# Efficiently solve for coefficients of large matrix problems

Say, I have a feed of data which gives me a `[X1, X2, X3, ... Xn]`, `[Y1, Y2, Y3, ... Yn]`, and `Z` once every interval of time. I have 2 criterion for any given time: `Round(Xn*An) = Yn for all n's`, but also `Round(X1*A1 + X2*A2 + X2*A2 + ... + Xn*An) = Z`.

What's an efficient way to use code to solve for `[A1, A2, A3, ... An]` such that over time, the set `[A]` satisfies every past data sets provided by the feed? I am using python if it helps, but a sort of pseudo code would make me very happy.

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So you know all the X's and Y's and want to deduce the A's? If so, if it were not for the rounding operations, this setup appears over-specified. It looks like the `Round(Xn*An) = Yn` requirements alone would specify the A's within an accuracy of 0.5. Are you wanting the Round(<sum>)=Z requirement to determine the A's to a greater level of accuracy? –  Daniel Renshaw May 24 '12 at 12:24
Agree with @Daniel . Your input is contradict. [An] can be calculated by 1st Round(), and wont fit 2nd Round(). –  fanlix May 24 '12 at 12:30
I need high enough accuracy such that it would fulfill the every data set. 0.5 is not nearly enough. Is the 2nd equation redundant? –  user1414976 May 24 '12 at 12:34
Is there a noise term in there somewhere? I suggest writing down your precise model using mathematical notation. –  Henry Gomersall May 24 '12 at 12:48
I don't think I was correct when I said the accuracy on the A's is within 0.5 since the rounding is on the result of a product, but that constraint does impose some degree of accuracy on the A's. It appears the Y's and Z's must be integers (for the equality to a rounded value to make sense). What is the domain of the X's and A's (are they reals, integers, or something more complex)? Also, does the round function partition at a remainder of 0.5? –  Daniel Renshaw May 24 '12 at 12:51