In mathematical analysis, the final value theorem (FVT) is one of several similar theorems used to relate frequency domain expressions to the time domain behavior as time approaches infinity.[1][2][3][4] Mathematically, if in continuous time has (unilateral) Laplace transform , then a final value theorem establishes conditions under which Likewise, if in discrete time has (unilateral) Z-transform , then a final value theorem establishes conditions under which

An Abelian final value theorem makes assumptions about the time-domain behavior of to calculate Conversely, a Tauberian final value theorem makes assumptions about the frequency-domain behaviour of to calculate (see Abelian and Tauberian theorems for integral transforms).

Final value theorems for the Laplace transform

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Deducing limt → ∞ f(t)

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In the following statements, the notation   means that   approaches 0, whereas   means that   approaches 0 through the positive numbers.

Standard Final Value Theorem

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Suppose that every pole of   is either in the open left half plane or at the origin, and that   has at most a single pole at the origin. Then   as   and  [5]

Final Value Theorem using Laplace transform of the derivative

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Suppose that   and   both have Laplace transforms that exist for all   If   exists and   exists then  [3]: Theorem 2.36 [4]: 20 [6]

Remark

Both limits must exist for the theorem to hold. For example, if   then   does not exist, but[3]: Example 2.37 [4]: 20   

Improved Tauberian converse Final Value Theorem

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Suppose that   is bounded and differentiable, and that   is also bounded on  . If   as   then  [7]

Extended Final Value Theorem

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Suppose that every pole of   is either in the open left half-plane or at the origin. Then one of the following occurs:

  1.   as   and  
  2.   as   and   as  
  3.   as   and   as  

In particular, if   is a multiple pole of   then case 2 or 3 applies  [5]

Generalized Final Value Theorem

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Suppose that   is Laplace transformable. Let  . If   exists and   exists then

 

where   denotes the Gamma function.[5]

Applications

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Final value theorems for obtaining   have applications in establishing the long-term stability of a system.

Deducing lims → 0 sF(s)

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Abelian Final Value Theorem

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Suppose that   is bounded and measurable and   Then   exists for all   and  [7]

Elementary proof[7]

Suppose for convenience that   on   and let  . Let   and choose   so that   for all   Since   for every   we have

 

hence

 

Now for every   we have

 

On the other hand, since   is fixed it is clear that  , and so   if   is small enough.

Final Value Theorem using Laplace transform of the derivative

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Suppose that all of the following conditions are satisfied:

  1.   is continuously differentiable and both   and   have a Laplace transform
  2.   is absolutely integrable - that is,   is finite
  3.   exists and is finite

Then[8]  

Remark

The proof uses the dominated convergence theorem.[8]

Final Value Theorem for the mean of a function

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Let   be a continuous and bounded function such that such that the following limit exists

 

Then  [9]

Final Value Theorem for asymptotic sums of periodic functions

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Suppose that Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "http://localhost:6011/en.wikipedia.org/v1/":): {\displaystyle f : [0,\infty) \to \mathbb{R} } is continuous and absolutely integrable in   Suppose further that   is asymptotically equal to a finite sum of periodic functions   that is

 

where   is absolutely integrable in   and vanishes at infinity. Then

 [10]

Final Value Theorem for a function that diverges to infinity

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Let   and   be the Laplace transform of   Suppose that   satisfies all of the following conditions:

  1.   is infinitely differentiable at zero
  2.   has a Laplace transform for all non-negative integers  
  3.   diverges to infinity as  

Then   diverges to infinity as  [11]

Final Value Theorem for improperly integrable functions (Abel's theorem for integrals)

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Let   be measurable and such that the (possibly improper) integral   converges for   Then   This is a version of Abel's theorem.

To see this, notice that   and apply the final value theorem to   after an integration by parts: For  

 

By the final value theorem, the left-hand side converges to   for  

To establish the convergence of the improper integral   in practice, Dirichlet's test for improper integrals is often helpful. An example is the Dirichlet integral.

