Difference between revisions of "ECE662Selecture zhenpengMLE" - Rhea

Revision as of 21:13, 5 May 2014

Expected Value of MLE estimate over standard deviation and expected deviation

A slecture by ECE student Zhenpeng Zhao

Statistical Density Theory Context
- Given c classes + some knowledge about features $x \in \mathbb{R}^n$ (or some other space)
- Given training data, $x_j\sim\rho(x)=\sum\limits_{i=1}^n\rho(x|w_i) Prob(w_i)$ , unknown class $w_{ij}$ for $$ x_j $$ is know, $\forall{j}=1,...,N$ (N hopefully large enough)
- In order to make decision, we need to estimate $\rho(x|w_i)$ , $$ Prob(w_i) $$ $\rightarrow$ use Bayes rule, or $\rho(x|w_i)$ $\rightarrow$ use Neyman-Pearson Criterion
- To estimate the above two, use training data.

The parametric pdf|Prob estimation problem
- Let $D={x_1,x_2,...,x_N}$ , $$ x_j $$ is drown independently from some probability law.
- Choose parametric from $\rho(x|\theta)$ for the pdf of x or $Prob(x|\theta)$ for the probability of x $\rightarrow$ an unknown parametric vector

(create a question page and put a link below)

@@ Line 23: / Line 23: @@
 **In order to make decision, we need to estimate <math>\rho(x|w_i)</math>, <math>Prob(w_i)</math> <math>\rightarrow</math> use Bayes rule, or <math>\rho(x|w_i)</math> <math>\rightarrow</math> use Neyman-Pearson Criterion
 **To estimate the above two, use training data.
+*The parametric pdf|Prob estimation problem
+** Let <math>D={x_1,x_2,...,x_N}</math>, <math>x_j</math> is drown independently from some probability law.
+** Choose parametric from <math>\rho(x|\theta)</math> for the pdf of x or <math>Prob(x|\theta)</math> for the probability of x <math>\rightarrow</math> an unknown parametric vector