This page provides details on the Renderer settings in V-Ray for Revit.


Page Contents



The Renderer tab provides convenient access to common Rendering functions such as choosing the render devices or sampler. You are also able to choose from several Quality presets of the Geometry Tessellation, the GI primary and secondary engine and adjust the Interactive renderer's settings, as well as choose the auto-save file path for your renders.  



Engine  Switches between CPU and GPU rendering engine. GPU enabled unlocks the menu on the right, where you can select which CUDA device(s) to perform the raytracing calculations or combine them for Hybrid Rendering. The Computer CPU is also listed as "C++/CPU" in the CUDA device list.

Sampler – Selects the image sampler type. For more information on how the Sampler works, see the Sampler page. 

Progressive  This is the default image sampler set in V-Ray for Revit. It renders the entire image progressively in passes.

Bucket – This sampler takes a variable number of samples per pixel based on the difference in intensity between the pixel and its neighbors.

Global Illumination

Global Illumination allows for selecting a primary and secondary GI engine.

There are several ways to combine primary and secondary GI engines in V-Ray for Revit.

1. Brute Force + Brute Force – very accurate but slow
2. Brute Force + Light Cache – accurate 
3. Irradiance Map + Light Cache - very fast
4. Irradiance Map + Brute Force - fast 

GI Depth – Specifies the number of light bounces that will be computed. GI Depth will also be used to calculate Interactive rendering GI Depth.

For more information on Global Illumination, see the Indirect Illumination Reference page. 

Interactive Settings

Trace Depth – Represents the maximum number of bounces that will be computed for reflections and refractions. The individual material reflection/refraction depth settings are still considered, as long as they don't exceed the value specified here.

Ray Bundle Size – Controls the number of rays that are sent to the V-Ray Interactive render servers for processing. When using distributed rendering, the smaller sizes cause more frequent client/server communication with smaller network packets, thus decreasing the speed of the renderer but increasing the interactivity. Note that this number is not the exact amount of rays, but is proportional to it. It is not recommended to increase this value beyond 512.

Rays Per Pixel – The number of rays that are traced for each pixel during one image pass. The greater the value, the smoother the picture from the very beginning of the rendering with GI, but interactivity may be significantly diminished. Increasing this value also reduces the amount of data transferred from the render servers back to client machine.

Undersampling – When set to a value greater than 0, during interactive updates, the image is rendered initially at a lower resolution in order to speed up the preview of the updates. Once you stop updating the model, the image is rendered at its final resolution The optimal value for Undersampling is the default one. 


Adaptive Lights  Optimizes the sampling of lights in scenes with many lights. 

Bucket Size – Determines the maximum bucket width in pixels when the Sampler is set to Buckets. 

Geometry Tessellation



This affects the tessellation of the geometry in each of the quality presets ranging from 0-15. Higher values result in geometry from Revit having more polygons. Lower values decrease render times but result in round geometry appearing to be more jagged in appearance. Values at and close to zero create odd situations such as round columns appearing to only have 4 or so sides.



When Auto-Save is Enabled V-Ray will save automatically completed renderings to a specified location. 



All selected render elements will also be saved.


File Path – Browse for a folder where completed renderings will be saved.

File Type – Select the file format of the auto-saved images.


Image Options


Alpha – Determines how the Alpha channel will be handled. This option is available for the following formats: .png, .tga, .sgi, .exr, .pic, and .tif. 

No Alpha – No Alpha channel will be saved. The background will be visible even if the output image format supports transparency. 
Include Alpha – The Alpha channel will be saved as image Alpha or Transparency depending on the file format. 
Separate Alpha 
– The Alpha channel will be saved as a separate file.

Compression Level – Specifies the image compression level for the .png file type.

Bits per Channel – Specifies the amount of data per channel for the .png, .sgi, .exr, and .tif file types. The following options are possible depending on the file type:

8 bits
16 bits



Hybrid Rendering with CPUs and the CUDA Engine

Starting in 3.60, V-Ray GPU can perform hybrid rendering with the CUDA engine utilizing both the CPU and NVIDIA GPUs. V-Ray can now execute the CUDA source on the CPU, as though the CPU was another CUDA device. To enable the hybrid rendering mode, simply enable the C++/CPU device from the list of CUDA devices.

The hybrid rendering mode does not require any special drivers. Furthermore, you can use the CPU as a CUDA device even if you don't have an NVIDIA GPU and/or NVIDIA drivers installed. Meaning, this mode can be used on computers that don't even have GPUs. The hybrid render engine running on a CPU supports the same features as the regular V-Ray GPU CUDA engine. 

Interactive GPU OpenCL rendering mode is currently not supported.

 When rendering an unsupported feature with V-Ray GPU, a warning note appears on the Messages and Warnings rollout of the Progress window.