Is the characteristic function constant everywhere if it is constant at 0?

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Discussion Overview

The discussion revolves around the properties of characteristic functions, particularly whether a characteristic function that is constant in a neighborhood of zero must be constant everywhere. Participants explore implications of this property in various contexts, including probabilistic and non-probabilistic frameworks.

Discussion Character

  • Debate/contested
  • Technical explanation

Main Points Raised

  • Wayne questions the validity of the claim that if a characteristic function is constant in a neighborhood of zero, it must be constant everywhere.
  • Another participant notes that while the characteristic function at zero equals one, they are not aware of any characteristic function being constant for all probability density functions (PDFs) and requests clarification or sources.
  • A participant points out that the question lacks specification regarding the topological space involved, suggesting that context is crucial for the discussion.
  • Another participant references a generalization from Feller, stating that any characteristic function with constant absolute value takes a specific form and discusses implications for distributions concentrated on a lattice.

Areas of Agreement / Disagreement

Participants express differing views on the implications of the characteristic function being constant in a neighborhood of zero, indicating that the discussion remains unresolved with multiple competing perspectives.

Contextual Notes

Participants highlight the need for clarity regarding the topological space and the definitions of characteristic functions in different contexts, which may affect the validity of claims made in the discussion.

wayneckm
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Hi there,


Recently I have come across a proof with application of characteristic function.

After some steps in the proof, it concluded that there is a neighborhood of 0 such that the characteristic function is constant at 1, then it said the characteristic function is constant at 1 everywhere over the domain.

I suspect that "If there exists a neighborhood of 0 such that the characteristic function is constant, it is constant everywhere." Is this correct?

I have tried to search from the web regarding this but found nothing. Would anyone suggest me some good reference on characteristic function as well.

Thanks.


Wayne
 
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wayneckm said:
After some steps in the proof, it concluded that there is a neighborhood of 0 such that the characteristic function is constant at 1, then it said the characteristic function is constant at 1 everywhere over the domain.

I suspect that "If there exists a neighborhood of 0 such that the characteristic function is constant, it is constant everywhere." Is this correct?

I have tried to search from the web regarding this but found nothing. Would anyone suggest me some good reference on characteristic function as well.

Thanks.Wayne

It's true that

[tex]\varphi (0)=\int_{-\infty}^\infty f_{X}(x)dx=1[/tex].

However, I'm not aware that the ChF is constant anywhere for any PDF. Can you provide the source? Perhaps you are you talking about the (Dirac)delta distribution?

EDIT: The characteristic function is apparently defined differently in a non-probabilistic context. See the first paragraph of the following:

http://mathworld.wolfram.com/CharacteristicFunction.html
 
Last edited:
The question doesn't make any sense, since you don't specify what topological space you are working in.
 
wayneckm said:
... it concluded that there is a neighborhood of 0 such that the characteristic function is constant at 1, then it said the characteristic function is constant at 1 everywhere over the domain.

An interesting generalization of the result is proved in Feller (vol 2 p 475), namely that any c.f. with constant absolute value is of the form [tex]\psi_X(t) = e^{ibt}[/tex], i.e. [tex]|\psi|=1[/tex] and the distribution of X is concentrated at b; moreover any c.f. that achieves absolute value 1 away from t=0 is periodic and represents a distribution concentrated on a lattice.
 

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