I have performed block SVD decomposition over image and I stored results. Now, I need to make reconstruction from this results. I found few examples all written in Matlab, which is a mystery for me. I only need formula from which I can reconstruct my picture, or example written in C language. Matrix A is equal U*S*V'. How will look formula, e.g. for calculating first five singular values (product of which rows and columns)? Please provide formula with indexes in C like style. U and V' are matrices and S is vector (not matrix).
Not sure if I get your question right, but if you just need to know singular values, they are the diagonal values of the middle matrix S. S in general is a diagonal matrix, which is stored here as a vector. I mean, only the diagonal is stored, you should imagine it as a matrix if you're thinking in matrix calculations. Those diagonal values are your singular values, if you need the first biggest singular values, just take the 5 biggest values of the vector S. Quoting from Wikipedia:
In the above quote, sigma is your S, and M is the original matrix. 


You have asked for C code, yet my hope is that pseudocode will suffice (it's late, I'm tired). The target matrix A has m rows, c columns and rank rho. The variable p = min(m,n). One strategy is to first form the the intermediate matrix product B = US. This is trivial due to the diagonallike nature of the matrix of singular values. Assume you have rho ( = 5 ) singular values. You must enforce rho <= p. Replace column vector u_{1} with s_{1}u_{1}. Replace column vector u_{2} with s_{2}u_{2}. ... Replace column vector u_{rho} with s_{rho}u_{rho}. Replace column vector u_{rho+1} with a zero vector of length m. Replace column vector u_{rho+2} with a zero vector of length m. ... Replace column vector u_{p} with a zero vector of length m. Next form the new image matrix A = BV^{T}. The matrix element in row r and column c is the dot product of the rth row vector (length rho) of B with the cth column vector (length rho) of V^{T}. Another strategy is to jump to the form where the matrix elements of A in row r and column c are a_{r,c} = sum ( s_{k}u_{r,k}v_{c,k}, { k, 1, rho } ) The row counter r runs from 1 to m; the column counter c runs from 1 to n. 

