This is one of the V-Ray's techniques for calculating motion blur. Instead of taking a number of time samples, the analytic method blurs the moving triangles perfectly. It will take in consideration all triangles crossing a given ray during a given time interval. Keep in mind that because of its "perfection" this method will be extremely slow on high-poly scenes with fast motion. (See also: Motion blur, Motion blur parameters, Quasi Monte Carlo sampling)
Antialiasing (Image sampling)
Antialiasing is a special technique for producing smooth images of high-contrast edges and small details in materials and objects. V-Ray achieves antialiasing by taking additional image samples where necessary. To determine if more samples are needed, V-Ray compares differences in color (and/or other properties) of neighboring image samples.. This comparison can be performed in several ways. V-Ray supports fixed, simple 2 level and adaptive antialiasing (See also: Image samplers, G-Buffer, G-Buffer Antialiasing)
Area light is a term describing a non-point light source. These types of light sources produce area shadows. V-Ray supports rendering of area lights through VRayLight. (See also: VRayLight, Area shadows)
Area Shadows (Soft shadows)
Area shadows are blurred shadows (or shadows with blurred edges) that are caused by non-point light sources (Area lights). V-Ray is capable of producing the effect of area shadows either through VRayShadow or through area lights. (See also: Area lights)
BRDF (Bi-Directional Reflectance Distribution Function)
One of the most general means to characterize the reflection properties of a surface is by use of the bi-directional reflection distribution function (BRDF), a function which defines the spectral and spatial reflection characteristic of a surface. V-Ray supports the following BRDF types: Phong, Blinn, Ward. (See also: VRayMtl)
BSP (BSP Tree, Binary Space Partitioning Tree)
BSP is special data structure for organizing scene geometry in order to speed up ray-triangle intersections (intersecting a ray with the triangles in the scene is the task most frequently performed by a raytracer). Currently V-Ray implements two types of BSP Tree. These are a static BSP Tree for scenes without motion blur and a motion blur BSP Tree. (See also: Motion Blur)
Bucket (Region, Rendering region)
A bucket is a rectangular part of the current frame that is rendered independently from other buckets. The division of a frame into rendering regions allows for optimal resource utilization (CPUs, PCs, memory). It also allows for distributed rendering. (See also: Distributed rendering)
This is the effect of light refracted by a non-opaque object hitting a (diffuse) surface. (See also: Caustics)
Depth of field (DOF)
Depth of field is the effect of having a particular point in the scene to appear focused (sharp) and the rest to out of focus (blurry) depending on camera shutter properties and the distance from the camera. This is similar to how real world cameras work so this effect is especially useful for producing photorealistic images. (See also: DOF, Camera)
Distributed rendering (DR)
Distributed rendering is a technique for utilization of all available computational resources (all CPUs in a machine, all machines in a LAN, etc.). DR divides the currently processed frame into rendering regions and keeps all CPUs in LAN-connected machines busy computing the rendering result. Overall DR assures that V-Ray makes the most out of your equipment when rendering a single frame. For animation sequences however, you should use MAX's standard network rendering as it may be more efficient. (See also: Bucket, Distributed rendering)
Early termination is a technique for reducing the samples taken for evaluating a blurry value. This basically works by looking at the samples as they are computed one by one and deciding, after each new sample, if more samples are required. Early termination is used throughout V-Ray for all blurry values. (See also: importance sampling.)
This term describes the collection of various data generated during image rendering. These could be Z-values, material IDs, object IDs, non-clamped colors etc. This has proven to be very useful for performing post-rendering image processing. (See also: Antialiasing, Image sampler)
V-Ray is capable of antialiasing the rendered image based on the differences in one or several G-Buffer channels. (See also: Antialiasing, Image sampler, G-Buffer)
HDRI (High Dynamic Range Image)
A High Dynamic Range Image is an image containing high-dynamic range colors (with components exceeding the range 0.0-1.0, or 0-255). This type of images is often used as an environment map to light the scene with natural light.
