat-shaded edges may result in moderately higher vertex counts in glTF compared to Blender, as such vertices are separated for export. Likewise, curves and other non-mesh data are not preserved, and must be converted to meshes prior to export.
Materials
The core material system in glTF supports a metal/rough PBR workflow with the following channels of information:
Base Color
Metallic
Roughness
Baked Ambient Occlusion
Normal Map (tangent space, +Y up)
Emissive
Some additional material properties or types of materials can be expressed using glTF extensions. The complete is can be found in _Extensions_ part of this documentation.
Imported Materials
The glTF material system is different from Blender’s own materials. When a glTF file is imported, the add-on will construct a set of Blender nodes to replicate each glTF material as closely as possible.
The importer supports Metal/Rough PBR (core glTF), Spec/Gloss PBR (KHR_materials_pbrSpecularGlossiness
)
and some extension materials. The complete is can be found in _Extensions_ part of this documentation.
Tipp
Examining the result of the material import process is a good way to see examples of the types of material nodes and settings that can be exported to glTF.
Exported Materials
The exporter supports Metal/Rough PBR (core glTF) and Shadeless (KHR_materials_unlit
) materials.
It will construct a glTF material based on the nodes it recognizes in the Blender material.
The material export process handles the settings described below.
Bemerkung
When image textures are used by materials, glTF requires that images be in PNG or JPEG format. The add-on will automatically convert images from other formats, increasing export time.
Base Color
The glTF base color is determined by looking for a Base Color input on a Principled BSDF node. If the input is unconnected, the input’s default color (the color field next to the unconnected socket) is used as the Base Color for the glTF material.
If an Image Texture node is found to be connected to the Base Color input, that image will be used as the glTF base color.
Metallic and Roughness
These values are read from the Principled BSDF node. If both of these inputs are unconnected, the node will display sliders to control their respective values between 0.0 and 1.0, and these values will be copied into the glTF.
When using an image, glTF expects the metallic values to be encoded in the blue (B
) channel,
and roughness to be encoded in the green (G
) channel of the same image.
If images are connected to the Blender node in a manner that does not follow this convention,
the add-on may attempt to adapt the image to the correct form during exporting (with an increased export time).
In the Blender node tree, it is recommended to use a Separate RGB node
to separate the channels from an Image Texture node, and
connect the green (G
) channel to Roughness, and blue (B
) to Metallic.
The glTF exporter will recognize this arrangement as matching the glTF standard, and
that will allow it to simply copy the image texture into the glTF file during export.
The Image Texture node for this should have its Color Space set to Non-Color.
Baked Ambient Occlusion
glTF is capable of storing a baked ambient occlusion map.
Currently there is no arrangement of nodes that causes Blender
to use such a map in exactly the same way as intended in glTF.
However, if the exporter finds a custom node group by the name of glTF Material Output
, and
finds an input named Occlusion
on that node group,
it will look for an Image Texture attached there to use as the occlusion map in glTF.
The effect need not be shown in Blender, as Blender has other ways of showing ambient occlusion,
but this method will allow the exporter to write an occlusion image to the glTF.
This can be useful to real-time glTF viewers, particularly on platforms where there
may not be spare power for computing such things at render time.
Tipp
The easiest way to create the custom node group is to import an existing glTF model that contains an occlusion map, such as the water bottle or another existing model. A manually created custom node group can also be used.
glTF stores occlusion in the red (R
) channel, allowing it to optionally share
the same image with the roughness and metallic channels.
Tipp
The Cycles render engine has a Bake panel that can be used to bake
ambient occlusion maps. The resulting image can be saved and connected
directly to the glTF Material Output
node.
Normal Map
To use a normal map in glTF, connect an Image Texture node’s color output to a Normal Map node’s color input, and then connect the Normal Map normal output to the Principled BSDF node’s normal input. The Image Texture node for this should have its Color Space property set to Non-Color.
The Normal Map node must remain on its default property of Tangent Space as this is the only type of normal map currently supported by glTF. The strength of the normal map can be adjusted on this node. The exporter is not exporting these nodes directly, but will use them to locate the correct image and will copy the strength setting into the glTF.
