ผลต่างระหว่างรุ่นของ "Probstat/notes/chi-squared distribution"
Jittat (คุย | มีส่วนร่วม) |
Jittat (คุย | มีส่วนร่วม) |
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(ไม่แสดง 4 รุ่นระหว่างกลางโดยผู้ใช้คนเดียวกัน) | |||
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== Definition == | == Definition == | ||
− | + | {{กล่องฟ้า| | |
− | Let <math>Z_1,Z_2,\ldots,Z_n</math> be independent unit normal random variables. A random variable | + | '''Definition:''' Let <math>Z_1,Z_2,\ldots,Z_n</math> be independent unit normal random variables. A random variable |
<center> | <center> | ||
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</center> | </center> | ||
− | is called a ''chi-squared'' random variable with <math>n</math> | + | is called a ''chi-squared'' random variable with <math>n</math> degrees of freedom. We also write |
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<math>X\sim \chi_n^2.</math> | <math>X\sim \chi_n^2.</math> | ||
</center> | </center> | ||
+ | }} | ||
Wikipedia has a [http://en.wikipedia.org/wiki/Chi-squared_distribution nice article on chi-squared distribution] which also includes plots of its pdf and cdf. | Wikipedia has a [http://en.wikipedia.org/wiki/Chi-squared_distribution nice article on chi-squared distribution] which also includes plots of its pdf and cdf. | ||
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=== Expectations and variances === | === Expectations and variances === | ||
− | If <math>X</math> is chi-squared with <math>n</math> | + | If <math>X</math> is chi-squared with <math>n</math> degrees of freedom, we have that its expectation |
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</center> | </center> | ||
− | Note that the only differences between this term and the previous one is the use of sample mean <math>\bar{X}</math> instead of the population mean. It can be proved (not here) that in fact, for normal population, <math>S^2</math> (with some scaling) is actually a chi-squared random variable with <math>n-1</math> | + | Note that the only differences between this term and the previous one is the use of sample mean <math>\bar{X}</math> instead of the population mean. It can be proved (not here) that in fact, for normal population, <math>S^2</math> (with some scaling) is actually a chi-squared random variable with <math>n-1</math> degrees of freedom (instead of <math>n</math> as in the term computed from <math>\mu</math>). That is, |
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More over, for normal population, <math>\bar{X}</math> and <math>S^2</math> are independent. This is very surprising because both quantities are calculated from the same sample. | More over, for normal population, <math>\bar{X}</math> and <math>S^2</math> are independent. This is very surprising because both quantities are calculated from the same sample. | ||
+ | |||
+ | These two facts are important in the development of the procedure for calculating confidence intervals in case where <math>\sigma^2</math> is unknown. (See [[Probstat/notes/t-distributions|notes]].) | ||
+ | |||
+ | {{กล่องเทา|Two important facts about sample means and sample variances: | ||
+ | |||
+ | 1. <math>(n-1)S^2/\sigma^2 \sim \chi_{n-1}^2.</math> | ||
+ | |||
+ | 2. <math>\bar{X}</math> and <math>S^2</math> are independent. | ||
+ | }} | ||
== Links == | == Links == | ||
* [http://en.wikipedia.org/wiki/Chi-squared_distribution Wikipedia article on the chi-squared distribution] | * [http://en.wikipedia.org/wiki/Chi-squared_distribution Wikipedia article on the chi-squared distribution] |
รุ่นแก้ไขปัจจุบันเมื่อ 20:23, 5 ธันวาคม 2557
- This is part of probstat.
Definition
Definition: Let be independent unit normal random variables. A random variable
is called a chi-squared random variable with degrees of freedom. We also write
Wikipedia has a nice article on chi-squared distribution which also includes plots of its pdf and cdf.
Properties
Here we states important properties of the chi-squared distribution without proofs.
Expectations and variances
If is chi-squared with degrees of freedom, we have that its expectation
and its variance
Sample variances
The chi-squared distribution is very important when we want to reason about the sample variances (See notes). Under that settings, we sample from a normal population whose mean is and variance is .
We first note that if and is known, a term similar to the one we used to compute the same variance is chi-squared. Recall that is unit normal. Therefore,
However, usually, is unknown and we are left to the sample variance, defined as
.
Note that the only differences between this term and the previous one is the use of sample mean instead of the population mean. It can be proved (not here) that in fact, for normal population, (with some scaling) is actually a chi-squared random variable with degrees of freedom (instead of as in the term computed from ). That is,
More over, for normal population, and are independent. This is very surprising because both quantities are calculated from the same sample.
These two facts are important in the development of the procedure for calculating confidence intervals in case where is unknown. (See notes.)
Two important facts about sample means and sample variances:
1.
2. and are independent.