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In NumPy, I'm trying to represent differential equations of the form: y' = p(t)y + g(t), where p(t) is an nxn matrix and and g(t) is an nx1 matrix. Something like:

y' = [[1,5], [2,1]] + [[e^t], [1]]

I know how to represent matrices in NumPy, but how would I represent matrices that contain variables (for example, 2t or e^t)?

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up vote 1 down vote accepted

A 'variable' in this sense (as in, y is a function of t) should probably be represented by a 1d array of that variable's domain. This would increase the dimension of your array (making it (n, n, m) where m is the size of your domain (length of t).

If you plan on using a scipy ode solver, then you write it as a function, so instead of

t = np.arange(0, 10, .1)
y' = [[1,5]*len(t), [2,1]*len(t)] + [[np.exp(t)], [1]*len(t)]

you need to do something like:

def yderiv(t):
    return [[1,5], [2,1]] + [[np.exp(t)], [1]]
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I'm not sure if e^t does what you expect it to. Did you mean something like np.exp(t)? – Hooked Apr 30 '13 at 15:58
@Hooked yeah. The matrix can contain variables. – darksky Apr 30 '13 at 15:58
Thanks @Hooked, you're probably right. I just copied from above. – askewchan Apr 30 '13 at 16:01
@askewchan yes I do mean that. I'm trying to solve ODEs on my own without SciPy using NumPy. Maybe use SciPy integration but I need solve the actual ODE alone and not using a library. To use a 1d array of that variable's domain, would it be like: `g = [2t, 1, 2], where the last element 2 is the size? I'm afraid I don't get it. – darksky Apr 30 '13 at 16:01
numpy.poly1d represents a polynomial. A matrix [[np.exp(t)], [1]] is not a polynomial, however. np.exp(t) throws an error when used alone since t is not defined. – darksky Apr 30 '13 at 16:11

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