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{{Short description|Condition determining when a linear electronic circuit will oscillate}}
[[Image:Oscillator diagram1.svg|thumb|250px|Block diagram of a feedback oscillator circuit to which the Barkhausen criterion applies. It consists of an amplifying element ''A'' whose output ''v<sub>o</sub>'' is fed back into its input ''v<sub>f</sub>'' through a feedback network ''ß(jω)''.]]
[[Image:Oscillator diagram2.svg|thumb|250px|To find the [[loop gain]], the feedback loop is considered broken at some point and the output ''v<sub>o</sub>'' for a given input ''v<sub>i</sub>'' is calculated:<br>
:<math>G = \frac {v_o}{v_i} = \frac{v_f}{v_i}\frac {v_o}{v_f} = \beta A(j \omega)\,</math>]]

{{For|the noise in the output of a ferromagnet upon a change in the magnetizing force|Barkhausen effect}}
{{For|the noise in the output of a ferromagnet upon a change in the magnetizing force|Barkhausen effect}}
{{Use dmy dates|date=January 2021}}
[[File:Oscillator diagram1.svg|thumb|250px|Block diagram of a feedback oscillator circuit to which the Barkhausen criterion applies. It consists of an amplifying element ''A'' whose output ''v<sub>o</sub>'' is fed back into its input ''v<sub>f</sub>'' through a feedback network ''β(jω)''.]]
[[File:Oscillator diagram2.svg|thumb|250px|To find the [[loop gain]], the feedback loop is considered broken at some point and the output ''v<sub>o</sub>'' for a given input ''v<sub>i</sub>'' is calculated:<br>
<math>G = \frac {v_o}{v_i} = \frac{v_f}{v_i}\frac {v_o}{v_f} = \beta A(j \omega)\,</math>]]In [[electronics]], the '''Barkhausen stability criterion''' is a mathematical condition to determine when a [[linear circuit|linear electronic circuit]] will [[oscillate]].<ref name="Basu">{{cite book
| last = Basu
| first = Dipak
| title = Dictionary of Pure and Applied Physics
| publisher = CRC Press
| year = 2000
| pages = 34–35
| url = https://books.google.com/books?id=-QhAkBSk7IUC&pg=PA35
| isbn = 1420050222}}</ref><ref name="Rhea">{{cite book
| last = Rhea
| first = Randall W.
| title = Discrete Oscillator Design: Linear, Nonlinear, Transient, and Noise Domains
| publisher = Artech House
| year = 2010
| pages = 3
| url = https://books.google.com/books?id=4Op56QdHFPUC&pg=PA3
| isbn = 978-1608070480}}</ref><ref name="Carter">{{cite book
| last = Carter
| first = Bruce
|author2=Ron Mancini
| title = Op Amps for Everyone, 3rd Ed.
| publisher = Newnes
| year = 2009
| pages = 342–343
| url = https://books.google.com/books?id=nnCNsjpicJIC&pg=PA342
| isbn = 978-0080949482}}</ref> It was put forth in 1921 by [[Germany|German]] physicist [[Heinrich Barkhausen]] (1881–1956).<ref name="Barkhausen">{{cite book
| last = Barkhausen
| first = H.
| title = Lehrbuch der Elektronen-Röhren und ihrer technischen Anwendungen |volume=3 |trans-title=Textbook of Electron Tubes and their Technical Applications |language=de
| publisher = S. Hirzel
| year = 1935
| location = Leipzig
|asin=B0019TQ4AQ
|oclc=682467377 <!-- for 1945 5th edition -->
}}</ref> It is widely used in the design of [[electronic oscillator]]s, and also in the design of general [[negative feedback]] circuits such as [[op amp]]s, to prevent them from oscillating.


==Limitations==
The '''Barkhausen stability criterion''' is a mathematical condition to determine when an [[electronic circuit]] will [[oscillate]]. It was put forth in 1921 by [[Germany|German]] physicist [[Heinrich Georg Barkhausen]] (1881-1956). It is widely used in the design of [[electronic oscillator]]s, and also in the design of general [[negative feedback]] circuits such as [[op amp]]s, to prevent them from oscillating.


Barkhausen's criterion applies to [[linear circuits]] with a [[feedback loop]]. It cannot be applied directly to active elements with [[negative resistance]] like [[tunnel diode]] oscillators.
==Applications==
Barkhausen's criterion applies to circuits with a [[feedback loop]]. Therefore it cannot be applied to one port [[negative resistance]] active elements like [[tunnel diode]] oscillators.


