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[[Category:ECE600]] | [[Category:ECE600]] | ||
[[Category:Lecture notes]] | [[Category:Lecture notes]] | ||
+ | |||
+ | [[ECE600_F13_notes_mhossain|Back to all ECE 600 notes]]<br/> | ||
+ | [[ECE600_F13_rv_distribution_mhossain|Previous Topic: Random Variables: Distributions]]<br/> | ||
+ | [[ECE600_F13_rv_Functions_of_random_variable_mhossain|Next Topic: Functions of a Random Variable]] | ||
+ | ---- | ||
+ | [[Category:ECE600]] | ||
+ | [[Category:probability]] | ||
+ | [[Category:lecture notes]] | ||
+ | [[Category:slecture]] | ||
<center><font size= 4> | <center><font size= 4> | ||
− | '''Random Variables and Signals''' | + | [[ECE600_F13_notes_mhossain|'''The Comer Lectures on Random Variables and Signals''']] |
</font size> | </font size> | ||
+ | |||
+ | [https://www.projectrhea.org/learning/slectures.php Slectures] by [[user:Mhossain | Maliha Hossain]] | ||
+ | |||
<font size= 3> Topic 7: Random Variables: Conditional Distributions</font size> | <font size= 3> Topic 7: Random Variables: Conditional Distributions</font size> | ||
</center> | </center> | ||
− | |||
---- | ---- | ||
− | + | ---- | |
We will now learn how to represent conditional probabilities using the cdf/pdf/pmf. This will provide us some of the most powerful tools for working with random variables: the conditional pdf and conditional pmf. | We will now learn how to represent conditional probabilities using the cdf/pdf/pmf. This will provide us some of the most powerful tools for working with random variables: the conditional pdf and conditional pmf. | ||
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==Continuous X== | ==Continuous X== | ||
− | Let A = {X≤x}. Then if P(B)>0, B ∈ ''F'', | + | Let A = {X≤x}. Then if P(B)>0, B ∈ ''F'', define <br/> |
<center><math>F_X(x|B)\equiv P(X\leq x|B) = \frac{P(\{X\leq x\}\cap B)}{P(B)}</math></center> | <center><math>F_X(x|B)\equiv P(X\leq x|B) = \frac{P(\{X\leq x\}\cap B)}{P(B)}</math></center> | ||
as the conditional cdf of X given B.<br/> | as the conditional cdf of X given B.<br/> | ||
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Note that B may be an event involving X. <br/> | Note that B may be an event involving X. <br/> | ||
− | '''Example:''' let B = { | + | '''Example:''' let B = {X ≤ a} for some a ∈ '''R'''. Then <br/> |
<center><math>F_X(x|B) = \frac{P(\{X\leq x\}\cap\{X\leq a\})}{P(X\leq a)}</math></center> | <center><math>F_X(x|B) = \frac{P(\{X\leq x\}\cap\{X\leq a\})}{P(X\leq a)}</math></center> | ||
Two cases: | Two cases: | ||
− | * Case (i): <math>x>a</math><br/> | + | * Case (i): <math>x > a</math><br/> |
− | <center><math>F_X(x|B) = \frac{P(X\leq a)}{P(X\leq a} = 1</math></center> | + | <center><math>F_X(x|B) = \frac{P(X\leq a)}{P(X\leq a)} = 1</math></center> |
− | * Case (ii): <math>x | + | * Case (ii): <math>x < a</math><br/> |
− | <center><math>F_X(x|B) = \frac{P(X\leq x)}{P(X\leq a} = \frac{F_X(x)}{F_X(a)}</math></center> | + | <center><math>F_X(x|B) = \frac{P(X\leq x)}{P(X\leq a)} = \frac{F_X(x)}{F_X(a)}</math></center> |
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Bayes' Theorem for continuous X:<br/> | Bayes' Theorem for continuous X:<br/> | ||
We can easily see that <br/> | We can easily see that <br/> | ||
− | <center><math>F_X(x|B)= \frac{P(B|X\leq x) | + | <center><math>F_X(x|B)= \frac{P(B|X\leq x)F_X(x)}{P(B)}</math></center> |
from previous version of Bayes' Theorem, and that <br/> | from previous version of Bayes' Theorem, and that <br/> | ||
<center><math>F_X(x)=\sum_{i=1}^n F_X(x|A_i)P(A_i)</math></center> | <center><math>F_X(x)=\sum_{i=1}^n F_X(x|A_i)P(A_i)</math></center> | ||
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Instead, we will use the following definition in this case:<br/> | Instead, we will use the following definition in this case:<br/> | ||
