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I am trying to solve equations such as the following for x:


Here the alpha's and K are given, and N will be upwards of 1,000. Is there a way to specify the LHS given an np.array for the alpha's using sympy? My hope was to define:

eqn = Eq(LHR - K)

by telling sympy that LHS= sum( a_i + x).

Any tips on solvers which would do this the fastest would also be appreciated. Thanks!

I was hoping for something like:

from sympy import Symbol, symbols, solve, summation, log
import numpy as np
alpha=np.random.randn(N, 1)
x = Symbol('x')
i = Symbol('i')
eqn = summation(log(x+alpha[i]), (i, 1, N))
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If you exponentiate both sides and simplify the left side, you end up with prod(a_i + x) = exp(K), a polynomial of degree N. What sort of answer do you expect to get? – Warren Weckesser Feb 5 '13 at 4:24
@WarrenWeckesser - They are written as base 10 logs. You'd have PROD(a_i + x) = 10 ** K. – m.brindley Feb 5 '13 at 4:37
log usually means log base e. – asmeurer Feb 5 '13 at 15:14
see edited post. – Kevin Feb 5 '13 at 15:24

You can't index a NumPy array with a SymPy symbol. Since your sum is finite, just use the Python sum function:

>>> alpha=np.random.randn(1, N)
>>> sum([log(x + i) for i in alpha[0]])
log(x - 1.85289943713841) + log(x - 1.40121781484552) + log(x - 1.21850393539695) + log(x - 0.605693136420962) + log(x - 0.575839713282035) + log(x - 0.105389419698408) + log(x + 0.415055726774043) + log(x + 0.71601559149345) + log(x + 0.866995633213984) + log(x + 1.12521825562504)

But even so, I don't get why you don't just rewrite this as (x - alpha[0])*(x - alpha[1])*...*(x - alpha[N - 1]) - exp(K), as suggested by Warren Weckesser. You can then use a numerical solver like SymPy's nsolve or something from another library to solve this numerically

>>> nsolve(Mul(*[(x - i) for i in alpha[0]]) - exp(K), 1)

You could also solve the log expression numerically, but unless your logs can have negative arguments, these should be the same.

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