Guy on Simulink

Simulink & Model-Based Design

Continuous Time Integrator

One of the ways I think of Simulink is as a graphical interface to the solvers.  Moreover, when I think of the solvers, I usually think of the continuous time solvers and the integrator block.  In this post, I will show you some of the capabilities of the continuous time integrator that you might not know about.  I will also demonstrate how I keep track of the ports on the integrator block.

The Continuous State

The continuous time Integrator block is the building block for ODEs/continuous time systems.  Labeing the input and output of the Integrator block keeps my signals organized when drawing ODEs.

The Integrator block

Labeling the signals is also beneficial when adding reset, initial condition, saturation, and state ports to the block.

External Reset

The External reset signal (second inport) triggers the integrator state to reset to the initial condition value.  External reset can be set to rising, falling, either edge, level or level hold.

Integrator block with rising edge reset

The internal initial condition is not always the right value at the time the state resets.  Often, the new state value comes from a calculation in the model via the IC port.

External Initial Condition

Set the Initial condition source as external to provide the IC value via signal.

Integrator block with external initial condition

This state (x) is set to this signal value when the reset signal triggers.  To provide an initial condition at time Tstart, add an IC block (from the Signal Attributes library) inline with the signal that calculates the IC.

Limit Output (state saturation)

The Limit output check box enables the Upper saturation limit and Lower saturation limit parameters.  This also adds the saturation icon to the block.  Note, it is easy to mistake this as an integral signal, however, this actually indicates that the state has an upper and/or lower limit.

Integrator block with limited output

Saturation Port

Check the Show saturation port parameter to add a second output, the saturation port.  The signal from this port is 0 when the value of the state is within the limits, and 1 when the value of the state is at the limit.  This transition from 0 to 1 and 1 to 0 can be used as rising and falling edges triggers.

Integrator block with staturation port

State port

Clicking Show state port adds a special port on the top of the block.  The state port provides a way to model self-resetting integrators and performing state hand off between enabled subsystems without creating algebraic loops.

Integrator with state port

Bouncing Ball Demo

The bouncing ball demo combines some of these integrator block capabilities.

Simulink bouncing ball model

Click on this image for a web view of the sldemo_bounce model.

Note the use of the IC block to provide an Initial Velocity and Initial Position for the bouncing ball.  The IC block feeds through its input when T≠Tstart.  This allows the ball to reset the velocity state (V) to -0.8 * V when the position of the ball hits zero.  This use of the state port prevents the algebraic loop connecting the velocity state to the initial state value and reset signals.  Here are the simulation results.

Bouncing ball demo scope

Now it’s your turn

I got into the habit of labeling the ports on the integrator while I was a trainer teaching Simulink.  It was always helpful in keeping the model organized.  Have you used these features of the Integrator block?  What did your model do?  Leave me a comment here.

|
  • print

コメント

コメントを残すには、ここ をクリックして MathWorks アカウントにサインインするか新しい MathWorks アカウントを作成します。