Applications

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Final value theorems for obtaining   have applications in probability and statistics to calculate the moments of a random variable. Let   be cumulative distribution function of a continuous random variable   and let   be the Laplace–Stieltjes transform of   Then the  -th moment of   can be calculated as   The strategy is to write   where   is continuous and for each     for a function   For each   put   as the inverse Laplace transform of   obtain   and apply a final value theorem to deduce   Then

 

and hence   is obtained.

Examples

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Example where FVT holds

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For example, for a system described by transfer function

 

the impulse response converges to

 

That is, the system returns to zero after being disturbed by a short impulse. However, the Laplace transform of the unit step response is

 

and so the step response converges to

 

So a zero-state system will follow an exponential rise to a final value of 3.

Example where FVT does not hold

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For a system described by the transfer function

 

the final value theorem appears to predict the final value of the impulse response to be 0 and the final value of the step response to be 1. However, neither time-domain limit exists, and so the final value theorem predictions are not valid. In fact, both the impulse response and step response oscillate, and (in this special case) the final value theorem describes the average values around which the responses oscillate.

There are two checks performed in Control theory which confirm valid results for the Final Value Theorem:

  1. All non-zero roots of the denominator of   must have negative real parts.
  2.   must not have more than one pole at the origin.

Rule 1 was not satisfied in this example, in that the roots of the denominator are   and  

Final value theorems for the Z transform

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Deducing limk → ∞ f[k]

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Final Value Theorem

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If   exists and   exists then  [4]: 101 

Final value of linear systems

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Continuous-time LTI systems

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Final value of the system

 
 

in response to a step input   with amplitude   is:

 

Sampled-data systems

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The sampled-data system of the above continuous-time LTI system at the aperiodic sampling times   is the discrete-time system

 
 

where   and

 ,  

The final value of this system in response to a step input   with amplitude   is the same as the final value of its original continuous-time system.[12]

See also

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Notes

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  1. ^ Wang, Ruye (2010-02-17). "Initial and Final Value Theorems". Archived from the original on 2017-12-26. Retrieved 2011-10-21.
  2. ^ Alan V. Oppenheim; Alan S. Willsky; S. Hamid Nawab (1997). Signals & Systems. New Jersey, USA: Prentice Hall. ISBN 0-13-814757-4.
  3. ^ a b c Schiff, Joel L. (1999). The Laplace Transform: Theory and Applications. New York: Springer. ISBN 978-1-4757-7262-3.
  4. ^ a b c d Graf, Urs (2004). Applied Laplace Transforms and z-Transforms for Scientists and Engineers. Basel: Birkhäuser Verlag. ISBN 3-7643-2427-9.
  5. ^ a b c Chen, Jie; Lundberg, Kent H.; Davison, Daniel E.; Bernstein, Dennis S. (June 2007). "The Final Value Theorem Revisited - Infinite Limits and Irrational Function". IEEE Control Systems Magazine. 27 (3): 97–99. doi:10.1109/MCS.2007.365008.
  6. ^ "Final Value Theorem of Laplace Transform". ProofWiki. Retrieved 12 April 2020.
  7. ^ a b c Ullrich, David C. (2018-05-26). "The tauberian final value Theorem". Math Stack Exchange.
  8. ^ a b Sopasakis, Pantelis (2019-05-18). "A proof for the Final Value theorem using Dominated convergence theorem". Math Stack Exchange.
  9. ^ Murthy, Kavi Rama (2019-05-07). "Alternative version of the Final Value theorem for Laplace Transform". Math Stack Exchange.
  10. ^ Gluskin, Emanuel (1 November 2003). "Let us teach this generalization of the final-value theorem". European Journal of Physics. 24 (6): 591–597. doi:10.1088/0143-0807/24/6/005.
  11. ^ Hew, Patrick (2020-04-22). "Final Value Theorem for function that diverges to infinity?". Math Stack Exchange.[permanent dead link]
  12. ^ Mohajeri, Kamran; Madadi, Ali; Tavassoli, Babak (2021). "Tracking Control with Aperiodic Sampling over Networks with Delay and Dropout". International Journal of Systems Science. 52 (10): 1987–2002. doi:10.1080/00207721.2021.1874074.
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