I'm a new OpenCL programmer, just got into GPGPU computing, i'm using an Nvidia Quadro 600. I'm making a research work based on GPU programming, my aim is to write a simple Kalman Filter kernel for OpenCL using a SIMT approach. I found this document which describes the principle by how it could be done with CUDA, i think it's a similar approach for OpenCL.
The basic operations done by Kalman Filter on a linear system are three equations, each one involving matrix manipulation, which computes the Kalman Gain matrix (K), the state estimation (x~), and updates the Error Covariance matrix (P) for the next state estimation. These three steps are iterated for each measurement taken from a real system. Considering the SIMT approach, I thought to execute one iteration of the kalman filter on each gpu thread within a thread block, i send to each thread values needed to compute the iteration (input and output from the the real system measurement, linear system matrices).
There is some better design i could consider for this algorithm to be done with OpenCL? It is possible (and useful) to make matrix operations on a separate kernel with a parallel manner?
Another question: assume we have k iteration, for each iteration k we calculate P for the step k+1, taking as input the P for step k from iteration k-1... Since each tread compute one iteration, it is possible to synchronize thread k to wait the P matrix from thread k-1?
UPDATE: After many search and tries, I thought it is impossible to adapt my implementation (as described above) for this problem to the OpenCL principles of operation. The only way I found to do that is to parallelize each single matrix operation, maybe using more GPUs to compute each matrix operation simultaneously. Real efficiency for this implementation could be achieved with big linear system to filter (that means: it works good with big matrices).