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Is it possible to use stochastic gradient descent for time-series analysis?

My initial idea, given a series of (t, v) pairs where I want an SGD regressor to predict the v associated with t+1, would be to convert the date/time into an integer value, and train the regressor on this list using the hinge loss function. Is this feasible?

Edit: This is example code using the SGD implementation in scikit-learn. However, it fails to properly predict a simple linear time series model. All it seems to do is calculate the average of the training Y-values, and use that as its prediction of the test Y-values. Is SGD just unsuitable for time-series-analysis or am I formulating this incorrectly?

from datetime import date
from sklearn.linear_model import SGDRegressor

# Build data.
s = date(2010,1,1)
i = 0
training = []
for _ in xrange(12):
    i += 1
    training.append([[date(2012,1,i).toordinal()], i])
testing = []
for _ in xrange(12):
    i += 1
    testing.append([[date(2012,1,i).toordinal()], i])

clf = SGDRegressor(loss='huber')

print 'Training...'
for _ in xrange(20):
    try:
        print _
        clf.partial_fit(X=[X for X,_ in training], y=[y for _,y in training])
    except ValueError:
        break

print 'Testing...'
for X,y in testing:
    p = clf.predict(X)
    print y,p,abs(p-y)
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You should look at the LMS algorithm. It is an adaptive Wiener Filter that can be used for prediction or for any other task. LMS is based on stochastic gradient descent. There are many other variants too like NLMS, Leaky LMS, Sign LMS.

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Well, this is not really a programming question. But, anyways...

The method of choice for time series prediction depends on what you know about your time series. If you choose a specific method for your task you always make implicit assumptions about the nature of your signal and the kind of system that generated the signal. Any method is always a model of the system. The more you know a priori about your signal and the system the better you are able to model it.

If your signal for instance is of stochastic nature, usually ARMA processes or Kalman filters are a good choice. If those fail, other more deterministic models might help, given, of corse, you have some information about you system.

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