Difference between revisions of "Material Data"

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[[Category:Materials]]
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{{RightToc}}


{{Warning|The information in this page applies to the work being done in the {{JiraIssue|STORM-1905|Normal & Specular Maps (aka Materials) Project}}None of this will work until that has been completed and released - and until that time, it may be subject to change.}}
This page describes how the various parameters and texture data used to define a material in Second Life are interpreted for rendering. It is intended to help content creators and external tool developers to better understand how to create images to achieve good visual results.
 
There are as many as two colors and three images associated with a face. 
For a more detailed explanation of the fundamentals of materials, see Pedro Toledo's [http://www.manufato.com/?p=902 Brief Considerations About Materials]
{{KBnote|'''Setting any of the materials properties on an object causes its Land Impact to be calculated using the current algorithm.'''
 
The additional textures used for Normal and Specular maps add to the Download Weight of the object.   


This page describes how the various parameters and texture data used to define a material in Second Life are interpreted for rendering. It is intended to help content creators and external tool developers to better understand how to create images to achieve good visual results.
If the object was previously using the legacy accounting (prim count), setting a material property on it may increase costs significantly due to other properties (such as complex shapes) that are more accurately accounted for in the current system.


For details, see [http://community.secondlife.com/t5/English-Knowledge-Base/Calculating-land-impact/ta-p/974163 Calculating land impact] and [[Physics Optimization]].
}}


There are as many as two colors and three images associated with a face. 
==Colors==
==Colors==


;Color
;Color
:a solid color for the surface; not used if a Texture is also specified
:a solid color for the surface; Tints the color of the diffuse map.


;Specular Color
;Specular Color
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==Textures==
==Textures==
<br>
{{KBtip|For Blender users, you may find the tutorial [https://aiaicapta.in/how-to-channel-pack-materials-for-secondlife/ here] useful for information on how to 'bake' material maps correctly in Second Life.}}


===Texture===
===Texture===
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===Normal Map===
===Normal Map===


An image whose color data encodes changes to the "normal" for each pixel on the surface.  The normal is the direction that the pixel "faces" for the purpose of determining how it is illuminated by and reflects light sources (imagine that each pixel is turned on tiny pivots).  Keep in mind these are OpenGL style normal maps, where bright green is up and bright red is right. For details on what a normal map is and for a sample normal map see http://en.wikipedia.org/wiki/Normal_mapping.  See also the [[#Texture Channel Encoding|Texture Channel Encoding]] table below.
An image whose color data encodes changes to the "normal" for each pixel on the surface.  The normal is the direction that the pixel "faces" for the purpose of determining how it is illuminated by and reflects light sources (imagine that each pixel is turned on tiny pivots).  The alpha channel of the Normal Map may contain a specular exponent value that is mutilplied by the "Glossiness" parameter.  A higher alpha value will result in specular highlights that are brighter and tighter.  Keep in mind these are OpenGL style normal maps, where bright green is up and bright red is right. (or to put in Industry terms, the normal maps are X+, Y+, Z+ normal maps)
 
For details on what a normal map is and for a sample normal map see http://en.wikipedia.org/wiki/Normal_mapping.  See also the [[#Texture Channel Encoding|Texture Channel Encoding]] table below.


;Positioning:The Normal Map has its own set of the same [[#Positioning &amp; Scaling Properties|Positioning &amp; Scaling Properties]] properties as the [[#Texture|Texture]].
;Positioning:The Normal Map has its own set of the same [[#Positioning &amp; Scaling Properties|Positioning &amp; Scaling Properties]] properties as the [[#Texture|Texture]].
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This encodes the color of the light reflected by each pixel on the surface.  See the [[#Texture Channel Encoding|Texture Channel Encoding]] table below.
This encodes the color of the light reflected by each pixel on the surface.  See the [[#Texture Channel Encoding|Texture Channel Encoding]] table below.


