Feedback

Examples

Feedback takes many forms, the most common in engineering applications being negative feedback and positive feedback. Two common examples of negative feedback are error-controlled regulation and the negative feedback amplifier.

Error-controlled regulation

(PD) Diagram: John R. Brews
Keeping a car at the speed limit despite road variability.

(PD) Diagram: John R. Brews
Thermostatic control of house temperature using a negative feedback system.

An everyday example of negative feedback to control a system is shown at the left, where a car is maintained at the speed limit by a driver using the throttle (accelerator) to adjust to road conditions (for example, curves or grades). The car's speed is decided by a combination of the road conditions and the gas supplied. The gas supplied is the system feedback, the amount of which is controlled by the driver who compares the speedometer reading with the speed limit and reduces the error.

A more formal example of negative feedback is the thermostatic control of house temperature.^[6] In the figure, the house temperature is a response to the combined heat input from the world and from the furnace. Suppose a change occurs in the heat supplied to the house by the outside world. The resultant house temperature is sensed by a thermometer and converted to an electrical signal. This signal is compared by the thermostat to a set-point signal that corresponds to the desired temperature value. The discrepancy between the set point and the signal is calculated as an error signal by the thermostat, activating the valves regulating gas to the furnace. Depending upon the sign of the error the furnace produces more or less heat, regulating the combined heat input to the house so the temperature stays constant. In other words, the information on system temperature is used to generate feedback that keeps the temperature at value.

It might be noted that translation of signals between various forms (such as temperature, chemical signals, electrical signals, mechanical signals) occurs throughout the feedback loop. Also, there are time delays introduced at each step in a feedback loop that affect its success in tracking variations in the world's input.

The same principle is found in biology as homeostasis.^[7]

Terminology

(PD) Diagram: John R. Brews
A general block diagram showing feedback control of a system to maintain a set-point for status.

To discuss the general example, some formal terminology that does not depend upon the specific system is useful.^[8]

Control variable: The monitored parameter used to determine the system status; for example, speed of the car or temperature of the house.
Measured variable: The translated form of the control variable as output from a sensor; for example, the speedometer reading of vehicle speed, or the thermometer reading corresponding to house temperature.
Set point: The value of the measured variable that is considered desirable.
Error: The discrepancy between the measured and set-point values as calculated by a controller; for example, the driver's observation of the discrepancy between speed and speed limit, or the output of the thermostat.
Manipulated variable: The feedback variable to the system; for example the throttle position controlling gasoline input to the car or the gas valve position controlling fuel input to the furnace.
Load variable: The environmental input affecting the system; for example the grade of the road or the heat from the sun.
Controller: The mechanism that detects the discrepancy between the set point and the measured variable indicating system status and signals for action.
Sensor (Measuring element): The mechanism used to translate the system status to a variable understood by the controller.
Effector (Actuator): The mechanism supplying the feedback response to the system. In part, the carburetor and fuel supply system in the car, or the furnace in the house.
Receptor: The part of the system subject to disturbance and to control.

Diagrams that are rearrangements of the block diagram above are found in many sources.^[9]^[10]

Negative feedback amplifier

For more information, see: Negative feedback amplifier.

(PD) Image: John R. Brews
Ideal negative feedback amplifier using unidirectional blocks.

Using the image at right, and labeling the input I and the output O, the gain O/I of the amplifier is found as follows:

O=A_{OL}(I-\beta O)

O(1+\beta A_{OL})=A_{OL}I;

{\frac {O}{I}}={\frac {A_{OL}}{1+\beta A_{OL}}}\approx {\frac {1}{\beta }}.

Here the approximate form results in the usual case where βA_OL >> 1. Assuming the feedback network is well-controlled, for example, being made up of passive elements such as resistors, so long as βA_OL >> 1, the gain of the feedback amplifier is stable, predictable, and linear. There are other advantages to negative feedback in amplifiers.^[11]

It is quite common in electronics literature to call the difference I–βO the "error", and some sources confound this "error" with the use of that term in error-controlled regulation. However, although called an error, the amplifier circuit makes no attempt to minimize or otherwise reduce the difference I–βO, which is given by:

I-\beta O=I\left(1-\beta {\frac {O}{I}}\right)={\frac {I}{1+\beta A_{OL}}}

and is therefore fixed by the arbitrary input signal I and the invariant values of β and A_OL, and is not 'adjusted' as a matter of circuit operation. In addition, of course, I and O are the signal and the amplified signal, neither acting as a set-point for some internal system variable, as used in computing the error in error-controlled regulation. Although the above argument about (I–βO) shows beyond any dispute that this "error" has nothing to with "error" as something the amplifier circuit attempts to reduce, the literature is replete with blurry confusion of the negative feedback amplifier with error-controlled regulation based upon sloppy language.

