There are two sets of GI lightmaps: Baked and Realtime. How you define which set to use depends on whether you’re working with environment lighting or specific lights:
Global illuminationA group of techniques that model both direct and indirect lighting to provide realistic lighting results. Unity has two global illumination systems that combine direct and indirect lighting.: Baked Global Illumination, and Realtime Global Illumination (deprecated).
See in Glossary (environment lighting) can be set to Realtime or Baked. Go to Window > RenderingThe process of drawing graphics to the screen (or to a render texture). By default, the main camera in Unity renders its view to the screen. More info
See in Glossary > Lighting Settings and choose an option from the Ambient GI drop-down menu.
Lights can be set to Realtime, Baked or Mixed.
Materials have emission controls that can be set to Realtime or Baked. See documentation on Standard Shader Material parameter emissions to learn more.
|LightmapA pre-rendered texture that contains the effects of light sources on static objects in the scene. Lightmaps are overlaid on top of scene geometry to create the effect of lighting. More info
See in Glossary
|Baked||Baked lightmaps are mainly useful for lights which do not change at all during run time (for example, a lit streetlamp), and are therefore stored as a static rendering in the lightmap. Features include direct lighting, indirect lighting, and baked ambient occlusionA method to approximate how much ambient light (light not coming from a specific direction) can hit a point on a surface.
See in Glossary.
|Realtime||Real-time lightmaps are mainly useful for lights that are animated during runtime (for example, a flickering street lamp), and therefore need to be rendered in real time. Features include indirect lighting only, and typically low resolution. Direct light is not in the lightmap, but is rendered in real time.|
|Mixed||When you set a light to Mixed mode, it contributes to the baked lightmaps, and also gives direct real-time lighting to non-static objects.|
You can use either one or both of these lightmap sets to light your ScenesA Scene contains the environments and menus of your game. Think of each unique Scene file as a unique level. In each Scene, you place your environments, obstacles, and decorations, essentially designing and building your game in pieces. More info
See in Glossary. Your choice determines which lightmaps the light contributions and resulting GI is added to.
It is important to be able to view the UVs that are being used, and Unity has a visualization tool to help you with this. First, open the Lighting window (menu: Window > Rendering > Lighting Settings) and tick the Auto checkbox at the bottom. This ensures that your bake and precompute are up-to-date, and outputs the data that is needed to view the UVs. Wait for the process to finish (this can take some time for large or complex Scenes).
To see the precomputed real-time GI UVs:
This displays the UV layout for the real-time lightmap of the selected instance of this Mesh.
Multiple instances can be packed into a real-time lightmap, so some of the charts you see might actually belong to other GameObjects.
NOTE: There is no direct correspondence in the grouping of instances between real-time and baked lightmaps. Two instances in the same real-time lightmap may also be in two different baked lightmaps, and vice versa.
To see the baked UVs:
As you can see, the baked UVs are very different to the precomputed real-time UVs. This is because the requirements for baked and precomputed real-time UVs are different.
It is important to note that you can never get the same UVs for precomputed real-time GI as for baked GI, even if you tick Preserve UVs.
If you could, you would see heavy aliasing (such as light or dark edges) in unexpected places. This is because the resolution of real-time lightmaps is intentionally low, so that it is feasible to update them in real time. This doesn’t affect the graphical quality, because it only stores indirect lighting, which is generally low frequency (meaning it does not usually have sudden changes in intensity or detailed patterns). The direct light and shadows are rendered separately using the standard real-time lighting and shadowmaps. Direct light is generally higher frequency (meaning it is more likely to have sudden changes in intensity or detailed patterns, such as sharp edges to shadows) and therefore requires higher resolution lightmaps to capture this information.
Low resolution lightmaps can create bleeding issues, caused when charts share texels. This has a detrimental effect on the quality of the lighting, but is solved by repacking the UV charts to ensure a half-pixel boundary around them. This way you are never sampling across charts (at the most detailed mip), even with bilinear interpolation. The other benefit of charts with a guaranteed half-pixel boundary is that you can place charts right next to each other, saving lightmap space.
In summary, UVs used for precomputed Realtime Global Illumination lightmaps are always repacked.
Because repacking guarantees a half-pixel boundary around the charts, the UVs are dependent on the scale and lightmap resolution of the instance. If you scale up the UVs to get a higher resolution lightmap, you are no longer guaranteed this half-pixel boundary. The UVs are packed individually, with the scale and resolution of the instance taken into account. The real-time UVs are therefore per instance. Note that if you have 1000 objects with the same scale and resolution, they share the UVs.
2017–07–04 Page published
2017–07–04 Documentation update only, no change to Unity functionality