Last Modified: January 12, 2018

Returns PID gains of a PID controller in the Series form.

Unit associated with the derivative gain.

This input accepts a ring or an array of rings.

Name | Value | Description |
---|---|---|

Hz | 0 | Specifies that the derivative gain is expressed in Hz. |

s | 1 | Specifies that the derivative gain is expressed in seconds. |

min | 2 | Specifies that the derivative gain is expressed in minutes. |

**Default: **The default value of this input changes depending on the data type you wire. If you wire a ring to this input, the default is s. If you wire an array of rings to this input, the default is Hz.

Unit associated with the integral gain.

This input accepts a ring or an array of rings.

Name | Value | Description |
---|---|---|

Hz | 0 | Specifies that the integral gain is expressed in Hz. |

s | 1 | Specifies that the integral gain is expressed in seconds. |

min | 2 | Specifies that the integral gain is expressed in minutes. |

**Default: **The default value of this input changes depending on the data type you wire. If you wire a ring to this input, the default is s. If you wire an array of rings to this input, the default is Hz.

Unit associated with the proportional gain.

The relationship between the available units is K = 100/PB.

This input accepts a ring or an array of rings.

Name | Value | Description |
---|---|---|

Gain (K) | 0 | Specifies that the proportional gain is expressed in terms of proportional gain (K). |

Band (PB) | 1 | Specifies that the proportional gain is expressed in terms of proportional band (PB). |

**Default: **Gain (K)

Value of the proportional component of the controller.

This input accepts a double-precision, floating-point number or an array of double-precision, floating-point numbers.

Value of the integral component of the controller.

This input accepts a double-precision, floating-point number or an array of double-precision, floating-point numbers.

Value of the derivative component of the controller.

This input accepts a double-precision, floating-point number or an array of double-precision, floating-point numbers.

Derivative lowpass filter coefficient of the controller.

If you specify a value for **filter coefficient unit**, you must also specify a value for **filter coefficient [a]**. When **filter coefficient unit** is Alpha, the valid value range of **filter coefficient [a]** is [0, 1]. When **filter coefficient unit** is N, the valid value range of **filter coefficient [a]** is [1, 1000].

**Default: ** NaN.

Unit of the derivative lowpass filter coefficients.

The relationship between the available units are as follows: N = 1/Alpha; Time Constant = 1/(2 * *Pi* * Cutoff Frequency).

This input accepts a ring or an array of rings.

Name | Value | Description |
---|---|---|

Alpha | 0 | Specifies that the filter coefficients are expressed in Alpha. |

N | 1 | Specifies that the filter coefficients are expressed in N. |

Cutoff Frequency | 2 | Specifies that the filter coefficients are expressed in Hz. |

Time Constant | 3 | Specifies that the filter coefficients are expressed in seconds. |

**Default: **Alpha

Action of the controller.

This input accepts a ring or an array of rings.

Name | Value | Description |
---|---|---|

Reverse | 0 | The controller is reverse-acting. |

Direct | 1 | The controller is direct-acting. |

**Default: **Reverse

Proportional gain, integral gain, derivative gain, and filter coefficient parameters of the controller.

This output can return a cluster or an array of clusters.

Proportional gain of the controller.

Integral gain of the controller.

Derivative gain of the controller.

Derivative lowpass filter coefficient of the controller.

The following transfer function represents a PID controller in the Series form:

${C}_{s}\left(s\right)={K}_{c}^{\prime}(1+\frac{1}{{T}_{I}^{\prime}s})\left(\frac{{T}_{D}^{\prime}s+1}{{\alpha}_{s}{T}_{D}^{\prime}s+1}\right)$

where

- ${K}_{c}^{\prime}$ is the proportional gain
- ${T}_{I}^{\prime}$ is the integral time constant
- ${T}_{D}^{\prime}$ is the derivative time constant
- ${\alpha}_{s}$ is the derivative filter coefficient

**Where This Node Can Run: **

Desktop OS: Windows

FPGA: Not supported

Web Server: Not supported in VIs that run in a web application