References

↑ Mario Lucertini, Ana Millàn Gasca, Fernando Nicolò (2004). Technological Concepts and Mathematical Models in the Evolution of Modern Engineering Systems: Controlling, Managing, Organizing. Springer Science & Business Media, p. 103. ISBN 9783764369408.
↑ Dale E. Seborg, Duncan A. Mellichamp, Thomas F. Edgar, Francis J. Doyle, III (2010). “§15.1 Introduction to feedforward control”, Process Dynamics and Control. John Wiley & Sons, pp. 274 ff. ISBN 9780470128671.
↑ Philip Julian Runkel, Margaret Runkel (1984). A Guide to Usage for Writers and Students in the Social Sciences. Rowman & Littlefield, p. 107. ISBN 9780822603825.
↑ Abhishek Yadav (2008). Solid State Devices and Circuits. Firewall Media, p. 406. ISBN 9788131803202.
↑ Alta Smit, Arturo O'Byrne (2011). “Bipolar feedback”, Introduction to Bioregulatory Medicine. Thieme, p. 6. ISBN 9783131469717.
↑ Rao Ganesh (2010). “Feedback control”, Control engineering. Pearson Education India, pp. 29 ff. ISBN 9788131732335.
↑ See, for example, Lauralee Sherwood (2005). Fundamentals of Physiology: A Human Perspective, 3rd ed. Cengage Learning, p. 14. ISBN 9780534466978.
↑ Sudheer S Bhagade, Govind Das Nageshwar (2011). “Control terminology”, Process Dynamics and Control. PHI Learning Private Limited, pp. 3 ff. ISBN 9788120344051.
↑ Sudheer S Bhagade, Govind Das Nageshwar (2011). “Control terminology”, Process Dynamics and Control. PHI Learning Private Limited, p. 9. ISBN 9788120344051.
↑ See Figure 3.31 (b) in SK Singh (2009). Process Control: Concepts Dynamics And Applications. PHI Learning Private Ltd., p. 222. ISBN 978812033678.
↑ Santiram Kal (2009). “§6.3 Advantages of negative feedback amplifiers”, Basic electronics: Devices, circuits and its fundamentals. PHI Learning Pvt. Ltd, 193 ff. ISBN 9788120319523.

[Lucertini-1] Mario Lucertini, Ana Millàn Gasca, Fernando Nicolò (2004). Technological Concepts and Mathematical Models in the Evolution of Modern Engineering Systems: Controlling, Managing, Organizing. Springer Science & Business Media, p. 103. ISBN 9783764369408.

[Seborg-2] Dale E. Seborg, Duncan A. Mellichamp, Thomas F. Edgar, Francis J. Doyle, III (2010). “§15.1 Introduction to feedforward control”, Process Dynamics and Control. John Wiley & Sons, pp. 274 ff. ISBN 9780470128671.

[Runkel-3] Philip Julian Runkel, Margaret Runkel (1984). A Guide to Usage for Writers and Students in the Social Sciences. Rowman & Littlefield, p. 107. ISBN 9780822603825.

[Yadav-4] Abhishek Yadav (2008). Solid State Devices and Circuits. Firewall Media, p. 406. ISBN 9788131803202.

[Smit-5] Alta Smit, Arturo O'Byrne (2011). “Bipolar feedback”, Introduction to Bioregulatory Medicine. Thieme, p. 6. ISBN 9783131469717.

[Ganesh-6] Rao Ganesh (2010). “Feedback control”, Control engineering. Pearson Education India, pp. 29 ff. ISBN 9788131732335.

[Sherwood-7] See, for example, Lauralee Sherwood (2005). Fundamentals of Physiology: A Human Perspective, 3rd ed. Cengage Learning, p. 14. ISBN 9780534466978.

[Nageshwar-8] Sudheer S Bhagade, Govind Das Nageshwar (2011). “Control terminology”, Process Dynamics and Control. PHI Learning Private Limited, pp. 3 ff. ISBN 9788120344051.

[Nageshwar2-9] Sudheer S Bhagade, Govind Das Nageshwar (2011). “Control terminology”, Process Dynamics and Control. PHI Learning Private Limited, p. 9. ISBN 9788120344051.

[Singh-10] See Figure 3.31 (b) in SK Singh (2009). Process Control: Concepts Dynamics And Applications. PHI Learning Private Ltd., p. 222. ISBN 978812033678.

[Kal1-11] Santiram Kal (2009). “§6.3 Advantages of negative feedback amplifiers”, Basic electronics: Devices, circuits and its fundamentals. PHI Learning Pvt. Ltd, 193 ff. ISBN 9788120319523.

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Error-controlled regulation

Terminology

Negative feedback amplifier

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Negative feedback amplifier

References

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