The kernel of the criterion is that a [[Zeros and poles|complex pole pair]] must be placed on the [[imaginary axis]] of the [[Complex plane|complex frequency plane]] if [[steady state]] oscillations should take place. In the real world, it is impossible to balance on the imaginary axis; small errors will cause the poles to be either slightly to the right or left, resulting in infinite growth or decreasing to zero, respectively. Thus, in practice a steady-state oscillator is a non-linear circuit; the poles are manipulated to be slightly to the right, and a nonlinearity is introduced that reduces the loop gain when the output is high.
==Theory==

It states that if <math>A \,</math> is the [[gain]] of the amplifying element in the circuit and <math>\beta(j\omega)\,</math> is the [[transfer function]] of the feedback path, so <math>\beta A\,</math> is the [[loop gain]] around the [[feedback loop]] of the circuit, the circuit will sustain steady-state oscillations only at frequencies for which:
==Criterion==
#The loop gain is equal to unity in absolute magnitude, that is, <math>|\beta A| = 1\,;</math>
It states that if ''A'' is the [[Gain (electronics)|gain]] of the amplifying element in the circuit and β(''j''ω) is the [[transfer function]] of the feedback path, so β''A'' is the [[loop gain]] around the [[feedback loop]] of the circuit, the circuit will sustain steady-state oscillations only at frequencies for which:
#There must be a positive feedback i.e., the [[phase shift]] around the loop is zero or an integer multiple of 2π: <math>\angle \beta A = 2 \pi n, n \in 0, 1, 2,\dots\,.</math>
#The loop gain is equal to unity in absolute magnitude, that is, <math>|\beta A| = 1\,</math> and
===Single-way condition===
#The [[phase shift]] around the loop is zero or an integer multiple of 2π: <math>\angle \beta A = 2 \pi n, n \in \{0, 1, 2,\dots\}\,.</math>
Barkhausen's criterion is a ''necessary'' condition for oscillation, not ''sufficient''. This means there are some circuits which satisfy the criterion but do not oscillate. These can be distinguished with the [[Nyquist stability criterion]], which is both necessary and sufficient.

Barkhausen's criterion is a ''necessary'' condition for oscillation but not a ''sufficient'' condition: some circuits satisfy the criterion but do not oscillate.<ref name="Lindberg">{{cite conference
| first = Erik
| last = Lindberg
| title = The Barkhausen Criterion (Observation ?)
| book-title = Proceedings of 18th IEEE Workshop on Nonlinear Dynamics of Electronic Systems (NDES2010), Dresden, Germany
| pages = 15–18
| publisher = Inst. of Electrical and Electronic Engineers
| date = 26–28 May 2010
| url = http://www.qucosa.de/fileadmin/data/qucosa/documents/3913/ProceedingsNDES2010.pdf
| access-date = 2 February 2013
| archive-url = https://web.archive.org/web/20160304040330/http://www.qucosa.de/fileadmin/data/qucosa/documents/3913/ProceedingsNDES2010.pdf
| url-status = dead
| archive-date = 4 March 2016}} discusses reasons for this. (Warning: large 56MB download)</ref> Similarly, the [[Nyquist stability criterion]] also indicates instability but is silent about oscillation. Apparently there is not a compact formulation of an oscillation criterion that is both necessary and sufficient.<ref>{{Citation |last= von Wangenheim |first= Lutz
|title=On the Barkhausen and Nyquist stability criteria
|journal=Analog Integrated Circuits and Signal Processing
|volume=66 |issue=1
|pages=139&ndash;141
|publisher= Springer Science+Business Media, LLC
|year= 2010
|issn= 1573-1979
|doi= 10.1007/s10470-010-9506-4 |s2cid= 111132040
}}. Received: 17 June 2010 / Revised: 2 July 2010 / Accepted: 5 July 2010.</ref>


==Erroneous version==
==Erroneous version==
Line 21: Line 78:
| last = Lundberg
| last = Lundberg
| first = Kent
| first = Kent
| authorlink =
| coauthors =
| title = Barkhausen Stability Criterion
| title = Barkhausen Stability Criterion
| work = [http://web.mit.edu/klund/www/ Kent Lundberg faculty website]
| work = Kent Lundberg
| publisher = MIT
| publisher = MIT
| date = 2002-11-14
| date = 14 November 2002
| url = http://web.mit.edu/klund/www/weblatex/node4.html
| url = http://web.mit.edu/klund/www/weblatex/node4.html
| access-date = 16 November 2008| archive-url= https://web.archive.org/web/20081007072144/http://web.mit.edu/klund/www/weblatex/node4.html| archive-date= 7 October 2008 | url-status= live}}</ref> However, ''sustained'' oscillations only occur at frequencies for which equality holds.
| format =
| doi =
| accessdate = 2008-11-16}}</ref> However, ''stable'' oscillations only occur at frequencies for which equality holds.


