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Adding the Transitions

Build It Yourself or Use the Supplied Model

To add the transitions yourself, work through the exercises in this section. Otherwise, open the supplied model to see how the transitions should appear in the chart. Enter this command at the MATLAB® prompt:

addpath(fullfile(docroot, 'toolbox', 'stateflow', 'gs', 'examples'))
Stage4Transitions

Design Considerations for Defining Transitions Between States

The following sections describe the decisions you make for defining state transitions.

Deciding How and When to Transition Between Operating Modes

Transitions create paths for the logic flow of a system from one state to another. When a transition is taken from state A to state B, state A becomes inactive and state B becomes active.

Transitions have direction and are represented in a Stateflow® chart by lines with arrowheads. Transitions are unidirectional, not bidirectional. You must add a transition for each direction of flow between two states.

Exclusive (OR) states require transitions. Recall that no two exclusive states can be active at the same time. Therefore, you need to add transitions to specify when and where control flows from one exclusive state to another.

Typically, parallel (AND) states do not require transitions because they execute concurrently.

The Air Controller chart models a system in which power can cycle on and off and, while power is on, fans can cycle on and off. Six exclusive (OR) states represent these operating modes. To model this activity, you need to add the following transitions between exclusive (OR) states:

  • PowerOff to PowerOn

  • PowerOn to PowerOff

  • FAN1.Off to FAN1.On

  • FAN1.On to FAN1.Off

  • FAN2.Off to FAN2.On

  • FAN2.On to FAN2.Off

Deciding Where to Place Default Transitions

Good design practice requires that you specify default transitions for exclusive (OR) states at each level of hierarchy. Default transitions indicate which exclusive (OR) state is to be active when there is ambiguity between two or more exclusive (OR) states at the same level in the Stateflow hierarchy. There are three such areas of ambiguity in the Air Controller chart:

  • When the chart wakes up, should power be on or off?

  • When FAN1 becomes active, should it be on or off?

  • When FAN2 becomes active, should it be on or off?

In each case, the initial state should be off so you will add default transitions to the states PowerOff, FAN1.Off, and FAN2.Off.

Deciding How to Guard the Transitions

Guarding a transition means specifying a condition, action, or event that allows the transition to be taken from one state to another. Based on the design of the Air Controller chart, here are the requirements for guarding the transitions from one exclusive operating mode to another:

TransitionWhen Should It Occur?How to Guard It

PowerOff to PowerOn

At regular time intervals

Specify an edge-triggered event

PowerOn to PowerOff

FAN1.Off to FAN1.On

When the temperature of the physical plant rises above 120 degrees

Specify a condition based on temperature value

FAN1.On to FAN1.Off

When the temperature of the physical plant falls below 120 degrees

FAN2.Off to FAN2.On

When the temperature rises above 150 degrees, a threshold indicating that first fan is not providing the required amount of cooling

FAN2.On to FAN2.Off

When the temperature falls below 150 degrees

Drawing the Transitions Between States

In Design Considerations for Defining Transitions Between States, you learned that the following transitions occur in the Air Controller chart:

  • Power for the control system can cycle on and off.

  • Each fan can cycle on and off.

You will model this activity by drawing transitions between the PowerOn and PowerOff states and between the On and Off states for each fan. Follow these steps:

  1. Open the model Stage3Actions — either the one you created in the previous exercises or the supplied model for stage 3.

    To open the supplied model, enter the following command at the MATLAB prompt:

    addpath(fullfile(docroot, 'toolbox', 'stateflow', 'gs', 'examples'))
    Stage3Actions
  2. Save the model as Stage4Transitions in your local work folder.

  3. In Stage4Transitions, double-click the Air Controller block to open the Stateflow chart.

    The chart opens on your desktop.

  4. Draw transitions between the PowerOff to PowerOn states:

    1. Move your pointer over the top edge of PowerOff until the pointer shape changes to crosshairs.

    2. Hold down the left mouse button, drag your pointer to the bottom edge of PowerOn, and release the mouse.

      You should see a transition pointing from PowerOff to PowerOn:

    3. Follow the same procedure to draw a transition from PowerOn to PowerOff.

      Your chart should now look like this:

  5. Follow the procedure described in step 3 to draw the following transitions between the Off and On states for each fan:

    • Transition from Off to On in FAN1

    • Transition from On to Off in FAN1

    • Transition from Off to On in FAN2

    • Transition from On to Off in FAN2

    Your chart should now look like this:

  6. Save Stage4Transitions, but leave the chart open for the next exercise.

Adding Default Transitions

In Deciding Where to Place Default Transitions, you learned that you need to add default transitions to PowerOff, FAN1.Off, and FAN2.Off. Follow these steps:

  1. In the Stateflow Editor, left-click the default transition icon in the object palette:

  2. Move your pointer into the drawing area.

    The pointer changes to a diagonal arrow.

