Velocity Loop

Overview

The velocity loop is active when the drive operates in velocity mode (AXIS#.OPMODE DRV.OPMODE = 1) or position mode (OPMODEDRV.OPMODE = 2). The parameters that govern the velocity loop are shown in the Velocity Loop view. The various types of tuning for the drive adjust these parameters automatically, so you normally do not need to adjust the velocity loop parameters in the velocity loop screen.

Tabs in the Velocity Loop View

The velocity view includes an active block diagram. If you click on a block in the diagram, the appropriate tab opens below.

  • Velocity clamp. The velocity clamp affects the maximum speed of the drive when the command source is service (AXIS#.CMDSOURCE DRV.CMDSOURCE ). This speed limit affects motion commanded in service motion and in motion tasks. These limits are also found in the limit screen on WorkBench. (AXIS#.VL.LIMITP VL.LIMITP and AXIS#.VL.LIMITN VL.LIMITN )
  • AR1, AR2, AR3, AR4: These values are the independent bilinear quadratic (bi-quad) filters inside the drive. AR1 and AR2 are in the forward path and AR3 and AR4 are in the feedback path. These bi-quad filters can each be configured in five different modes.

  • 0–Unity Gain. The filter is off, and it will not affect the loop.
  • 1–Low Pass. In modes 1, 2, and 3, the bi-quad filter is configured for each respective type of filtering. The Edit Parameters field is used to set up the filter. The actual bi-quad filter values are shown to the left:

  • 2–Notch
  • 3–Lead Lag
  • 4–Bi-quad . A manually configured Bi-quad filter. This is an advanced tuning function.
  • 5–Autotuned Biquad . When the PST sets a filter after the PST process is complete, the values are input into the Bi-Quad filter and are shown as read only values.
  • Status. The status tab shows parameters that are relevant to the velocity loop performance.

Velocity Loop Default Settings and Changes

By default, a PI loop with a low-pass filter (AR1) is set in the drive.

The default value for the low-pass filter is 675Hz. The low-pass filter is important for disturbance rejection, and it also reduces the audible noise of the system.

Velocity Loop Changes Based on Slider Tuning

Slider tuning (see Slider Tuning) uses the slider control to adjust the proportional gain and integral gain values of the velocity loop based on the desired bandwidthClosedIn computer networking, bandwidth often refers to a data rate measured in bits/s, for example, network throughput. The reason for the connection of data rate with the term bandwidth is that the limit to the data rate of a physical communication link is related to its bandwidth in hertz. If you adjust the bandwidth using the slider tuner and then return to the velocity loop screen, you will see different values inside the proportional gain and integral gain fields. No adjustment is made to the filters automatically by using the slider tuner. Only the proportional and integral terms are adjusted.

Biquad Filters

Filters in the drive all exist as digital biquad filters in the servo loops. Lowpass, LeadLag, and Resonator filters are derived by the following equations. WorkBench handles all the math involved for the user. Enter the values in the fields for the type of filter desired.

Generate a Biquad as a Lowpass at Frequency F

Numerator Frequency = 5000

Numerator Q = Sqrt(2)/2 (this is 0.707)

Denominator Frequency = F

Denominator Q = Sqrt(2)/2 (this is 0.707)

Generate a Biquad as a LeadLag at Frequency F, Gain G

Numerator Frequency = F * 10^(-G/80)

Numerator Q = Sqrt(2)/2 (this is 0.707)

Denominator Frequency = F * 10^(G/80)

Denominator Q = Sqrt(2)/2 (this is 0.707)

Generate a Biquad as a Resonator at Frequency F, Gain G, Bandwidth Q

Numerator Frequency = F

Numerator Q = 10^(-G/40) * Q

Denominator Frequency = F

Denominator Q = 10^(G/40) * Q

Related Parameters

VL Parameters VL Parameters | AXIS#.CMDSOURCE DRV.CMDSOURCE | AXIS#.OPMODE DRV.OPMODE

Related Topics

Limits Limits | Service Motion | Tuning Your System | Motion TasksMotion Tasks