EDIT:

@auxsvr is correct that I had the force equations wrong, and about the -3/2 exponent.

Another way to see this it to simply to 2 dimensions and consider a force acting from the origin, proportional to 1/r^2 just like gravity, where r is the distance from the origin.

At (x,y), the force acts in the direction (-x,-y). However, that's just the direction, not the magnitude. If we use k as the constant of proportionality, the force is (-kx, -ky).

The magnitude of the force is thus Sqrt[(-kx)^2+(-ky)^2], or k*Sqrt[x^2+y^2], or k*Sqrt[r^2] or k*r

Since the force magnitude is also 1/r^2, this gives us k= 1/r^3.

The force is thus (-x/r^3, -y/r^3).

Since I was initially using r^2 as my primary quantity, that's (r^2)^(-3/2), which is where the 3/2 comes from.

This effectively invalidates my question, although it still makes an interesting theoretical discussion.

I retried this Mathematica with the correct equations, but still got no answer. As other points out, the result is only an ellipse under certain conditions (could be a parabola or hyperbola in other cases).

Additionally, although the eventual orbit is a conic section, the initial orbit may spiral in or out until the final conic section orbit is achieved.

EDIT ENDS HERE

I'm using Mathematica to solve the two-body problem:

```
DSolve[{
d2[t] == (x1[t]-x0[t])^2 + (y1[t]-y0[t])^2 + (z1[t]-z0[t])^2,
D[x0[t], t,t] == (x1[t]-x0[t])/d2[t],
D[y0[t], t,t] == (y1[t]-y0[t])/d2[t],
D[z0[t], t,t] == (z1[t]-z0[t])/d2[t],
D[x1[t], t,t] == -(x1[t]-x0[t])/d2[t],
D[y1[t], t,t] == -(y1[t]-y0[t])/d2[t],
D[z1[t], t,t] == -(z1[t]-z0[t])/d2[t]
},
{x0,y0,z0,x1,y1,x1,d2},
t
]
```

But I get back:

There are fewer dependent variables than equations, so the system is overdetermined.

I count 7 equations and 7 dependent variables?

In fact, the system is semi-undetermined, since I don't provide positions and velocities at time 0.

I realize my equations themselves might be wrong for the two-body problem, but I'd still like to know why Mathematica complains about this.