== See also ==
== See also ==
*[[Nyquist criterion]]
*[[Nyquist stability criterion]]

== Notes ==
<references/>


== References ==
== References ==
{{reflist|30em}}



[[Category:Oscillation]]
[[Category:Oscillation]]
[[Category:Electronic circuits]]
[[Category:Electronic circuits]]

[[hi:बार्कहाउजेन कसौटी]]
[[sv:Barkhausen-kriteriet]]

Latest revision as of 02:19, 23 November 2024

For the noise in the output of a ferromagnet upon a change in the magnetizing force, see Barkhausen effect.

Block diagram of a feedback oscillator circuit to which the Barkhausen criterion applies. It consists of an amplifying element A whose output vo is fed back into its input vf through a feedback network β(jω).
To find the loop gain, the feedback loop is considered broken at some point and the output vo for a given input vi is calculated:

In electronics, the Barkhausen stability criterion is a mathematical condition to determine when a linear electronic circuit will oscillate.[1][2][3] It was put forth in 1921 by German physicist Heinrich Barkhausen (1881–1956).[4] It is widely used in the design of electronic oscillators, and also in the design of general negative feedback circuits such as op amps, to prevent them from oscillating.

Limitations

[edit]

Barkhausen's criterion applies to linear circuits with a feedback loop. It cannot be applied directly to active elements with negative resistance like tunnel diode oscillators.

The kernel of the criterion is that a complex pole pair must be placed on the imaginary axis of the complex frequency plane if steady state oscillations should take place. In the real world, it is impossible to balance on the imaginary axis; small errors will cause the poles to be either slightly to the right or left, resulting in infinite growth or decreasing to zero, respectively. Thus, in practice a steady-state oscillator is a non-linear circuit; the poles are manipulated to be slightly to the right, and a nonlinearity is introduced that reduces the loop gain when the output is high.

Criterion

[edit]

It states that if A is the gain of the amplifying element in the circuit and β(jω) is the transfer function of the feedback path, so βA is the loop gain around the feedback loop of the circuit, the circuit will sustain steady-state oscillations only at frequencies for which:

  1. The loop gain is equal to unity in absolute magnitude, that is, and
  2. The phase shift around the loop is zero or an integer multiple of 2π:

Barkhausen's criterion is a necessary condition for oscillation but not a sufficient condition: some circuits satisfy the criterion but do not oscillate.[5] Similarly, the Nyquist stability criterion also indicates instability but is silent about oscillation. Apparently there is not a compact formulation of an oscillation criterion that is both necessary and sufficient.[6]

Erroneous version

[edit]

Barkhausen's original "formula for self-excitation", intended for determining the oscillation frequencies of the feedback loop, involved an equality sign: |βA| = 1. At the time conditionally-stable nonlinear systems were poorly understood; it was widely believed that this gave the boundary between stability (|βA| < 1) and instability (|βA| ≥ 1), and this erroneous version found its way into the literature.[7] However, sustained oscillations only occur at frequencies for which equality holds.

See also

[edit]

References

[edit]
  1. ^ Basu, Dipak (2000). Dictionary of Pure and Applied Physics. CRC Press. pp. 34–35. ISBN 1420050222.
  2. ^ Rhea, Randall W. (2010). Discrete Oscillator Design: Linear, Nonlinear, Transient, and Noise Domains. Artech House. p. 3. ISBN 978-1608070480.
  3. ^ Carter, Bruce; Ron Mancini (2009). Op Amps for Everyone, 3rd Ed. Newnes. pp. 342–343. ISBN 978-0080949482.
  4. ^ Barkhausen, H. (1935). Lehrbuch der Elektronen-Röhren und ihrer technischen Anwendungen [Textbook of Electron Tubes and their Technical Applications] (in German). Vol. 3. Leipzig: S. Hirzel. ASIN B0019TQ4AQ. OCLC 682467377.
  5. ^ Lindberg, Erik (26–28 May 2010). "The Barkhausen Criterion (Observation ?)" (PDF). Proceedings of 18th IEEE Workshop on Nonlinear Dynamics of Electronic Systems (NDES2010), Dresden, Germany. Inst. of Electrical and Electronic Engineers. pp. 15–18. Archived from the original (PDF) on 4 March 2016. Retrieved 2 February 2013. discusses reasons for this. (Warning: large 56MB download)
  6. ^ von Wangenheim, Lutz (2010), "On the Barkhausen and Nyquist stability criteria", Analog Integrated Circuits and Signal Processing, 66 (1), Springer Science+Business Media, LLC: 139–141, doi:10.1007/s10470-010-9506-4, ISSN 1573-1979, S2CID 111132040. Received: 17 June 2010 / Revised: 2 July 2010 / Accepted: 5 July 2010.
  7. ^ Lundberg, Kent (14 November 2002). "Barkhausen Stability Criterion". Kent Lundberg. MIT. Archived from the original on 7 October 2008. Retrieved 16 November 2008.
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