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?