ULV Drives

← 3.2.2 DC- Closed Loop - Speed v 1.0         

Note: The Guide can be downloaded in PDF format at the end of the article.

Disclaimer and Safety Information

Disclaimer

This quick startup guide is provided as a complementary resource to the official motor drive manual and datasheets. It is not intended to be the sole source of information for proper motor drive configuration and operation. Incorrect configuration or software bugs may cause unintended behavior, including uncontrolled motor operation or runaway. Users must always conduct tests cautiously and ensure they have a reliable method to safely stop the system in such scenarios. Roboteq, the author, and related parties are not liable for any hardware damage, personal injury, or other consequences arising from the use or misuse of the information in this guide.

Safety Symbols Explanation

Table of Contents

1. How to Use This Guide
2. Theory
3. Required Parameters List
4. Configuration Steps
5. Closed Loop Position Tracking Tuning
   
6. Velocity Feedforward Tuning
7. Troubleshooting

1. How to Use This Guide

• This guide is part of a series of documents that must be followed sequentially to configure and test a Brushless DC motor. The process begins with the Open Loop configuration and continues through the sequence of documents until reaching the final target operating mode.
• For example, configuring a higher-level operating mode, such as Count Position with Hall sensors, requires completing the configuration and testing of lower-level modes, including Open, Torque and Speed modes.

2. Theory: Mode Operation

2. Theory: Motor Command and Feedback

• The accepted motor command range in Position Tracking mode is -1000 to +1000.
• If the motor command is sent through a communication parameter (e.g., serial command, CAN object, etc.), it will be internally limited to ±1000.
• If the command is received from another source (e.g., analog or pulse input, encoder, etc.), the input or sensor's minimum and maximum limits must be configured. These configurable limits will correspond to ±1000.
• Similarly, the feedback will be scaled to ±1000. To achieve this, the feedback sensor's minimum and maximum values must be set through the drive’s configuration.

2. Theory: Cascaded Operation

• The motor drive uses a cascaded control structure: the Position Loop controls the Speed Loop, which controls the Torque Loop, ensuring stable motor control. 
• Tuning Position mode requires both Speed and Torque loops to be tuned, while Speed mode needs only the Torque loop. Torque and Open Loop modes operate independently. 

2. Theory: Velocity Feedforward control

• Velocity Feedforward control is an additional feedforward loop taking part in Position mode. 
• In contrast to the Acceleration Feedforward control that acts in Speed Loop only during the acceleration of the motor, the Velocity Feedforward control acts every whenever there is a change in the trajectory and a resulting motor movement. 
• The motor drive operates by multiplying the motor's desired velocity by the velocity feedforward gain. The higher the velocity, the more feedforward power will be applied to the motor. The velocity feedforward power is added to the power output of the Position mode PID, so this mode operates in parallel with the position mode PID.

3. Required Parameters List

To complete the configuration sequence, ensure you have the following specifications readily available:

4. Configuration steps

1. Set the operating mode to ‘Closed Loop Count Position’

Closed-Loop Count Position mode uses a predefined acceleration, constant velocity, and deceleration to move the motor for the desired number of counts.

2. Set the command mode

If pulse or analog inputs are used, they should be configured accordingly. Set the input's minimum, center, and maximum values to correspond to -1000, 0, and +1000 for the motor command. Depending on the input mode, the range values will use different units. For example, in analog mode, the input values are expressed in millivolts (mV), while in pulse width mode, they are measured in microseconds (µs). For more details, refer to the Roborun+ manual and respective tutorials.

3. Pay attention to the command priorities. 

If a pulse or analog input is used, the Roborun+ slider should be muted to avoid conflicting commands. If the drive receives commands from multiple sources, the command priorities must be configured appropriately. For more details, refer to the Roborun+ manual and related guides.

4. Configure the feedback sensor

Position Tracking mode for DC drives supports pulse, analog, encoders, and SSI sensors as feedback. The sensors' minimum and maximum values must be set to scale their output to ±1000. The configuration process is similar to that of analog and pulse inputs. 

5. Configure the Closed Loop Error Detection 

This parameter is used to detect large tracking errors due to mechanical or sensor failures and shut down the motor in case of problem in closed loop speed or position modes. The detection mechanism checks the size of the tracking error and the time the error is present. Both loop error limit and time parameters are configurable.

