Specify attributes of signal
This class enables you to create workspace objects that you can use to assign or validate the attributes of a signal or discrete state, such as its data type, numeric type, dimensions, and so on. You can use a signal object to:
Assign values to signal attributes that are left unassigned (have a value of -1 or auto) by the signal source.
Validate signal attributes whose values are explicitly assigned by the signal source. Such attributes have values other than -1 or auto. Successful validation guarantees that the signal has the attributes that you intended it to have.
You can create a Simulink.Signal object in the MATLAB® workspace or in a model workspace.
Use signal objects to assign or validate signal or discrete state attributes by giving the signal or discrete state the same name as the workspace variable that references the Simulink.Signal object.
You can use a Signal Specification block rather than a Simulink.Signal object to assign properties left unspecified by a signal source. Each technique has advantages and disadvantages:
Using a signal object simplifies the model and allows you to change signal property values without editing the model, but does not show signal property values directly in the block diagram.
Using a Signal Specification block displays signal property values directly in the block diagram, but complicates the model and requires editing it to change signal property values.
You can use a Signal Specification block with virtual and nonvirtual buses; you can use only nonvirtual buses with a Simulink.Signal object.
The following two models illustrate the respective advantages of the two ways of assigning attributes to a signal.
In the first example, the signal object named Sig1 specifies the sample time and data type of the signal emitted by input port In1.
To determine the properties of the Sig1 signal, you can view the signal object in the Model Explorer. In this model, the sample time is -1 and the data type is auto.
Using a signal object to specify the sample time and data type properties of signal Sig1 allows you to change the sample time or data type without having to edit the model. For example, you could use the Model Explorer, the MATLAB command line, or a MATLAB program to change these properties.
The second example uses a Signal Specification block specifies the sample time and data type of the signal emitted by input port In2. The Signal Specification block displays the data type and signal sample time properties right in the diagram, which in this case are uint8 and 4, respectively.
This section describes how you can use signal objects to assign or validate signal attributes. The same techniques work with discrete states also. To use a signal object to assign or validate signal attribute values:
Create a Simulink.Signal object that has the same name as the signal to which you want to assign attributes or whose attributes you want to validate.
Open the Model Explorer.
In the Model Hierarchy pane, select either the Base workspace or Model workspace node, depending on the context you want for the signal object. If you create the signal object in a model workspace, you must set the Storage class parameter to Auto.
Select Add > Simulink Signal.
Set the properties of the object that correspond to the attributes left unspecified by the signal source, or that correspond to the attributes you want to validate. See Property Dialog Box for details.
Enable explicit or implicit signal resolution:
Explicit resolution: In the Signal Properties dialog box for the signal, enable Signal name must resolve to Simulink signal object. This is the preferred technique. See Explicit and Implicit Symbol Resolution for more information.
Implicit resolution: Set the Configuration Parameters > Diagnostics > Data Validity > Signal resolution option for the model to Explicit and implicit or Explicit and warn implicit. Explicit resolution is the preferred technique.
Assign the signal object to a workspace variable.
Associate the signal object with the source signal.
Give the signal the same name as the workspace variable that references the signal object.
You can use a variety of techniques to associate a signal object with a signal. For examples, see Using Signal Objects to Initialize Signals and Discrete States, Using Signal Objects to Tune Initial Values, and Apply Custom Storage Classes.
The result when a signal does not match a signal object can depend on several factors. Simulink® software can validate a signal property when you update the diagram, while you run a simulation, or both. When and how validation occurs can depend on internal rules that are subject to change, and sometimes on configuration parameter settings.
Not all signal validation compares signal source attributes with signal object properties. For example, if you specify Minimum and Maximum signal values using a signal object, the signal source must specify the same values as the signal object (or inherit the values from the object) but such validation relates only to agreement between the source and the object, not to enforcement of the minimum and maximum values during simulation.
If the value of Configuration Parameters > Diagnostics > Data Validity > Simulation range checking is none (the default), Simulink does not enforce any minimum and maximum signal values during simulation, even though a signal object provided or validated them. To enforce minimum and maximum signal values during simulation, set Simulation range checking to warning or error. See Signal Ranges and Diagnostics Pane: Data Validity for more information.
You can associate a given signal object with more than one signal if the storage class of the signal object is Auto. If the storage class of the object is other than Auto, you can associate the signal object with no more than one signal.
You can associate a given signal with no more than one signal object. The signal can refer to the signal object more than once, but every reference must resolve to exactly the same signal object. Referencing two different signal objects that have exactly the same properties causes a compile-time error.
A compile-time error occurs if a model associates more than one signal object with any signal. To prevent the error, decide which object you want the signal to use, then delete or reconfigure all references to any other signal objects, so that all remaining references resolve to the chosen signal object. See Display Signal Sources and Destinations for a description of techniques that you can use to trace the full extent of a signal.
Data type of the signal. The default entry, auto, specifies that Simulink should determine the data type. Use the adjacent pulldown list to specify built-in data types (for example, uint8). To specify a custom data type, enter a MATLAB expression that specifies the type, (for example, a base workspace variable that references a Simulink.NumericType object).
To specify a bus object as the data type for the signal object, use the Bus: <object_name> option. See Bus Support for details about what you need to do if you specify a bus object as the data type.
Click the Show data type assistant button to display the Data Type Assistant, which helps you set the Data type parameter. (See Specify Data Types Using Data Type Assistant.)
Numeric type of the signal. Valid values are auto (determined by Simulink), real, or complex.
