I am trying to solve an Inverse Kinematics (IK) task as an optimisation problem using Python and SciPy. There exists a robot arm in a 2D environment, and I want to reach for a specific target in the Cartesian space. I have formulated my problem using the trust-region constrained method and it works. However, I would like to compare it with SLSQP.

When using SLSQP, I formulate the problem with a constant objective function (e.g., 1), and the reaching task as an equality constraint (where the constraint function corresponds to the Forward Kinematics (FK) of the current robot joint positions).

This formulation leads to the following error:

Singular matrix C in LSQ subproblem    (Exit mode 6)
            Current function value: 0.0
            Iterations: 1
            Function evaluations: 6
            Gradient evaluations: 1

After putting considerable effort searching online for this problem, I have found less than a handful of people having similar problems [4] [5] [6]. And unfortunately, all the threads I have found on Stack Overflow or GitHub have very poor discussions and no conclusive answers.

At first, I thought that maybe this was due to my Jacobian not being square:

>>> print(J)
[[-2.51189432 -1.81188199 -0.83828558]
 [ 0.39717558 -0.31695518 -0.5452314 ]]

But then I checked the documentation and tutorial for using SLSQP and, as you can see, the example's equality constraint also has a non-square Jacobian, and it does not produce this Singular matrix C in LSQ subproblem error.

Furthermore, I have investigated formulating the equality constraint as two inequality constraints, and this actually worked. However, I must be doing something fundamentally wrong, and of course using an equality would most likely be the proper way of formulating the problem.

So, I guess my question really boils down to:
- What does this error really mean?
- What am I doing wrong?
- At which point in the problem formulation may I be introducing it?

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