1

Following some example I found online, I can do this:

from sympy import var
from sympy import solve

Ldy, Ldz = var('Ldy Ldz')
g, x, y, z = var('g x y z')
xZ, yZ, zZ = var('xZ yZ zZ')
xdd, ydd, zdd = var('xdd ydd zdd')

E1 = z * xdd + (xZ - x) * (g + zdd)
E2 = z * ydd + (yZ - y) * (g + zdd) - Ldy
E3 = -y * xdd + x * ydd - zZ * (g + zdd) + Ldz

out = solve([E1, E2, E3], [xdd, ydd, Ldy])

print(type(xdd))
print("xdd = ", (out[xdd]).factor())

Which yields xdd = (g + zdd)*(x - xZ)/z.

Now, doing it for my own equations:

from sympy import symbols, solve

x, y, z, k12, k26, x0 = symbols("x, y, z, k12, k26, x0")
symbols = x, y, z, k12, k26, x0

eq1 = k12 * x**2 -y
eq2 = k26 * y**3 - z
eq3 = x * 2*y + 6*z - x0

out = solve([eq1, eq2, eq3], [x,y,z])
print("x = ", (out[x]).factor())

Gives instead TypeError: list indices must be integers or slices, not Symbol.

What am I doing wrong?

0

The issue is that solve has multiple return types: sometimes it returns a list, sometimes a dict, sometimes a list of dicts. The output form depends on the particulars of the equations being solved: number of variables, number of solutions. This mean one should use either list=True or dict=True to force consistent output from solve. Note that dict=True means the output is a list of dicts, since multiple solutions may exist -- which is the case here. In your example:

out = solve([eq1, eq2, eq3], [x,y,z], dict=True)
for sol in out:
    print("x = ", sol[x].factor())

prints

x =  18**(1/3)*((3*x0 - sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(sqrt(6*k12*k26*x0 + 1) + 1)/(18*k12*x0)
x =  -18**(1/3)*((3*x0 + sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(sqrt(6*k12*k26*x0 + 1) - 1)/(18*k12*x0)
x =  -2**(1/3)*((3*x0 - sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(3**(2/3) - 3*3**(1/6)*I)*(sqrt(6*k12*k26*x0 +1) + 1)/(36*k12*x0)
x =  -2**(1/3)*((3*x0 - sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(3**(2/3) + 3*3**(1/6)*I)*(sqrt(6*k12*k26*x0 +1) + 1)/(36*k12*x0)
x =  2**(1/3)*((3*x0 + sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(3**(2/3) - 3*3**(1/6)*I)*(sqrt(6*k12*k26*x0 + 1) - 1)/(36*k12*x0)
x =  2**(1/3)*((3*x0 + sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(3**(2/3) + 3*3**(1/6)*I)*(sqrt(6*k12*k26*x0 + 1) - 1)/(36*k12*x0)

For this and other reasons, SymPy developers recommend using solveset and its relatives instead of solve. Specifically, nonlinsolve can be used here:

out = nonlinsolve([eq1, eq2, eq3], [x,y,z])
for sol in out:
    print("x = ", sol[x].factor())

which prints

x =  -18**(1/3)*((3*x0 + sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(sqrt(6*k12*k26*x0 + 1) - 1)/(18*k12*x0)
x =  18**(1/3)*((3*x0 - sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(sqrt(6*k12*k26*x0 + 1) + 1)/(18*k12*x0)
x =  2**(1/3)*((3*x0 + sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(3**(2/3) - 3*3**(1/6)*I)*(sqrt(6*k12*k26*x0 + 1) - 1)/(36*k12*x0)
x =  2**(1/3)*((3*x0 + sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(3**(2/3) + 3*3**(1/6)*I)*(sqrt(6*k12*k26*x0 + 1) - 1)/(36*k12*x0)
x =  -2**(1/3)*((3*x0 - sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(3**(2/3) + 3*3**(1/6)*I)*(sqrt(6*k12*k26*x0 +1) + 1)/(36*k12*x0)
x =  -2**(1/3)*((3*x0 - sqrt(6*k12*k26*x0 + 1)/(k12*k26) + 1/(k12*k26))/k26)**(2/3)*(3**(2/3) - 3*3**(1/6)*I)*(sqrt(6*k12*k26*x0 +1) + 1)/(36*k12*x0)

The return type of solveset and its relatives is always a SymPy set.

  • Also mentioned here: stackoverflow.com/questions/49469047/…, that nonlinsolve gives wrong solutions for not-so-obvious reasons. – komodovaran_ Sep 27 '18 at 13:46
  • I didn't notice there were six solutions here. Both solve and nonlinsolve find the same solutions, they just don't present them in the same order. – user6655984 Sep 28 '18 at 1:03

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.