Tipp
The Cycles render engine has a Bake panel that can be used to bake tangent-space normal maps from almost any other arrangement of normal vector nodes. Switch the Bake type to Normal. Keep the default space settings (space: Tangent, R: +X, G: +Y, B: +Z) when using this bake panel for glTF. The resulting baked image can be saved and plugged into to a new material using the Normal Map node as described above, allowing it to export correctly.
See: Cycles Render Baking
Emissive
An Image Texture node can be connected to the Emission input on the Principled BSDF node to include an emissive map with the glTF material. Alternatively, the Image Texture node can be connected to an Emission shader node, and optionally combined with properties from a Principled BSDF node by way of an Add Shader node.
If the emissive map is alone in the material, it is best to set the Base Color default to black, and the Roughness default to 1.0. This minimizes the influence of the other channels if they are not needed.
If any component of emissiveFactor is > 1.0, KHR_materials_emissive_strength
extension will be used.
Clearcoat
When the Clearcoat input on the Principled BSDF node has a nonzero default value or
Image Texture node connected, the KHR_materials_clearcoat
glTF extension will be
included in the export. This extension will also include a value or Image Texture
from the Clearcoat Roughness input if available.
If Image Textures are used, glTF requires that the clearcoat values be written to
the red (R
) channel, and Clearcoat Roughness to the green (G
) channel.
If monochrome images are connected, the exporter will remap them to these color channels.
The Clearcoat Normal input accepts the same kinds of inputs as the base Normal input, specifically a tangent-space normal map with +Y up, and a user-defined strength. This input can reuse the same normal map that the base material is using, or can be assigned its own normal map, or can be left disconnected for a smooth coating.
All Image Texture nodes used for clearcoat shading should have their Color Space set to Non-Color.
Sheen
When the Velvet BSDF node is used in addition to Principled BSDF node, the KHR_materials_sheen
glTF
extension will be included in the export. The Sheen Color will be exported from Color socket of Vevlet node.
Sheen Roughness will be exported from Sigma socket.
If a Sheen Rougness Texture is used, glTF requires the values be written to the alpha (A
) channel.
Tipp
Velvet BSDF node is only available on Cycles render engine. You may have to temporary switch to Cycles to add this node, and get back to Eevee.
Bemerkung
Because the node tree is adding 2 Shaders (Principled and Sheen), the resulting shader is not fully energy conservative. You may find some difference between Blender render, and glTF render. Sheen models are not fully compatible between Blender and glTF. This trick about adding Velvet Shader is the most accurate approximation (better that using Sheen Principled sockets).
Specular
When the Specular or Specular Tint input of Principled BSDF node have a non default value or
Image Texture node connected, the KHR_materials_specular
glTF extension will be
included in the export.
Bemerkung
Specular models are not fully compatible between Blender and glTF. By default, Blender data are converted to glTF at export, with a possible loss of information. Some conversion are also performed at import, will a possible loss of information too.
At import, a custom node group is created, to store original Specular data, not converted.
At export, by default, Specular data are converted from Principled BSDF node.
You can export original Specular data, enabling the option at export. If enabled, Principled Specular data are ignored, only data from custom node are used.
Tipp
If you enable Shader Editor Add-ons in preferences, you will be able to add this custom node group from Menu: Add > Output > glTF Material Output
Transmission
When the Transmission input on the Principled BSDF node has a nonzero default value or
Image Texture node connected, the KHR_materials_transmission
glTF extension will be
included in the export. When a texture is used, glTF stores the values in the red (R
) channel.
The Color Space should be set to Non-Color.
Transmission is different from alpha blending, because transmission allows full-strength specular reflections. In glTF, alpha blending is intended to represent physical materials that are partially missing from the specified geometry, such as medical gauze wrap. Transmission is intended to represent physical materials that are solid but allow non-specularly-reflected light to transmit through the material, like glass.
glTF does not offer a separate „Transmission Roughness“, but the material’s base roughness can be used to blur the transmission, like frosted glass.
Tipp
Typically the alpha blend mode of a transmissive material should remain „Opaque“, the default setting, unless the material only partially covers the specified geometry.
Bemerkung
In real-time engines where transmission is supported, various technical limitations in the engine may determine which parts of the scene are visible through the transmissive surface. In particular, transmissive materials may not be visible behind other transmissive materials. These limitations affect physically-based transmission, but not alpha-blended non-transmissive materials.
