I'm tackling an interesting machine learning problem and would love to hear if anyone knows a good algorithm to deal with the following:

- The algorithm must learn to approximate a function of
**N inputs**and**M outputs** - N is quite large, e.g.
**1,000-10,000** - M is quite small, e.g.
**5-10** - All inputs and outputs are
**floating point values**, could be positive or negative, likely to be relatively small in absolute value but no absolute guarantees on bounds - Each time period I get N inputs and need to predict the M outputs, at the end of the time period the actual values for the M outputs are provided (i.e. this is a
**supervised learning**situation where learning needs to take place**online**) - The underlying function is
**non-linear**, but not too nasty (e.g. I expect it will be smooth and continuous over most of the input space) - There will be a
**small amount of noise**in the function, but signal/noise is likely to be good - I expect the N inputs will expain 95%+ of the output values - The underlying function is
**slowly changing over time**- unlikely to change drastically in a single time period but is likely to shift slightly over the 1000s of time periods range - There is
**no hidden state to worry about**(other than the changing function), i.e. all the information required is in the N inputs

I'm currently thinking some kind of back-propagation neural network with lots of hidden nodes might work - but is that really the best approach for this situation and will it handle the changing function?