# In Dymola to solve DAEs, why use the DASSL algorithm after performing the Patelides algorithm?

I am confused about the solving DAEs process in Dymola. So I made an example to explore it.
Here is the screenshot of the example scheme and control equations

Based on the following definition of variables, I think the solving DAEs process is to

1. choose the state variables
2. using an integrator to calculate the state variables according to their derivatives.
3. calculate the other variables.

I build the model in Dymola with the following debug settings.

Since the DAE's index in my model is 3, there is a need to do index reduction, after using the Pantelides Algorithm, Dymola would adding more differentiated equations to the DAE system.
The translate log verified my deduction.

Now, according to the equation browser, it is apparent the DAE system has been modified into a BLT form, I think I could just use the newton method with the current equation system, but Dymola would use the DASSL algorithm. And apparently, DASSL would do build the Structural Jacobian Matrix from scratch again, so during the initialization(using Pantelides Algorithm) and simulation(using DASSL Algorithm) processes, different Structural Jacobian Matrix would be used.

My question is:
After using Pantelides Algorithm to do index reduction and partitioning, I could solve the equations with Newton Method, but why does Dymola have to do partitioning again and use DASSL Algorithm?

In addition, I compared the Structural Jacobian Matrix in initialization and simulation process in Wolfram System Modeler, which showed these two matrices are different.

• Does setting `Advance.Define.DAEsolver=true;` change anything? Commented Feb 9, 2021 at 19:18
• @Priyanka. The question is not about a specific example, I am wondering why I have to use DASSL after performing Pantelides Algorithm and getting a Solvable BLT form of the DAE system. I think there is no need to do the partitioning again and use DASSL, I could calculate the derivatives of state variables directly and do integration of state variables, update the state variables then go to the next time instant.
– Jack
Commented Feb 9, 2021 at 19:37

I think there are actually two things that are important to understand the overall process:

1. The system of equations is different for initialization and for simulation. The reason is e.g. found in the Modelica Language Specification 3.4 in Section 8.6:

During this phase, also the derivatives, `der(..)`, and the pre-variables, `pre(..)`, are interpreted as unknown algebraic variables. The initialization uses all equations and algorithms that are utilized in the intended operation...

Basically, a different set of unknowns (and respective equations) results in two separated problems to solve for initialization and during simulation. As far as I know symbolic processing (incl. Pantelides algorithm) is applied to simplify both problems. As an example: Translating `Modelica.Blocks.Examples.PID_Controller` results in the following translation log, which separates the two aspects (Note: the "Translated Model" and the "Initialization problem" being different):

1. After a consistent solution for the initial problem is found (e.g. using a Newton Method), the actual integration starts. What DASSL does after the initialization is finished, is the same as every other solver for dynamic simulation: Computing the state vector for the next simulation step, using information from the current step and the derivatives computed by the model equations (and in case of DASSL and some others, future values as DASSL uses a BDF algorithm which is implicit, see e.g. here).

One thing that is special about DASSL, though not unique, is that DASSL has two interfaces which can be used during simulation: It can work with an ODE description of the system (after it has been transformed e.g. by the symbolic pre-processing of Dymola) or it can use a DAE description (by setting `Advance.Define.DAEsolver=true;`). By default, the ODE interface is used. Both have advantages, the Dymola Manual states:

When DAE solver is enabled the equations in the output and dynamics section of the model are not solved during calls to the model. They are instead handled by the integrator as part of the nonlinear system of equations that the integrator solves each step. If the translated model contains several or large nonlinear equation systems, then DAE solvers may be more efficient since fewer nonlinear systems are solved.

After using Pantelides Algorithm to do index reduction and partitioning, I could solve the equations with Newton Method, but why does Dymola have to do partitioning again and use DASSL Algorithm?

The simple answer is: it doesn't have to do either additional partitioning or use DASSL. You can just click a few buttons and change the algorithm to cvode, Runge-Kutta, Euler, etc. I'm a bit unsure, but I don't think Dymola does any additional partitioning for DASSL in ODE mode (I know for sure that OpenModelica's DASSL algorithm does not - although it's a little silly using a DAE solver to solve an ODE system). If you run the simulation in DAE mode, you can perhaps even skip index reduction (depending on the index of the system).

What the integration method (e.g. dassl) does is actually solve the system time step by time step. What Pantelides algorithm does is index reduction (in Modelica tools usually to ODE form, which is what most of the integration methods require).

• So why the equation blocks during initialization and simulation are different in Wolfram SystemModeler? But Dymola only provide one set of equation block for visualization, which seems to be used both in initialization and simulation. What about it in OpenModelica?
– Jack
Commented Feb 10, 2021 at 7:24
• My confuse is actually whether the initialization and simulation processes use the same structural Jacobian matrix or they use different matrices?
– Jack
Commented Feb 10, 2021 at 7:28
• Dymola might visualize only one of them, but it will have two different partitions in most cases. For initialization itself, you do not need a Jacobian since there are no states. The nonlinear systems tend to be bigger (and might have their own Jacobian matrixes that are of course different from the continuous-time system). OpenModelica does not have a graphical visualization of the blocks, but it has multiple partitions for the regular equation system if there are independent (decoupled) parts. And you can inspect each partition (initial, homotopy, regular, and parameter systems). Commented Feb 10, 2021 at 13:25
• could you tell me where to find the option or manual about this function of `you can inspect each partition` in openmodlica?
– Jack
Commented Feb 10, 2021 at 13:50
• In OMEdit, you can open the transformational debugger. It has all the information available. But it's all in one big chunk of information and not visualized very well. Commented Feb 10, 2021 at 14:20