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Check Static Range

Check that signal falls inside fixed range of amplitudes

  • Check Static Range block

Libraries:
Simulink / Model Verification
HDL Coder / Model Verification

Description

The Check Static Range block checks that each element of the input signal falls inside the same range of amplitudes at each time step. The Upper bound and Lower bound parameters define the upper and lower bounds of the range. The block then executes an assertion after comparison. If the signal falls inside the bounds, the assertion is true (1) and the block does nothing. If not, the block halts the simulation and returns an error message by default.

The input signal and bounds can be scalars, vectors, or matrices. All three must be the same data type. The block compares the value of the input to the bounds differently depending on the signal.

  • When comparing scalars to vectors or matrices, the block compares the scalar to each element of the non-scalar input signal or bounds.

  • When comparing vectors or matrix signals to other vectors or matrices, the block compares the input signal to the bounds element-by-element.

  • For models with more than one vector or matrix input signal or bounds, the vectors or matrices must have the same dimensions.

Examples

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Using the Check Static Range block, you can check if an input signal falls outside of an unchanging range of values.

In this example, the Check Static Range block compares the value of a Sine Wave block to the values entered in the Upper bound and Lower bound parameters, which are 0.5 and -0.5. The Constant blocks, labeled Upper Bound and Lower Bound, illustrate these parameters in the Scope block but do not affect the parameter values. The Check Static Range block checks if the value of the input signal is greater than the Lower bound value or less than the Upper bound value. If it is, the block asserts true (1). Because the Output assertion signal parameter of the block is selected, the block outputs the assertion value. Run the simulation to observe the model output.

At the start of the simulation, the Check Static Range block outputs 1 because the value of the Sine Wave block is less than the Upper bound value. At a time of 0.52, the sine wave exceeds 0.5. The Check Static Range block recognizes this change and outputs 0. When the time reaches 2.62, the sine wave falls below the Upper bound value and the assertion is true. When the time reaches 3.67, the sine wave falls below the Lower bound value. The Check Static Range block recognizes this change and outputs 0. The output stays at 0 until the time is 5.76, when the sine wave then exceeds the Lower bound value. This pattern repeats until the simulation end time.

Ports

Input

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Input signal checked against the range specified by the Upper bound and Lower bound parameters.

Data Types: half | single | double | int8 | int16 | int32 | int64 | uint8 | uint16 | uint32 | uint64 | Boolean | fixed point | enumerated

Output

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Output signal that is true (1) if the assertion succeeds, and false (0) if the assertion fails. If, in the Configuration Parameters window, in the Math and Data Types section, under Advanced parameters, you select Implement logic signals as Boolean data, then the output data type is Boolean. Otherwise, the data type of the signal is double.

Dependencies

To enable this output port, set the Output assertion signal parameter check box.

Data Types: double | Boolean

Parameters

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Specify the upper bound on the range of amplitudes that the input signal can have.

Programmatic Use

Parameter: max
Type: string scalar or character vector
Default: "100"

Select this check box to make the range of valid input amplitudes include the upper bound.

Programmatic Use

Parameter: min_included
Type: string scalar or character vector
Values: "on" | "off"
Default: "on"

Specify the lower bound on the range of amplitudes that the input signal can have.

Programmatic Use

Parameter: min
Type: string scalar or character vector
Default: "0"

Select this check box to make the range of valid input amplitudes include the lower bound.

Programmatic Use

Parameter: min_included
Type: string scalar or character vector
Values: "on" | "off"
Default: "on"

Clearing this parameter disables the block and causes the model to behave as if the block does not exist. To enable or disable all verification blocks, regardless of the setting of this option, go to the Configuration Parameters window, click Diagnostics > Data Validity, expand the Advanced parameters section, and set Model Verification block enabling to Enable all or Disable all.

Programmatic Use

Parameter: enabled
Type: string scalar or character vector
Values: "on" | "off"
Default: "on"

Specify a MATLAB® expression to evaluate when the assertion fails. Because the expression is evaluated in the MATLAB workspace, define all variables used in the expression in that workspace.

Dependencies

To enable this parameter, select Enable assertion.

Programmatic Use

Parameter: callback
Type: string scalar or character vector
Default: ""

Select this parameter to stop the simulation when the check fails. Clear this parameter to display a warning and continue the simulation.

Programmatic Use

Parameter: stopWhenAssertionFail
Type: string scalar or character vector
Values: "on" | "off"
Default: "on"

Select this parameter to enable the output port.

Programmatic Use

Parameter: export
Type: string scalar or character vector
Values: "on" | "off"
Default: "off"

Specify the style of the block icon. The graphic option displays a graphical representation of the assertion condition on the icon. The text option displays a mathematical expression that represents the assertion condition.

Programmatic Use

Parameter: icon
Type: string scalar or character vector
Values: "graphic" | "text"
Default: "graphic"

Block Characteristics

Data Types

Boolean | double | enumerated | fixed point | half | integer | single

Direct Feedthrough

no

Multidimensional Signals

yes

Variable-Size Signals

no

Zero-Crossing Detection

no

Extended Capabilities

PLC Code Generation
Generate Structured Text code using Simulink® PLC Coder™.

Fixed-Point Conversion
Design and simulate fixed-point systems using Fixed-Point Designer™.

Version History

Introduced before R2006a