Difference between revisions of "Dual-loop feedback position control"
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| − | + | In many linear motion cases it is preferred to use linear encoder mounted directly to the axis to provide accurate position readout and to use it as feedback signal for position controller. The benefit of that is the elimiation of error sources between rotary motor and linear motion. This page explains the implementation of such system. | |
| − | + | ==Background: traditional signel-loop feedback== | |
| + | A typical closed loop controller resembles the diagram below. | ||
| − | + | {{picturebox|Controller general.png|350px}} | |
| − | + | The closed loop system is formed by an '''actuator''', '''feedback''' and '''substraction''' (sigma): | |
| + | *Actuator is typically a comination of '''amplifier''' (such as a P or PI or PID gain amplifier), '''driver''' (such as an adjustable current source), and '''transducer''' (such as a motor). | ||
| + | *Feedback is typically a feedback device that measures the system output and converts it a numeric value (such as position count). | ||
| + | *Substraction (sigma) part is simply a calculation for tracing error: tracking_error = setpoint - measured_value_of_output | ||
| + | ===Practical position control servo axis=== | ||
| + | In a practical case, this type of closed loop may be used for servo motor position control just by choosing appropriate components: | ||
| − | + | {{picturebox|Controller position.png|350px}} | |
| − | + | This kind of controller could be used to produce linear motion with appropriate mechatronics assembly such as: | |
| − | [[ | + | {{picturebox|Servolinearaxis.png|600px}} |
| + | |||
| + | ==Dual-loop system: linear encoder feedback== | ||
| + | The drawback of above position control system is the position error caused by lead screw backlash, pitch error and flex. The problem is that the error is unknown because it is not being measured or controller: | ||
| + | |||
| + | {{picturebox|Controller position with error.png|500px}} | ||
| + | |||
| + | ===Dual-loop system=== | ||
| + | To elimiate the error of mechanics, one can add a linear encoder to read out the actual position of the axis instead of using derived value from rotary encoder behind the lead screw: | ||
| + | |||
| + | {{picturebox|Servolinearaxis dualloop.png|600px}} | ||
| + | |||
| + | However the problem there is that we have two separate position feedback signals: rotary and linear. One may think to replace rotary feedback with linear feedback in the original system. However, that will cause stability problems to the control loop due to backlash and flex of the mechanics. If motor is being controlled based on feedback signal with time delay (due to flex and backlash), it will easily render control loop unstable or leave user with very [[Servo stiffness|low stiffness]]. | ||
| + | |||
| + | In order to achieve stiff position control it is necessary to control motor by it's local rotary encoder AND control axis position based on linear encoder. Such system can be achieved by a dual-loop feedback system: | ||
| + | |||
| + | {{picturebox|Controller dualloop.png|750px}} | ||
| + | |||
| + | In the system above, we have two contorl loops: inner loop (rotary encoder based) and outer loop (linear encoder based). In this system outer loop generates the setpoint for the inner loop to correct the small error produced by mechanical inaccuracies. | ||
| + | |||
| + | ==How to build a dual-loop system== | ||
| + | The most common method to make a dual loop system is to connect servo motor with rotary encoder to a servo drive and tune it for velocity control mode. The linear encoder feedback should go to the [[controller]] that implements it's own position control and outputs a velocity setpoint to the servo drive. | ||
| + | |||
| + | {{picturebox|System dualloop.png|800px}} | ||
| + | Servo drive can be also set in position or torque mode but the simplest solution is to use velocity control mode in the inner loop. | ||
| + | |||
| + | From off-the-shelf solutions at least [[LinuxCNC]] supports dual-loop operation as the software implements a position controller with feedback input. | ||
| + | |||
| + | |||
| + | [[category:glossary]] | ||
| + | [[category:technology]] | ||
Latest revision as of 19:56, 22 September 2014
In many linear motion cases it is preferred to use linear encoder mounted directly to the axis to provide accurate position readout and to use it as feedback signal for position controller. The benefit of that is the elimiation of error sources between rotary motor and linear motion. This page explains the implementation of such system.
Contents
Background: traditional signel-loop feedback[edit | edit source]
A typical closed loop controller resembles the diagram below.
The closed loop system is formed by an actuator, feedback and substraction (sigma):
- Actuator is typically a comination of amplifier (such as a P or PI or PID gain amplifier), driver (such as an adjustable current source), and transducer (such as a motor).
- Feedback is typically a feedback device that measures the system output and converts it a numeric value (such as position count).
- Substraction (sigma) part is simply a calculation for tracing error: tracking_error = setpoint - measured_value_of_output
Practical position control servo axis[edit | edit source]
In a practical case, this type of closed loop may be used for servo motor position control just by choosing appropriate components:
This kind of controller could be used to produce linear motion with appropriate mechatronics assembly such as:
Dual-loop system: linear encoder feedback[edit | edit source]
The drawback of above position control system is the position error caused by lead screw backlash, pitch error and flex. The problem is that the error is unknown because it is not being measured or controller:
Dual-loop system[edit | edit source]
To elimiate the error of mechanics, one can add a linear encoder to read out the actual position of the axis instead of using derived value from rotary encoder behind the lead screw:
However the problem there is that we have two separate position feedback signals: rotary and linear. One may think to replace rotary feedback with linear feedback in the original system. However, that will cause stability problems to the control loop due to backlash and flex of the mechanics. If motor is being controlled based on feedback signal with time delay (due to flex and backlash), it will easily render control loop unstable or leave user with very low stiffness.
In order to achieve stiff position control it is necessary to control motor by it's local rotary encoder AND control axis position based on linear encoder. Such system can be achieved by a dual-loop feedback system:
In the system above, we have two contorl loops: inner loop (rotary encoder based) and outer loop (linear encoder based). In this system outer loop generates the setpoint for the inner loop to correct the small error produced by mechanical inaccuracies.
How to build a dual-loop system[edit | edit source]
The most common method to make a dual loop system is to connect servo motor with rotary encoder to a servo drive and tune it for velocity control mode. The linear encoder feedback should go to the controller that implements it's own position control and outputs a velocity setpoint to the servo drive.
Servo drive can be also set in position or torque mode but the simplest solution is to use velocity control mode in the inner loop.
From off-the-shelf solutions at least LinuxCNC supports dual-loop operation as the software implements a position controller with feedback input.