Warnung
Transmission is complex for real-time rendering engines to implement,
and support for the KHR_materials_transmission
glTF extension is not yet widespread.
IOR
At import, there are two different situation:
if
KHR_materials_ior
is not set, IOR value of Principled BSDF node is set to 1.5, that is the glTF default value of IOR.If set, the
KHR_materials_ior
is used to set the IOR value of Principled BSDF.
At export, IOR is included in the export only if one of these extensions are also used:
KHR_materials_transmission
KHR_materials_volume
KHR_materials_specular
IOR of 1.5 are not included in the export, because this is the default glTF IOR value.
Volume
Volume can be exported using a Volume Absorption node, linked to Volume socket of Output node.
Data will be exported using the KHR_materials_volume
extension.
For volume to be exported, some transmission must be set on Principled BSDF node.
Color of Volume Absorption node is used as glTF attenuation color. No texture is allowed for this property.
Density of Volume Absorption node is used as inverse of glTF attenuation distance.
Thickess can be plugged into the Thickess socket of custom group node
glTF Material Output
.If a texture is used for thickness, it must be plugged on (
G
) Green channel of the image.
glTF Variants
Bemerkung
For a full Variants experience, you have to enable UI in Add-on preferences
There are two location to manage glTF Variants in Blender
In 3D View, on
glTF Variants
tabFor advanced settings, in Mesh Material Properties (see Advanced glTF Variant checks)
The main concept to understand for using Variants, is that each material slot will be used as equivalent of a glTF primitive.
glTF Variants switching
After importing a glTF file including KHR_materials_variants
extension, all variants can be displayed.
You can switch Variant, by selecting the variant you want to display, then clicking on Display Variant.
You can switch to default materials (when no Variant are used), by clicking on Reset to default.
glTF Variants creation
You can add a new Variant by clicking the +
at right of the Variant list. Then you can change the name by double-clicking.
After changing Materials in Material Slots, you can assign current materials to the active Variant using Assign to Variant.
You can also set default materials using Assign as Original. These materials will be exported as default material in glTF.
This are materials that will be displayed by any viewer that don’t manage KHR_materials_variants
extension.
Advanced glTF Variant checks
If you want to check primitive by primitive, what are Variants used, you can go to Mesh Material Properties.
The glTF Material Variants tab refers to the active material Slot and Material used by this slot. You can see every Variants that are using this material for the given Slot/Primitive.
You can also assign material to Variants from this tab, but recommandation is to perform it from 3D View tab.
Double-Sided / Backface Culling
For materials where only the front faces will be visible, turn on Backface Culling in the Settings panel of an Eevee material. When using other engines (Cycles, Workbench) you can temporarily switch to Eevee to configure this setting, then switch back.
Leave this box unchecked for double-sided materials.
Blend Modes
The Base Color input can optionally supply alpha values. How these values are treated by glTF depends on the selected blend mode.
With the Eevee render engine selected, each material has a Blend Mode on the material settings panel. Use this setting to define how alpha values from the Base Color channel are treated in glTF. Three settings are supported by glTF:
- Opaque
Alpha values are ignored.
- Alpha Blend
Lower alpha values cause blending with background objects.
- Alpha Clip
Alpha values below the Clip Threshold setting will cause portions of the material to not be rendered at all. Everything else is rendered as opaque.
Bemerkung
Be aware that transparency (or Alpha Blend mode) is complex for real-time engines to render, and may behave in unexpected ways after export. Where possible, use Alpha Clip mode instead, or place Opaque polygons behind only a single layer of Alpha Blend polygons.
UV Mapping
Control over UV map selection and transformations is available by connecting a UV Map node and a Mapping node to any Image Texture node.
Settings from the Mapping node are exported using a glTF extension named KHR_texture_transform
.
There is a mapping type selector across the top. Point is the recommended type for export.
Texture and Vector are also supported. The supported offsets are:
Location - X and Y
Rotation - Z only
Scale - X and Y
For the Texture type, Scale X and Y must be equal (uniform scaling).
Tipp
These nodes are optional. Not all glTF readers support multiple UV maps or texture transforms.
Factors
Any Image Texture nodes may optionally be multiplied with a constant color or scalar. These will be written as factors in the glTF file, which are numbers that are multiplied with the specified image textures. These are not common.
