Discrete Filter (Simulation Module)
Computes an Infinite Impulse Response (IIR) filter or Finite Impulse Response (FIR) filter with forward and backward coefficients. The Numerator and Denominator parameters define these coefficients. Details Example
| Dialog Box Options |
| Block Diagram Inputs |
| Block Diagram Outputs |
Dialog Box Options
| Parameter | Description |
|---|---|
| Polymorphic instance | Specifies whether this function is single-input single-output (SISO) or multiple-input multiple-output (MIMO). The default value is SISO. |
| Execution Mode | Configures the function to be either a Direct or Indirect feedthrough function. Enable this control by selecting a parameter from the Parameters list and then selecting Terminal from the Parameter source pull-down list. If you select Configuration Dialog Box from the Parameter source pull-down list, LabVIEW disables this control and calculates the feedthrough behavior automatically.
Refer to the Details section for a description of the parameters that determine the feedthrough behavior of this function. |
| Parameters | Lists all the parameters associated with this function. Select a parameter from this list to configure the parameter. When you select a parameter, the parameter and its associated Parameter source control appear in the Parameter Information section of the configuration dialog box. |
| Preview | Displays a graphical preview, if available, of the function output or configuration. |
| Parameter Information | Contains the parameters you can configure for this function. You must select a parameter from the Parameters list to make that parameter and its associated Parameter source control visible in the Parameter Information section of the configuration dialog box. |
| Parameter source | Specifies whether you configure this parameter using the Configuration Dialog Box or a Terminal on the simulation diagram. The default value is Configuration Dialog Box. If you select Terminal, LabVIEW displays an input for that parameter on the simulation diagram, and you can wire values to that input to configure this function programmatically. If you select Configuration Dialog Box, LabVIEW removes that input from the simulation diagram. You then must set the value for this parameter inside the configuration dialog box. |
| sample period (sec) | Specifies the length of the discrete time step, in seconds, of this function. If you enter a value of –1, this function inherits the discrete time step you specify for the simulation diagram. Otherwise, the value of sample period (sec) must be a multiple of the discrete time step you specify for the simulation diagram. The default value of sample period (sec) is 1. |
| sample skew (sec) | Specifies the length of time by which you want to delay the execution of this function. The default value is 0. The value of this parameter must satisfy the following relationship:
0 ≤ sample skew (sec) ≤ sample period (sec) |
| Filter | Specifies the filter in terms of numerator and denominator polynomial functions.
|
Block Diagram Inputs
| Parameter | Description |
|---|---|
| sample period (sec) | Specifies the length of the discrete time step, in seconds, of this function. If you enter a value of –1, this function inherits the discrete time step you specify for the simulation diagram. Otherwise, the value of sample period (sec) must be a multiple of the discrete time step you specify for the simulation diagram. The default value of sample period (sec) is 1. |
| sample skew (sec) | Specifies the length of time by which you want to delay the execution of this function. The default value is 0. The value of this parameter must satisfy the following relationship:
0 ≤ sample skew (sec) ≤ sample period (sec) |
| Filter | Specifies the filter in terms of numerator and denominator polynomial functions.
|
| input | Specifies the input to this function. |
Block Diagram Outputs
| Parameter | Description |
|---|---|
| output | Returns the output of this function. |
Discrete Filter Details
This function uses the following equation to calculate the output:
| where | b0…bm are the coefficients of the numerator polynomial function |
| a0…an are the coefficients of the denominator polynomial function | |
| m is the order of the numerator | |
| n is the order of the denominator | |
| z is the z-transform variable |
The Discrete Filter function is based completely on the Discrete Transfer Function function.
Feedthrough Behavior
The number of zeros that begin the Numerator and Denominator subparameters determine the feedthrough behavior of this function. Given c as the index of the first non-zero coefficient in the Numerator and d as the index of the first non-zero coefficient in the Denominator:
- If c = d, all input/output pairs have direct feedthrough behavior.
- If c > d, the following input/output pair has indirect feedthrough behavior.
- input – output
- If c < d, LabVIEW returns an error.
When you use the configuration dialog box to configure c and d, LabVIEW verifies that the feedthrough behavior is correct. For example, if you set the Execution Mode parameter to Indirect, and you set c equal to d, LabVIEW changes the Execution Mode parameter to Direct.
If you set Numerator and Denominator programmatically, LabVIEW does not adjust the feedthrough behavior for you. You must ensure that you specify the proper feedthrough behavior for the Numerator and Denominator values you specify.
Example
Refer to the discrete filter VI in the labview\examples\simulation\Getting Started\Discrete Linear directory for an example of using the Discrete Filter VI.