<center><math>P(A|X=a)\equiv\lim_{\Delta x\rightarrow 0}P(A|x<X\leq x+\Delta x)</math></center> | <center><math>P(A|X=a)\equiv\lim_{\Delta x\rightarrow 0}P(A|x<X\leq x+\Delta x)</math></center> | ||
+ | <center><math>\Delta x > 0 \ </math></center> | ||
using our standard definition of conditional probability for the rhs. This leads to the following derivation:<br/> | using our standard definition of conditional probability for the rhs. This leads to the following derivation:<br/> | ||
<center><math>\begin{align} | <center><math>\begin{align} | ||
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This is how Bayes' Theorem is normally stated for a continuous random variable X and an event ''A''∈''F'' with P(''A'') > 0. | This is how Bayes' Theorem is normally stated for a continuous random variable X and an event ''A''∈''F'' with P(''A'') > 0. | ||
− | We will revisit Bayes' Theorem one more time when we discuss two random variables. | + | We will revisit Bayes' Theorem one more time when we discuss [[ECE600_F13_Conditional_Distributions_for_Two_Random_Variables_mhossain| conditional distributions for two random variables]]. |
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---- | ---- | ||
− | [[ECE600_F13_notes_mhossain|Back to all ECE 600 notes]] | + | [[ECE600_F13_notes_mhossain|Back to all ECE 600 notes]]<br/> |
+ | [[ECE600_F13_rv_distribution_mhossain|Previous Topic: Random Variables: Distributions]]<br/> | ||
+ | [[ECE600_F13_rv_Functions_of_random_variable_mhossain|Next Topic: Functions of a Random Variable]] |
Latest revision as of 11:11, 21 May 2014
Back to all ECE 600 notes
Previous Topic: Random Variables: Distributions
Next Topic: Functions of a Random Variable
The Comer Lectures on Random Variables and Signals
Topic 7: Random Variables: Conditional Distributions
We will now learn how to represent conditional probabilities using the cdf/pdf/pmf. This will provide us some of the most powerful tools for working with random variables: the conditional pdf and conditional pmf.
Recall that
∀ A,B ∈ F with P(B) > 0.
We will consider this conditional probability when A = {X≤x} for a continuous random variable or A = {X=x} for a discrete random variable.
Discrete X
If P(B)>0, then let
∀x ∈ R, for a given B ∈ F.
The function p$ _X $ is the conditional pmf of X. Recall Bayes' theorem and the Total Probability Law:
and
if $ A_1,...,A_n $ form a partition of S and $ P(A_i)>0 $ ∀i.
In the case A = {X=x}, we get
where p$ _X $(x|B) is the conditional pmf of X given B and $ p_X(x) $ is the pmf of X. Note that Bayes' Theorem in this context requires not only that P(B) >0 but also that P(X = x) > 0.
We also can use the TPL to get
Continuous X
Let A = {X≤x}. Then if P(B)>0, B ∈ F, define
as the conditional cdf of X given B.
The conditional pdf of X given B is then
Note that B may be an event involving X.
Example: let B = {X ≤ a} for some a ∈ R. Then
Two cases:
- Case (i): $ x > a $
- Case (ii): $ x < a $
Now,
Bayes' Theorem for continuous X:
We can easily see that
from previous version of Bayes' Theorem, and that
if $ A_1,...,A_n $ form a partition of S and P($ A_i $) > 0 ∀$ i $, from TPL.
but what we often want to know is a probability of the type P(A|X=x) for some A∈F. We could define this as
but the right hand side (rhs) would be 0/0 since X is continuous.
Instead, we will use the following definition in this case:
using our standard definition of conditional probability for the rhs. This leads to the following derivation:
So,
This is how Bayes' Theorem is normally stated for a continuous random variable X and an event A∈F with P(A) > 0.
We will revisit Bayes' Theorem one more time when we discuss conditional distributions for two random variables.
References
- M. Comer. ECE 600. Class Lecture. Random Variables and Signals. Faculty of Electrical Engineering, Purdue University. Fall 2013.
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