  3. Place your pointer at the left edge of the PowerOff state.

  4. When the arrow becomes orthogonal to the edge, release the mouse button.

    The default transition attaches to the PowerOff state. It appears as a directed line with an arrow at its head and a closed tail:

  5. Repeat the same procedure to add default transitions at the top edges of FAN1.Off and FAN2.Off.

    Your chart should now look like this:

      Tip   The location of the tail of a default transition determines the state it activates. Therefore, make sure that your default transition fits completely inside the parent of the state that it activates. In the Air Controller chart pictured above, notice that the default transition for FAN1.Off correctly resides inside the parent state, FAN1. Now consider this chart:

      In this example, the tail of the default transition resides in PowerOn, not in FAN1. Therefore, it will activate FAN1 instead of FAN1.Off.

  6. Save Stage4Transitions, but leave the chart open for the next exercise.

Adding Conditions to Guard Transitions

Conditions are expressions enclosed in square brackets that evaluate to true or false. When the condition is true, the transition is taken to the destination state; when the condition is false, the transition is not taken and the state of origin remains active.

As you learned in Deciding How to Guard the Transitions, the fans cycle on and off depending on the air temperature. In this exercise, you will add conditions to the transitions in FAN1 and FAN2 that model this behavior.

Follow these steps:

  1. Click the transition from FAN1.Off to FAN1.On.

    The transition appears highlighted and displays a question mark (?).

  2. Click next to the question mark to display a blinking text cursor.

  3. Type the following expression:

    [temp >= 120]

    You may need to reposition the condition for readability. Click outside the condition, then left-click and drag the condition expression to a new location.

  4. Repeat these steps to add the following conditions to the other transitions in FAN1 and FAN2:

    TransitionCondition
    FAN1.On to FAN1.Off[temp < 120]
    FAN2.Off to FAN2.On[temp >= 150]
    FAN2.On to FAN2.Off[temp < 150]

    Your chart should look like this:

  5. Save Stage4Transitions, but leave the chart open for the next exercise.

Adding Events to Guard Transitions

Events are nongraphical objects that trigger activities during the execution of a Stateflow chart. Depending on where and how you define events, they can trigger a transition to occur, an action to be executed, and state status to be evaluated. In this exercise, you will define an event that triggers transitions.

As you learned in Deciding How to Guard the Transitions, the control system should power on and off at regular intervals. You model this behavior by first defining an event that occurs at the rising or falling edge of an input signal, and then associating that event with the transitions between the PowerOn and PowerOff states.

Follow these steps to define an edge-triggered event and associate it with the transitions:

  1. In the Stateflow Editor, add an input event by selecting Chart > Add Inputs & Outputs > Event Input From Simulink.

    The Event properties dialog box opens on your desktop:

    Note that the event is assigned to trigger port 1.

  2. Edit the following properties:

    PropertyWhat to Specify
    NameChange the name to SWITCH.
    TriggerSelect Either from the drop-down menu so the event can be triggered by either the rising edge or falling edge of a signal.

  3. Click OK to record the changes and close the dialog box.

  4. Look back at the model and notice that a trigger port appears at the top of the Stateflow block:

    When you define one or more input events for a chart, Stateflow software adds a single trigger port to the block. External Simulink® blocks can trigger the input events via a signal or vector of signals connected to the trigger port.

  5. Back in the Stateflow Editor, associate the input event SWITCH with the transitions:

    1. Select the transition from PowerOff to PowerOn and click the question mark to get a text cursor.

    2. Type the name of the event you just defined, SWITCH.

      You might need to reposition the event text for readability. If so, click outside the text string, left-click the text, and drag it to the desired location.

    3. Repeat these steps to add the same event, SWITCH, to the transition from PowerOn to PowerOff.

    Your chart should now look something like this:

    Now that you have associated these transitions with the event SWITCH, the control system will alternately power on and off every time SWITCH occurs — that is, every time the chart detects a rising or falling signal edge.

    Note that the sf_aircontrol model has already defined the pulse signal SWITCH in the Signal Builder block at the top level of the model hierarchy:

    In the next phase of the workflow, you will connect your Stateflow chart to the SWITCH signal to trigger the transitions between power on and power off.

  6. Save Stage4Transitions.

Where to go next.  Now you are ready to implement an edge-triggered event to wake up the chart at regular intervals. See Implementing the Triggers.

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