Example
A single material may use all of the above at the same time, if desired. This figure shows a typical node structure when several of the above options are applied at once:
Exporting a Shadeless (Unlit) Material
To export an unlit material, mix in a camera ray, and avoid using the Principled BSDF node.
Endung
The core glTF 2.0 format can be extended with extra information, using glTF extensions. This allows the file format to hold details that were not considered universal at the time of first publication. Not all glTF readers support all extensions, but some are fairly common.
Certain Blender features can only be exported to glTF via these extensions. The following glTF 2.0 extensions are supported directly by this add-on:
Import
KHR_materials_pbrSpecularGlossiness
KHR_materials_clearcoat
KHR_materials_transmission
KHR_materials_unlit
KHR_materials_emissive_strength
KHR_materials_volume
KHR_materials_sheen
KHR_materials_specular
KHR_materials_ior
KHR_materials_variants
KHR_lights_punctual
KHR_texture_transform
KHR_mesh_quantization
Export
KHR_draco_mesh_compression
KHR_lights_punctual
KHR_materials_clearcoat
KHR_materials_transmission
KHR_materials_unlit
KHR_materials_emissive_strength
KHR_materials_volume
KHR_materials_sheen
KHR_materials_specular
KHR_materials_ior
KHR_materials_variants
KHR_texture_transform
Third-party glTF Extensions
It is possible for Python developers to add Blender support for additional glTF extensions by writing their own third-party add-on, without modifying this glTF add-on. For more information, see the example on GitHub and if needed, register an extension prefix.
Custom Properties
Custom properties are always imported, and will be exported from most objects
if the extras
field on the corresponding object in the glTF file.
Unlike glTF extensions, custom properties (extras) have no defined namespace, and may be used for any user-specific or application-specific purposes.
Animation
A glTF animation changes the transforms of objects or pose bones, or the values of shape keys. One animation can affect multiple objects, and there can be multiple animations in a glTF file.
Import
Imported models are set up so that the first animation in the file is playing automatically. Scrub the Timeline to see it play.
When the file contains multiple animations, the rest will be organized using the Nonlinear Animation editor. Each animation becomes an action stashed to an NLA track. The track name is the name of the glTF animation. To make the animation within that track visible, click Solo (star icon) next to the track you want to play.
If an animation affects multiple objects, it will be broken up into multiple parts. The part of the animation that affects one object becomes an action stashed on that object. Use the track names to tell which actions are part of the same animation. To play the whole animation, you need to enable Solo (star icon) for all its tracks.
Bemerkung
There is currently no way to see the non-animated pose of a model that had animations.
Export
You can export animations by creating actions. How glTF animations are made from actions is controlled by the
export option.Group by NLA Track on (default)
An action will be exported if it is the active action on an object, or it is stashed to an NLA track (e.g. with the Stash or Push Down buttons in the Action Editor). Actions which are not associated with an object in one of these ways are not exported. If you have multiple actions you want to export, make sure they are stashed!
A glTF animation can have a name, which is the action name by default. You can override it
by renaming its NLA track from NLATrack
/[Action Stash]
to the name you want to use.
For example, the Fig. fox model will export with three animations,
„Survey“, „Walk“, and „Run“.
If you rename two tracks on two different objects to the same name, they will become part
of the same glTF animation and will play together.
The importer organizes actions so they will be exported correctly with this mode.
Group by NLA Track off
In this mode, the NLA organization is not used, and only one animation is exported using the active actions on all objects.
Bemerkung
For both modes, remember only certain types of animation are supported:
Object transform (location, rotation, scale)
Pose bones
Shape key values
Animation of other properties, like physics, lights, or materials, will be ignored.
Bemerkung
In order to sample shape key animations controlled by drivers using bone transformations, they must be on a mesh object that is a direct child of the bones‘ armature.
File Format Variations
The glTF specification identifies different ways the data can be stored. The importer handles all of these ways. The exporter will ask the user to select one of the following forms:
glTF Binary (.glb
)
This produces a single .glb
file with all mesh data, image textures, and
related information packed into a single binary file.
Tipp
Using a single file makes it easy to share or copy the model to other systems and services.
glTF Separate (.gltf
+ .bin
+ textures)
This produces a JSON text-based .gltf
file describing the overall structure,
along with a .bin
file containing mesh and vector data, and
optionally a number of .png
or .jpg
files containing image textures
referenced by the .gltf
file.