Importance sampling is a technique for basing the number of samples required for evaluating a blurry value, on the effect that value has on the final result. For example, dark materials require fewer samples for evaluating GI than bright materials; dim area lights can do with less samples than bright lights etc. Importance sampling is used throughout V-Ray for all blurry values. (See also: early termination)
Index of Refraction (IOR)
The index of refraction is defined as the speed of light in vacuum divided by the speed of light in a given medium. IOR = C/V, where V is the light speed specific for the different mediums. To achieve a material with a specific IOR you have to set the Index of refraction field value in MAX's standard materials in the section Extended parameters.
|Air at STP||1.00029|
|Water at 20 C||1.33|
|Sugar solution (80%)||1.49|
|Typical crown glass||1.52|
|Spectacle crown, C-1||1.523|
|Heavy flint glass||1.65|
|Extra dense flint, EDF-3||1.7200|
|Heaviest flint glass||1.89|
Indirect Illumination (Global lighting, Global Illumination)
In real world when a particle ray of light hits an object it produces multiple reflected rays with different intensity in all directions. These rays on their turn may hit some other objects and produce even more rays and so on. This process, multiply repeated, generates the so called Global Illumination. (See also: Indirect Illumination, Irradiance map)
Indirect Illumination in V-Ray is generally achieved by calculating GI samples. The irradiance map is a special cache where V-Ray keeps precalculated GI samples. During the rendering process when V-Ray needs a particular GI sample it computes it by interpolating the nearest precalculated GI samples stored in the irradiance map. Once computed, the Irradiance map can be saved in a file and reused in subsequent renderings. This can be especially useful for camera fly-through animations. Samples for VRayLight can also be stored in the irradiance map. (See also: Indirect Illumination parameters, Indirect Illumination, Area lights, Area shadows)
Low accuracy computations
In certain cases V-Ray will not need to compute absolutely precisely a ray contribution to the final image. V-Ray will then use faster but less precise methods for computation and will take fewer samples. This produces slightly noisier results, but decreases rendering times. Users can control the degree of optimization by changing when V-Ray switches to Low accuracy computations by changing Degrade depth values. (See also: Degrade depth, Low subdivs)
(Quasi) Monte Carlo sampling
Monte Carlo sampling is a method for numerical computation of integrals of functions by evaluating these functions at a number of random points. Quasi Monte Carlo sampling is a modification of this method, which instead of randomly generated points uses points forming a low-discrepancy sequence, which are more evenly distributed than purely random ones. This is the method used by V-Ray to evaluate complex things like global illumination, blurry reflections, depth of field, motion blur and image antialiasing.
This effect is observed when looking at some fast-moving object. The motion is so fast that one can not focus the object and the object's image appears blurred to the viewer. (See also: Motion Blur, Analytic sampling, Monte Carlo sampling)
Photon, Photon map
This is a simulation of a real world photons (a photon is a light particle). In order to produce caustics effects V-Ray traces certain amount of photons that come out of the light sources. Then the results are stored in a photon map and used during the rendering process so that highly realistic caustic effects are produced.
As an advanced raytracer V-Ray supports accurate reflections. Glossy reflections are as well supported (See also: VRayMap, VRayMtl, Glossiness)
Refraction is the bending of a wave when it enters a medium where it's speed is different. The refraction of light when it passes from a fast medium to a slow medium bends the light ray toward the normal to the boundary between the two media. As an advanced raytracer V-Ray supports true accurate refractions. V-Ray also handles glossy refractions (See also: VRayMap, VRayMtl, IOR, Translucency, Glossiness, Reflections)
This is a technique for reducing variance (i.e. noise) by eliminating computationally intensive paths with little or no contribution to the final picture, without introducing bias.
In V-Ray subdivs is a measure for the maximum amount of samples (rays) that V-Ray will use to compute a certain value. The maximum number of samples is proportional to the square of the subdivs value. For example, if the subdivs value of a glossy reflection is 5, V-Ray will never make more than 5 x 5 = 25 samples to evaluate the reflection.
Translucency is a term describing the interaction of light with a non-opaque medium (wax, marble, skin etc.). V-Ray supports a simple translucency model that can nevertheless produce quite natural results. (See also: VRayMap, VRayMtl, Refractions)