6. Set the desired motion profile by configuring the acceleration, deceleration and position mode velocity parameters. 

The motor will move to the desired position following a trapezoidal acceleration, speed, and deceleration profile. How closely this profile is followed is determined by the PID gains. Note that higher acceleration and deceleration values will require more current for the movements.

7. Set a starting value for the position proportional gain and start the tuning. 

Position mode is primarily tuned using proportional gain. A small value, such as 0.03, can be tested initially. Increase the gain until the feedback matches the track command. Integral gain may reduce the final position error but can also cause overshoots. Test with a small amount of integral gain.

• If the motor command is gradually increased (e.g. when using a potentiometer), the motor feedback should closely follow.
• In cases where the command comes from another source (e.g., serial command), the feedback will have a delay, since the rotor cannot physically reach the set point immediately.
• Integral gain may help reduce the final position error but can also cause overshoots. Test with a small amount of integral gain.

Warning: 

Before testing closed-loop Position, Open Loop and Speed modes must be configured, and the sensor must be set correctly so that the reported speed is positive when a positive command is given. If the sensor is not set properly, the motor may enter a dangerous runaway condition. Ensure you have followed the respective guides.

5. Closed Loop Position Tracking Tuning

A small value of I gain has been used to ensure that an additional amount of power will be developed, so the motor accurately reaches the target position.

6. Velocity Feedforward Tuning

6. Add Velocity Feedforward Gain.

• The Velocity Feedforward control can be enabled by adding a non-zero value to the Velocity Feedforward gain.
• Start by setting a small value, such as 0.1
• Increase the gain until the desired response is achieved
• An easy way to determine the responsiveness of the position mode is by monitoring the Loop Error.
• Increase the Velocity Feedforward gain, until the loop Error is minimized.  
• A negative Loop Error indicates that the motor position is being updated faster than the desired trajectory
• Select a value that results in the minimum positive or negative loop error.
• In this example, the value of feedforward gain that will be retained is 1

7. Troubleshooting

Count Position mode operation should be an easy and straightforward process. If the motor does not behave as expected, consider checking the following general points:

• Test the Position command and Feedback
  1. Move the input and the feedback sensor to both edges and verify that they correspond to the ±1000 motor command and feedback.
• Pay attention to the command priorities: 
  1. Script and Fieldbus always have the highest priority. The priority of other command sources can be configured through the command priorities parameter. The command mode will change from the highest to the lowest priority if the command source remains inactive for longer than the watchdog timer’s time.
• Ensure that Torque and Speed modes are properly configured and tuned. 
  1. The motor drive uses a cascaded control operation, where control modes are interdependent. Poor configuration of Torque or Speed modes can affect Position mode.
• PI Tuning
  1. Large amounts of P gain can cause vibrations. 
  2. If the proportional gain cannot be increased more, because it creates vibrations, but still the desired performance is not achieved, consider modifying Speed or Torque mode configuration. Decrease the speed feedback filter cutoff frequency or decrease the torque mode bandwidth.
  3.  If the motor cannot reach the setpoint using only P gain, a small amount of I gain can be tested.
• Motor Runaway
  1. This could be due to misconfiguration of the sensor (feedback increases in the opposite direction). 
• Slow response
  1. The motor will follow the trajectory based on the PID settings. Achieving a faster response will require more current for the movement. However, if the current reaches the amp limit parameter, the response time cannot be further improved. Similarly, if the motor power reaches 100% (+- 1000 of Motor power parameter)
  2. The desired trajectory of the motor is represented by the Track Command parameter. The motor feedback should closely follow this value. If the trajectory is slow, consider increasing the motor Acceleration, Deceleration and Position Velocity parameters.
• Motor Does not Start:
  1. Verify that the sensor is properly configured for feedback 
  2. Perform an emergency stop and manually rotate the shaft, ensuring that the feedback value changes 
  3. Monitor the chart to confirm that the motor command is received 
  4. Ensure that there is not conflict between watchdog timer and motor command 
  5. Check the Run tab for any error flags 
  6. Ensure that the motor brake is disengaged or the motor is not jammed

← 3.2.2 DC- Closed Loop - Speed v 1.0