The Alpha channel value of the Specular Map encodes the specular exponent, or "Glossiness" of the surface.  A lower value in the alpha channel will make specular highlights broader and more diffuse, like in plastic or rough stone, while a higher value will make specular highlights tighter and brighter, like in metal or polished stone/wood.
The Alpha channel value of the Specular Map encodes the environment intensity.  A lower value in the alpha channel will diminish the impact of the environment map reflections on the surface of the object.


;Positioning:The Specular Map has its own set of the same [[#Positioning &amp; Scaling Properties|Positioning &amp; Scaling Properties]] properties as the [[#Texture|Texture]].
;Positioning:The Specular Map has its own set of the same [[#Positioning &amp; Scaling Properties|Positioning &amp; Scaling Properties]] properties as the [[#Texture|Texture]].
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|Normal Y Axis
|Normal Y Axis
|Normal Z Axis
|Normal Z Axis
|Specular Exponent
|Specular exponent
|+
|+
!Specular Map
!Specular Map
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|Green
|Green
|Blue
|Blue
|Environment Mask
|Environment intensity
|}
|}


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:;Transparency (blended):The value is a degree of transparency (255 = opaque, 0 = fully transparent)
:;Transparency (blended):The value is a degree of transparency (255 = opaque, 0 = fully transparent)
:;Alpha Mask (cutoff):The value (0...255) is compared to the Alpha Cutoff parameter (below); if the pixel is greater than the cutoff, it is fully opaque; if not, it is fully transparent.
:;Alpha Mask (cutoff):The value (0...255) is compared to the Alpha Cutoff parameter (below); if the pixel is greater than the cutoff, it is fully opaque; if not, it is fully transparent.
:;Emissive:The value is used to encode how brightly the pixel emits light (glows): 0 = no glow; 255 = full brightness
:;Emissive:The value is used to encode how brightly the pixel appears in the absence of light (ambiance): 0 = no additional ambiance (default); 255 = full brightness
:''Note that using any alpha mode other than Transparency may cause problems when rendered with viewers that do not yet support materials because they will be rendered as blended transparency.  We expect that support for materials will be adopted quickly in most viewers, so this is acceptable.''


;Alpha Cutoff
;Alpha Cutoff
:Used only when Alpha Mode is Alpha Test (see description of that mode above)
:Used only when Alpha Mode is Alpha Mask (see description of that mode above)


;Specular Light Color
;Specular Light Color
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;Environment Intensity
;Environment Intensity
:Modulates the intensity of the environment on the surface as a whole.  When an environment mask is present in the specular map, the environment mask is modulated by this to provide better control over the intensity of the environment that’s being reflected (some parts of the surface can reflect the environment more or less than others).
:Modulates the intensity of the environment on the surface as a whole.   


;Glossiness
;Glossiness
:This controls the “glossiness”, or the roughness, of the reflected light on a surface.  The lower this value is, the “rougher” the light reflectance is, while the higher the value the “sharper” the light reflectance is.  When the normal map’s alpha channel is present, the specular exponent map contained in it is modulated by this parameter.
:This controls the “glossiness”, or the roughness, of the reflected light on a surface.  The lower this value is, the “rougher” the light reflectance is, while the higher the value the “sharper” the light reflectance is.  When the normal map’s alpha channel is present, the specular exponent map contained in it is modulated by this parameter.

Latest revision as of 10:18, 28 June 2022


This page describes how the various parameters and texture data used to define a material in Second Life are interpreted for rendering. It is intended to help content creators and external tool developers to better understand how to create images to achieve good visual results.

There are as many as two colors and three images associated with a face. For a more detailed explanation of the fundamentals of materials, see Pedro Toledo's Brief Considerations About Materials

KBnote.png Note: Setting any of the materials properties on an object causes its Land Impact to be calculated using the current algorithm.

The additional textures used for Normal and Specular maps add to the Download Weight of the object.

If the object was previously using the legacy accounting (prim count), setting a material property on it may increase costs significantly due to other properties (such as complex shapes) that are more accurately accounted for in the current system.

