Chi-squared dist. converges to normal as df goes to infinity, but

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nomadreid
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chi-squared dist. converges to normal as df goes to infinity, but...

This is surely going to sound naive, but at least this will make it easy to answer.

For a chi-squared distribution, if k = the degrees of freedom, then
[a] k = μ = (1/2) σ2
as k goes to infinity, the distribution approaches a normal distribution.

But when I put these two together, I get
[c] as k goes to infinity, the mean and the variance become infinite
which would seem odd for a normal curve.
What am I getting wrong here? Thanks in advance.
 
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The curve for every k gets closer and closer to a normal distribution with the same mean and variance with increasing k.
If you scale the distribution in an appropriate way, you get something approaching a normal distribution with mean 0 and variance 1.
 


mfb, thanks very much. That makes sense.
 


Putting k=μ (mean of the normals, I presume) appears weired, k is positive integer ( being the number of normals summed here), and -< μ< ∞ is real. Also that, if all means of the initial normal distributions are not 0, the then the resulting chi sq is non central.
 
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Where is the problem in different gaussian distributions which all have an integer as expectation value?
The chi-squared distribution is positive for positive values only, but for large k, the gaussian distribution is a reasonable approximation (its part <0 is negligible).
 


nomadreid said:
ssd: I did not "put" μ=k; this is a consequence of the definition: see http://en.wikipedia.org/wiki/Chi-squared_distribution. Why should this make it non-central? (contrast this with http://en.wikipedia.org/wiki/Noncentral_chi-squared_distribution). And since the naturals are a subset of the reals, there is no contradiction when the mean is a natural number.

Please check again. I am talking of μ as normal mean... you are mistaking μ as chi sq mean. "μ =k" CAN NOT be consequence of any literature definition, where ever written...lodge a request for correction there. And of course, I stand correct about non centrality... please go through the derivation of n.c. chi sq.

mfb said:
Where is the problem in different gaussian distributions which all have an integer as expectation value?
The chi-squared distribution is positive for positive values only, but for large k, the gaussian distribution is a reasonable approximation (its part <0 is negligible).
About integer and real part: I did not say that a particular value of normal mean cannot be integer. But I say, taking normal mean as integer is weired. The first loophole arises in context of the present problem as the fact that μ is differentiable but k is not.
 
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I am talking of μ as normal mean... you are mistaking μ as chi sq mean.
In that case, I am not sure of your question, because you referred to the original μ=k, and in the original context, μ is the mean of the chi squared distribution.
please go through the derivation of n.c. chi sq.
I'm also not sure whether this is a suggestion for me to go through it myself, or to write down the derivation here in this post. In the latter case, probably another contributor would do a better job of it than I would.
 


Well, if μ is assumed as chi sq mean, no issues (is it not obvious from my posts). The original post is some what misleading with (unnecessary) involvement of μ as the chi sq mean... where k clearly stands for that. Without clarification, μ has been naturally presumed as the originating normal mean. I understood your problem in a completely wrong way altogether.
Hope it clarifies my statements.
PS. "going through" in common jargon probably does not mean writing down. :)
 
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All's well that ends well. That's what I like about mathematics (and mathematicians): if people talk at cross purposes, it quickly gets cleared up. Unlike in most disciplines. So I guess this thread can be closed.