Tipp
Having an assortment of separate files makes it much easier for a user to go back and edit any JSON or images after the export has completed.
Bemerkung
Be aware that sharing this format requires sharing all of these separate files together as a group.
glTF Embedded (.gltf
)
This produces a JSON text-based .gltf
file, with all mesh data and
image data encoded (using Base64) within the file. This form is useful if
the asset must be shared over a plain-text-only connection.
Warnung
This is the least efficient of the available forms, and should only be used when required.
Eigenschaften
Import
- Pack Images
Pack all images into the blend-file.
- Shading
How normals are computed during import.
- Guess Original Bind Pose
Determines the pose for bones (and consequently, skinned meshes) in Edit Mode. When on, attempts to guess the pose that was used to compute the inverse bind matrices.
- Bone Direction
Changes the heuristic the importer uses to decide where to place bone tips. Note that the Fortune setting may cause inaccuracies in models that use non-uniform scaling. Otherwise this is purely aesthetic.
Export
- Dateiformat
See: File Format Variations.
- Textures
Folder to place texture files in. Relative to the gltf-file.
- Copyright
Legal rights and conditions for the model.
- Remember Export Settings
Store export settings in the blend-file, so they will be recalled next time the file is opened.
Include
- Selected Objects
Export selected objects only.
- Visible Objects
Export visible objects only.
- Renderable Objects
Export renderable objects only.
- Active Collection
Export objects from active collection only.
- Active Scene
Export active scene only.
- Custom Properties
Export custom properties as glTF extras.
- Cameras
Export cameras.
- Punctual Lights
Export directional, point, and spot lights. Uses the
KHR_lights_punctual
glTF extension.
Transform
- Y Up
Export using glTF convention, +Y up.
Geometry
- Apply Modifiers
Export objects using the evaluated mesh, meaning the resulting mesh after all Modifiers have been calculated.
- UVs
Export UVs (texture coordinates) with meshes.
- Normals
Export vertex normals with meshes.
- Tangents
Export vertex tangents with meshes.
- Vertex Colors
Export Color Attributes with meshes.
- Loose Edges
Export loose edges as lines, using the material from the first material slot.
- Loose Points
Export loose points as glTF points, using the material from the first material slot.
- Materials
Export full materials, only placeholders (all primitives but without materials), or does not export materials. (In that last case, primitive are merged, lossing material slot information).
- Bilder
Output format for images. PNG is lossless and generally preferred, but JPEG might be preferable for web applications due to the smaller file size. If None is chosen, materials are exported without textures.
Compression
Compress meshes using Google Draco.
- Compression Level
Higher compression results in slower encoding and decoding.
- Quantization Position
Higher values result in better compression rates.
- Normal
Higher values result in better compression rates.
- Texture Coordinates
Higher values result in better compression rates.
- Color
Higher values result in better compression rates.
- Generic
Higher values result in better compression rates.
Animation
- Use Current Frame
Export the scene in the current animation frame. For rigs, when off, rest pose is used as default pose for joints in glTF file. When on, the current frame is used as default pose for joints in glTF file.
Animation
Exports active actions and NLA tracks as glTF animations.
- Limit to Playback Range
Clips animations to selected playback range.
- Sampling Rate
How often to evaluate animated values (in frames).
- Always Sample Animations
Apply sampling to all animations.
- Group by NLA Track
Whether to export NLA strip animations.
- Optimize Animation Size
Reduce exported file-size by removing duplicate keyframes.
- Export Deformation Bones Only
Export deformation bones only.
Shape Keys
Export shape keys (morph targets).
- Shape Key Normals
Export vertex normals with shape keys (morph targets).
- Shape Key Tangents
Export vertex tangents with shape keys (morph targets).
Skinning
Export skinning (armature) data.
- Include All Bone Influences
Allow more than 4 joint vertex influences. Models may appear incorrectly in many viewers.
Contributing
This importer/exporter is developed through the glTF-Blender-IO repository, where you can file bug reports, submit feature requests, or contribute code.
Discussion and development of the glTF 2.0 format itself takes place on the Khronos Group glTF GitHub repository, and feedback there is welcome.