# 11.7. High-level interface: Basic example¶

Consider the following linear MPC problem with lower and upper bounds on state and inputs, and a terminal cost term:

This problem is parametric in the initial state \(\color{red} x\) and the first input \(u_0\) is typically applied to the system after a solution has been obtained.

You can download the Matlab code of this example to try it out for yourself by
clicking `here`

.

## 11.7.1. Defining the problem data¶

Let’s define the known data of the MPC problem, i.e. the system matrices \(A\) and \(B\), the prediction horizon \(N\), the stage cost matrices \(Q\) and \(R\), the terminal cost matrix \(P\), and the state and input bounds:

```
%% system
A = [1.1 1; 0 1];
B = [1; 0.5];
[nx,nu] = size(B);
%% MPC setup
N = 10;
Q = eye(nx);
R = eye(nu);
if( exist('dlqr','file') )
[~,P] = dlqr(A,B,Q,R);
else
P = 10*Q;
end
umin = -0.5; umax = 0.5;
xmin = [-5, -5]; xmax = [5, 5];
```

## 11.7.2. Defining the MPC problem¶

Let’s now dive in right into the problem formulation:

```
%% FORCES multistage form
% assume variable ordering zi = [ui; xi] for i=1...N
% dimensions
model.N = 11; % horizon length
model.nvar = 3; % number of variables
model.neq = 2; % number of equality constraints
% objective
model.objective = @(z) z(1)*R*z(1) + [z(2);z(3)]'*Q*[z(2);z(3)];
model.objectiveN = @(z) z(1)*R*z(1) + [z(2);z(3)]'*P*[z(2);z(3)];
% equalities
model.eq = @(z) [ A(1,:)*[z(2);z(3)] + B(1)*z(1);
A(2,:)*[z(2);z(3)] + B(2)*z(1)];
model.E = [zeros(2,1), eye(2)];
% initial state
model.xinitidx = 2:3;
% inequalities
model.lb = [ umin, xmin ];
model.ub = [ umax, xmax ];
```

## 11.7.3. Generating a solver¶

We have now populated `model`

with the necessary fields to generate a solver
for our problem. Now we use the function `FORCES_NLP`

to generate a solver for
the problem defined by `model`

with the first state as a parameter:

```
%% Generate FORCES solver
% get options
codeoptions = getOptions('FORCESNLPsolver');
codeoptions.printlevel = 2;
% generate code
FORCES_NLP(model, codeoptions);
```

## 11.7.4. Calling the generated solver¶

Once all parameters have been populated, the MEX interface of the solver can be used to invoke it:

```
problem.x0 = zeros(model.N*model.nvar,1);
problem.xinit = xinit;
[solverout,exitflag,info] = FORCESNLPsolver(problem);
```

Tip

Type `help solvername`

to get more information about how to call the solver.

## 11.7.5. Simulation¶

Let’s now simulate the closed loop over the prediction horizon \(N\):

```
%% simulate
x1 = [-4; 2];
kmax = 30;
X = zeros(2,kmax+1); X(:,1) = x1;
U = zeros(1,kmax);
problem.x0 = zeros(model.N*model.nvar,1);
for k = 1:kmax
problem.xinit = X(:,k);
[solverout,exitflag,info] = FORCESNLPsolver(problem);
if( exitflag == 1 )
U(:,k) = solverout.x01(1);
solvetime(k) = info.solvetime;
iters(k) = info.it;
else
error('Some problem in solver');
end
%X(:,k+1) = A*X(:,k) + B*U(:,k);
X(:,k+1) = model.eq( [U(:,k);X(:,k)] )';
end
```

## 11.7.6. Results¶

The results of the simulation are presented in Figure 11.14. The plot on the top shows the system’s states over time, while the plot on the bottom shows the input commands. We can see that all constraints are respected.