## Optimize Live Editor Task with `fmincon`

Solver

This example shows how to use the solver-based **Optimize** Live Editor task with the
`fmincon`

solver to minimize a quadratic subject to linear
and nonlinear constraints and bounds.

Consider the problem of finding [*x*_{1},
*x*_{2}] that solves

$$\underset{x}{\mathrm{min}}f(x)={x}_{1}^{2}+{x}_{2}^{2}$$

subject to the constraints

$$\begin{array}{rr}\hfill 0.5\le {x}_{1}& \hfill \text{(bound)}\\ \hfill -{x}_{1}-{x}_{2}+1\le 0& \hfill \text{(linearinequality)}\\ \hfill \begin{array}{r}\hfill -{x}_{1}^{2}-{x}_{2}^{2}+1\le 0\\ \hfill -9{x}_{1}^{2}-{x}_{2}^{2}+9\le 0\\ \hfill \text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}-{x}_{1}^{2}+{x}_{2}\le 0\\ \hfill \text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{\hspace{0.17em}}-{x}_{2}^{2}+{x}_{1}\le 0\end{array}\}& \hfill \text{(nonlinearinequality)}\end{array}$$

The starting point `x0`

for this problem is
*x*_{1} = 3 and
*x*_{2} = 1.

### Start Optimize Live Editor Task

Create a new live Script by clicking the **New Live Script**
button in the **File** section on the **Home**
tab.

Insert an **Optimize** Live Editor task. Click the
**Insert** tab and then, in the **Code**
section, select **Task > Optimize**.

For this example, choose the solver-based task.

For later use in entering problem data, select **Insert > Section
Break**. New sections appear above and below the task.

### Enter Problem Data

Starting from the top of the task, enter the problem type and constraint types. Click the

**Objective > Quadratic**button and the**Constraints > Lower bounds**,**Linear inequality**, and**Nonlinear**buttons. The task shows that the recommended solver is`fmincon`

.**Objective Function**The objective function is simple enough to represent as an anonymous function. Position the cursor in the section above the task and enter this code.

fun = @(x)sum(x.^2);

**Lower Bound**The problem contains the lower bound

*x*_{1}≥ 0.5. Express this bound as a variable`lb`

. With the cursor at the end of the line defining the objective function, press**Enter**, and enter the following code to specify the lower bound.lb = [0.5 -Inf];

**Initial Point**With the cursor at the end of the line defining the lower bound, press

**Enter**, and enter the following code to set the initial point.x0 = [3,1];

**Linear Constraint**With the cursor at the end of the line defining the initial point, press

**Enter**, and enter the following code to set the linear constraint.A = [-1,-1]; b = -1;

**Run Section**The top section now includes five parameters.

Next, you need to run the section to place the parameters in the workspace as variables. To do so, click the left-most area of the section, which contains a bar of diagonal stripes. After you click this area, the bar becomes a solid bar, indicating the variables are now in the workspace. (Note: You can also press

**Ctrl+Enter**to run the section.)**Set Problem Data**Enter the variables in the

**Select problem data**section of the task. To specify the objective function, select**Objective function > Function handle**and choose**fun**.Set the initial point

**x0**.Select

**Lower bounds > From workspace**and select**lb**.Set the linear inequality constraint variables

`A`

and`b`

in the**Linear inequality**area.Now specify the nonlinear inequality constraints. In the

**Select problem data**section, select**Nonlinear > Local function**, and then click the**New**button. The function appears in a new section below the task. Edit the resulting code to contain the following uncommented lines.function [c,ceq] = constraintFcn(x) % You can include commented code lines or not. % Be sure that just these uncommented lines remain: c = [-x(1)^2 - x(2)^2 + 1; -9*x(1)^2 - x(2)^2 + 9; -x(1)^2 + x(2); -x(2)^2 + x(1)]; ceq = []; end

In the

**Select problem data**section, select the**constraintFcn**function.**Monitor Progress**In the

**Display progress**section of the task, select**Text display > Each iteration**so you can monitor the solver progress. Select**Objective value**for the plot.Your setup looks like this:

### Run Solver and Examine Results

To run the solver, click the options button **⁝** at the top
right of the task window, and select **Run Section**.

The plot appears in a separate figure window and in the task output area.

To see where the solution variables are returned, look at the top of the task.

The final point and its associated objective function value appear in the
`solution`

and `objectiveValue`

variables in
the workspace. View these values by entering this code in the live editor section
below the task.

solution, objectiveValue

Press **Ctrl+Enter** to run the section.