For details, see Calculating land impact and Physics Optimization.

Colors

Color
a solid color for the surface; Tints the color of the diffuse map.
Specular Color
this is a color that ‘tints’ any reflections from the face; see also Specular Map

Textures


KBtip2.png Tip: For Blender users, you may find the tutorial here useful for information on how to 'bake' material maps correctly in Second Life.

Texture

Also called the Diffuse Map, this is an image that is displayed on the surface. The way the texture is applied to the face is controlled by

Positioning & Scaling Properties

Note that each image (diffuse/texture, normal map, specular map) has its own values for these parameters.

Mapping
Default or Planar
Horizontal Repeats
number of repeats of the image over the surface (used only in default mapping)
Vertical Repeats
number of repeats of the image over the surface (used only in default mapping)
Rotation
clockwise degrees the image is rotated
Repeats Per Meter
number of repeats of the image per in-world meter of the surface (used only in planar mapping)
Horizontal Offset
distance in meters the image is shifted right on the surface
Vertical Offset
distance in meters the image is shifted up on the surface

Normal Map

An image whose color data encodes changes to the "normal" for each pixel on the surface. The normal is the direction that the pixel "faces" for the purpose of determining how it is illuminated by and reflects light sources (imagine that each pixel is turned on tiny pivots). The alpha channel of the Normal Map may contain a specular exponent value that is mutilplied by the "Glossiness" parameter. A higher alpha value will result in specular highlights that are brighter and tighter. Keep in mind these are OpenGL style normal maps, where bright green is up and bright red is right. (or to put in Industry terms, the normal maps are X+, Y+, Z+ normal maps)

For details on what a normal map is and for a sample normal map see http://en.wikipedia.org/wiki/Normal_mapping. See also the Texture Channel Encoding table below.

Positioning
The Normal Map has its own set of the same Positioning & Scaling Properties properties as the Texture.

Specular Map

This encodes the color of the light reflected by each pixel on the surface. See the Texture Channel Encoding table below.

The Alpha channel value of the Specular Map encodes the environment intensity. A lower value in the alpha channel will diminish the impact of the environment map reflections on the surface of the object.

Positioning
The Specular Map has its own set of the same Positioning & Scaling Properties properties as the Texture.

Texture Channel Encoding

How the renderer will treat each color value in a texture image channel
Parameter Red Green Blue Alpha
Diffuse Map Red Green Blue selectable

see Alpha Mode

Normal Map Normal X Axis Normal Y Axis Normal Z Axis Specular exponent
Specular Map Red Green Blue Environment intensity

Additional Parameters

Alpha Mode
This controls the interpretation of the Alpha channel data in the Diffuse Map. It can have one of four values:
None
Alpha channel data is not used
Transparency (blended)
The value is a degree of transparency (255 = opaque, 0 = fully transparent)
Alpha Mask (cutoff)
The value (0...255) is compared to the Alpha Cutoff parameter (below); if the pixel is greater than the cutoff, it is fully opaque; if not, it is fully transparent.
Emissive
The value is used to encode how brightly the pixel appears in the absence of light (ambiance): 0 = no additional ambiance (default); 255 = full brightness
Note that using any alpha mode other than Transparency may cause problems when rendered with viewers that do not yet support materials because they will be rendered as blended transparency. We expect that support for materials will be adopted quickly in most viewers, so this is acceptable.
Alpha Cutoff
Used only when Alpha Mode is Alpha Mask (see description of that mode above)
Specular Light Color
Tints the light reflected from the object; this value is combined with any value from the color for the pixel as specified in the Specular Map, if any.
Environment Intensity
Modulates the intensity of the environment on the surface as a whole.
Glossiness
This controls the “glossiness”, or the roughness, of the reflected light on a surface. The lower this value is, the “rougher” the light reflectance is, while the higher the value the “sharper” the light reflectance is. When the normal map’s alpha channel is present, the specular exponent map contained in it is modulated by this parameter.