The prediction time depends on number of support vector, but I want to do prediction faster.
How can I set number of support vectors in libsvm to const value?
Maybe I can find N support vectors and then reduce it to K (K< N) by some approximation?
The prediction time depends on number of support vector, but I want to do prediction faster. How can I set number of support vectors in libsvm to const value? Maybe I can find N support vectors and then reduce it to K (K< N) by some approximation? 


As stated in other answers, the easier way to control the number of support vectors is by playing with C and kernel parameters. However, there are a few interesting papers on that topic: Building Support Vector Machines with Reduced Classifier Complexity PDF An Eﬃcient Method for Simplifying Support Vector Machines PDF A Study on Reduced Support Vector Machines PDF And unfortunately I couldn't find a public source for this one: An Algorithm for Reducing the Number of Support Vectors (http://link.springer.com/chapter/10.1007%2F1402034326_12?LI=true#page1) 


Number of support vectors depends on training data and parameters c, and chosen kernel parameters (e.g. gaussian has Gamma). As far as I know there is no explicit way how to define number of support vectors. Just a clue: maybe some extreme values like c=0 would make some extreme number of support vectors  but supposedly it is not what you are looking for ... Likely, better approach would be to find parameters setting that would give you number of support vectors you need and results are still reasonable. 


Depending on the kernel you use, you would have to do an exhaustive grid search for the C and Gamma parameters (see grid.py) and optimize the number of support vectors. There are no guarantees that the grid of values from grid.py will yield the best values for your particular problem, but it's a good place to start. Be warned, minimizing the number of SVs does not maximize accuracy. PS: you'll need to write a custom script for this task, since this functionality is not built in AFAIK. 