Dimensions of this signal. Valid values are -1 (the default) specifying any dimensions, N specifying a vector signal of size N, or [M N] specifying an MxN matrix signal.
Dimensions mode of this signal. From the drop-down list, select
Auto — Allows variable-size and fixed-size signals.
Fixed — Allows only fixed-size signals. Does not allow variable-size signals.
Variable — Allows only variable-size signals.
Rate at which the value of this signal should be computed. See Specify Sample Time for details.
Sample mode of this signal. Simulink ignores the setting of this field.
Minimum value that the signal should have. The default value is  (unspecified). Specify a finite, real, double, scalar value.
Note: If you specify a bus object as the data type for a signal, do not set the minimum value for bus data on the signal property dialog box. Simulink ignores this setting. Instead, set the minimum values for bus elements of the bus object specified as the data type. For information on the Minimum property of a bus element, see Simulink.BusElement.
Simulink uses this value in the following ways:
When updating the diagram or starting a simulation, Simulink generates an error if the signal's initial value is less than the minimum value or if the minimum value is outside the range for the data type of the signal.
When you enable the Simulation range checking diagnostic, Simulink alerts you during simulation if the signal value is less than the minimum value (see Simulation range checking).
Maximum value that the signal should have. The default value is  (unspecified). Specify a finite, real, double, scalar value.
Note: If you specify a bus object as the data type for a signal, do not set the maximum value for bus data on the signal property dialog box. Simulink ignores this setting. Instead, set the maximum values for bus elements of the bus object specified as the data type. For information on the Maximum property of a bus element, see Simulink.BusElement.
Simulink uses this value in the following ways:
When updating the diagram or starting a simulation, Simulink generates an error if the initial value of the signal is greater than the maximum value or if the maximum value is outside the range of the data type of the signal.
When you enable the Simulation range checking diagnostic, Simulink alerts you during simulation if the signal value is greater than the maximum value (see Simulation range checking).
Signal or state value before a simulation takes its first time step. You can specify any MATLAB string expression that evaluates to a double numeric scalar value or array.
1.5 [1 2 3] 1+0.5 foo = 1.5; s1.InitialValue = 'foo';
uint(1) foo = '1.5'; s1.InitialValue = 'foo';
If you use a bus object as the data type for the signal object, set Initial value to a string containing either 0 or a MATLAB structure that matches the bus object. See Bus Support for details.
If the initial value evaluates to a MATLAB structure, then in the Configuration Parameters > Diagnostics > Data Validity pane, set Underspecified initialization detection to simplified.
If necessary, Simulink converts the initial value to ensure type, complexity, and dimension consistency with the corresponding block parameter value. If you specify an invalid value or expression, an error message appears when you update the model. Also, Simulink performs range checking of the initial value. The software alerts you when the initial value of the signal lies outside a range that corresponds to its specified minimum and maximum values and data type.
Classic initialization mode: In this mode, initial value settings for signal objects that represent the following signals and states override the corresponding block parameter initial values if undefined (specified as ):
Output signals of conditionally executed subsystems and Merge blocks
Simplified initialization mode: In this mode, initial values of signal objects associated with the following blocks are ignored. The initial values of the corresponding blocks are used instead.
Outport blocks of conditionally executed subsystems
Measurement units in which the value of this signal is expressed, (for example, inches). You can use this parameter to document this signal. Simulink ignores it during simulation.
Storage class of this signal. For more information, see Simulink Package Custom Storage Classes.
If you create the signal object in a model workspace, you must set the object storage class to Auto.
Alternate name for this signal. Simulink ignores this setting. This property is used for code generation.
Data alignment boundary, specified in number of bytes. The starting memory address for the data allocated for the signal will be a multiple of the Alignment setting. The default value is -1, which specifies that the code generator should determine an optimal alignment based on usage. Otherwise, specify a positive integer that is a power of 2, not exceeding 128. This field is intended for use by Simulink Coder™ software. See Data Alignment for Code Replacement. Simulink software ignores this setting.
Description of this signal. This field is intended for use in documenting this signal. This property is used by the Simulink Report Generator and for code generation.
Simulink.Signal supports nonvirtual buses as the output data type.
If you set the Data type of the signal object to be a bus object, then you cannot associate the signal object with a non-bus signal.
If you use a bus object as the data type, set Initial value to 0 or a MATLAB structure that matches the bus object.
The structure you specify must contain a value for every element of the bus represented by the bus object.
You can use the Simulink.Bus.createMATLABStruct to create a full structure that corresponds to a bus.
You can use Simulink.Bus.createObject to create a bus object from a MATLAB structure.
To enable the use of a bus object as the signal object data type, before you start a simulation, in the Configuration Parameters > Diagnostics > Connectivity pane, set Mux blocks used to create bus signals to error. The documentation for that diagnostic explains how convert your model to handle error messages the diagnostic generates.
Information used by Simulink Coder for generating code for this signal. The value of this property is an object of Simulink.SignalCoderInfo class.
Description of this signal. This field is intended for use in documenting this signal. (Description)
String specifying the data type of this signal. (Data type)
Minimum value that this signal can have. (Minimum)
Maximum value that this signal can have. (Maximum)
Measurement units used for expressing this signal value. (Units)
Scalar or vector specifying the dimensions of this signal. (Dimensions)
String specifying the numeric type of this signal. Valid values are 'auto', 'real', or 'complex'. (Complexity)
Rate at which this signal should be updated. (Sample time)
Sampling mode of this signal. (Sample mode)
Signal or state value before a simulation takes its first time step. (Initial Value)