Проверено с версией:: 5.1


Сложность: Базовая

Reflection Source

By default, objects in a scene are rendered using Unity’s ‘Standard Shader’. The Standard Shader is a 'physically based shader' (PBS). This attempts to accurately represent the behavior of light on materials by mimicking physical properties such as reflectivity and the principles of ‘energy conservation’ which exist in the real world.

When using the Standard Shader, every material has a degree of reflectivity based on its ‘specularity’, or ‘metalness’. Without hardware powerful enough to ray trace reflections in realtime we have to rely on pre-rendering reflections. We do this with a cubemap - a 6-sided image of the world derived either from the sky, or from a ‘Reflection Probe’ which renders the environment from a specific point in space, writing the results to a texture. This is then blended with other lighting and surface data by a material’s shader in order to approximate the effects of reflectivity, like we see in the real world.

Reflection Source By default, highly Specular/Metal materials in your scene will reflect the Skybox, defined by the Reflection Source property of the Environment Lighting Panel. This behaviour can be changed by choosing a different source, or by adding a Reflection Probe to your scene.

By default, objects in a Unity scene will reflect the Skybox. However, this behaviour can be changed globally in the Lighting window using the ‘Reflection Source’ property. The Skybox, or alternatively, a custom cubemap may be used. This ‘Reflection Source’ can be thought of as a scene-wide cubemap used by all objects in the scene, unless overridden - by adding a Reflection Probe.

Reflection Probes

Often it is undesirable for objects to simply reflect the Skybox in a Unity scene. In many instances, objects may be blocked or ‘occluded’ from the sky. They may be indoors or underneath an architectural feature like a bridge or tunnel . To create more accurate reflections we need to sample what objects ‘see’ using a ‘Reflection Probe’. These probes render the world from their position in 3D space and write the results to a cubemap. This can then be used by nearby objects to give the impression that they are reflecting the world around them.

A reflection probe can be added via (GameObject>Light>Reflection Probe).

The position of a Reflection Probe will determine what the generated cubemap looks like, and therefore what is ‘seen’ in the reflections. Generally, for performance reasons it is better to use as few probes as possible. Remember, reflection probes are not meant to give physically accurate results, but instead give the impression of reflections in the game world. A few well placed probes throughout your scene will be sufficient in most cases.

Reflection Probes Left: Our scene with default reflections. Right: With a Reflection Probe added.

In the Inspector panel for a Reflection Probe we can set the ‘Type’ property of the probe to choose between ‘Baked’, ‘Custom’ or ‘Realtime’. It should be noted that Realtime Reflection Probes are extremely detrimental to performance as we are effectively rendering the scene an additional 6 times for each probe. There are specific cases where a realtime reflection probe is required and this expense is justified, but as a general rule, Baked Reflection Probes are preferable as they are considerably more performant.

Note that GameObjects are only visible to Baked Reflection Probes if marked as ‘Reflection Probe Static’ from the ‘Static’ drop-down at the top of the Inspector panel. Conversely, ‘Realtime’ probes render all visible GameObjects in the world unless a culling mask is applied.

Unity For Artists

  1. Lighting Overview
  2. Lights
  3. Materials
  4. The Standard Shader
  5. Textures
  6. Using Skyboxes
  7. A Gentle Introduction to Shaders
  8. Using detail textures for extra realism close-up
  9. Frame Debugger
  1. Introduction to Lighting and Rendering
  2. Choosing a Lighting Technique
  3. The Precompute Process
  4. Choosing a Rendering Path
  5. Choosing a Color Space
  6. High Dynamic Range (HDR)
  7. Reflections
  8. Ambient Lighting
  9. Light Types
  10. Emissive Materials
  11. Light Probes
  1. Introduction to Precomputed Realtime GI
  2. Realtime Resolution
  3. Understanding Charts
  4. Starting the precompute process
  5. Probe lighting
  6. Unwrapping and Chart reduction
  7. Optimizing Unity's auto unwrapping
  8. Understanding Clusters
  9. Fine tuning with Lightmap Parameters
  10. Summary - Precomputed Realtime GI
  1. The Particle System
  2. Adding Lighting To Particles
  3. Adding Movement To Particles With Noise
  4. Fun with Explosions!
  5. Cinematic Explosions - PIT
  1. Intro to Timeline and Cinemachine Tutorial (including Dolly Track)
  2. Intro to Timeline [ by Brackeys ]
  3. Intro to Cinemachine [ by Brackeys ]
  4. Cinemachine Clear Shot Camera Tutorial
  5. Using Timeline: Getting Started
  6. Using Timeline: Understanding Tracks
  7. Using Timeline: Working with Animation Clips
  1. Materials
  2. Emissive Materials
  3. How to remove lighting from Photogrammetry with the De-lighting tool
  1. Introduction to Art & Design Essentials
  2. Uber Standard Shader Real Time Snow Effect
  3. Building Levels With Octave3D
  4. Volumetric Fog with Fog Volume 3
  5. Questions and Answers for Art & Design Essentials
  1. Overview and Goals
  2. Best Practices
  3. Mesh Normal Calculation
  4. DCC Tool Light Import
  5. DCC Tool Camera Import
  6. Importing Visibility Animation
  7. Animation Keyframing Improvements
  8. Stingray PBS Materials
  9. FBX Material Embedding
  10. Questions and Answers