Counting Sample Points

Combinatorics - counting rules in set theory. This provides the idea of the principles of enumeration, counting sample points in the sample space.
When an experiment is performed, the statistician want to evaluate the chance associated with the occurrence of certain events.
In many cases we can evaluate the probability by counting the number of points in the sample space.
Theorem 2.1 (multiplication rule):

$\fbox{\parbox{5in}{ If an operation can be performed in $n_1$\ ways, and if for ... ...$\ ways, then the two operations can be performed together in $n_1n_2$\ ways. }}$
The multiplication rule is the fundamental principle of counting sample points.

Example 2.14: Home buyers are offered
- four exterior styling
- three floor plans
Since and , a buyer must choose from

$\displaystyle n_1n_2=12$
possible homes

**Figure 2.4:** Tree diagram for Example 2.14.
$\includegraphics[scale=0.33]{figures/02-04}$

Theorem 2.2 (generalized multiplication rule):
$\fbox{\parbox{5in}{ If an operation can be performed in $n_1$\ ways, and if for ... ...he sequence of $k$\ operations can be performed in $n_1n_2 \ldots n_k$\ ways. }}$
The multiplication rule can be extended to cover any number of operations.

Example 2.16: How many even four-digit numbers can be formed from the digits 0, 1, 2, 5, 6, and 9 if each digit can be used only once?
We consider the unit position by two parts, 0 or not 0.
- If the units position is 0 :
  - choices for the thousands positions,
  - choices for the hundreds positions,
  - choices for the tens positions.
  - a total of choices.
- If the units position is not 0 :
  - choices for the thousands positions,
  - choices for the hundreds positions,
  - choices for the tens positions.
  - a total of choices.
- The total number of even four-digit numbers is 60 + 96 = 156

Permutation: Definition 2.7
$\fbox{\parbox{5in}{ A permutation is an arrangement of all or part of a set of objects. }}$
An ordered arrangement of distinct objects. Consider the number of ways of filling boxes with objects.
Theorem 2.3:
$\fbox{\parbox{5in}{ The number of permutation of $n$ objects is $n!$. }}$
Theorem 2.4:
$\fbox{\parbox{5in}{ The number of permutation (ways to arrange) of $n$\ distinct... ...gin{displaymath} _nP_r=n(n-1)\ldots(n-r+1)=\frac{n!}{(n-r)!} \end{displaymath}}}$
Example 2.17: In one year, three awards (research, teaching, and service) will be given for a class of 25 graduate students in a statistics department.
- If each student can receive at most one award, how many possible selections are there?
- Since the awards are distinguishable, it is a permutation problem.
- The number of sample points is $_{25}P_3=\frac{25!}{22!}$

Example 2.18: A president and a treasurer are to be chosen from a student club consisting of 50 people. How many different choices of officers are possible if
- there are no restrictions; $_{50}P_2=\frac{50!}{48!}=2450$
- will serve only if he is president;
  1. is selected as the president, which yields 49 possible outcomes; or
  2. Officers are selected from the remaining 49 people which has the number of choices $_{49}P_2$
  Therefore, the total number of choices is $49+_{49}P_2= 2401$ .
- and will serve together or not at all;
  1. The number of selections when and serve together is 2.
  2. The number of selections when both and are not chosen is $_{48}P_2$
  Therefore, the total number of choices in this situation is 2 + 2256 = 2258.
- and will not serve together; $2*48+2*48+_{48}P_2$
  1. The number of selections when serves as officer but not ,
  2. The number of selections when serves as officer but not
  3. The number of selections when both and are not chosen
  Therefore, the total number of choices is 2448. This problem also has another short solution: $_{50}P_2 -2$ (since and can only serve together in 2 ways).

Permutations are used when we are sampling without replacement and order matters.
Theorem 2.5:
$\fbox{\parbox{5in}{ The number of permutation of $n$\ objects arranged in a circle is $(n-1)!$ }}$
Permutations that occur by arranging objects in a circular are called circular permutations.
Two circular permutations are not considered different unless corresponding objects in the two arrangements are preceded or followed by a different objects as we proceed in a clockwise direction.

Theorem 2.6:
$\fbox{\parbox{5in}{ The number of distinct permutations of $n$ things of which ... ... kind is \begin{displaymath} \frac{n!}{n_1!n_2!\ldots n_k!} \end{displaymath}}}$
Example 2.19: In a college football training session, the defensive coordinator needs to have 10 players standing in a row.
- Among these 10 players, there are 1 freshman, 2 sophomores, 4 juniors, and 3 seniors, respectively.
- How many different ways can they be arranged in a row if only their class level will be distinguished?
  
  $\displaystyle \frac{10!}{1!2!3!4!}=12600$

Theorem 2.7:
$\fbox{\parbox{5in}{ The number of ways of partitioning a set of $n$ objects int... ...ots,n_r\\ \end{array}\right)=\frac{n!}{n_1!n_2!\ldots n_r!} \end{displaymath}}}$
The order of the elements within each cell is of no importance.
The intersection of any two cells is the empty set and the union of all cells gives the original set.
Example 2.22: How many different letter arrangements can be made from the letters in the word of STATISTICS?
We have total 10 letters, while letters S and T appear 3 times each, letter I appears twice, and letters A and C appear once each.

$\begin{displaymath} \left( \begin{array}{c} 10 \\ 3,3,2,1,1\\ \end{array}\right)=\frac{10!}{3!3!2!1!1!}=50400 \end{displaymath}$

Theorem 2.8:
$\fbox{\parbox{5in}{ The number of combinations (ways of choosing, \textbf{regard... ...ray}{c} n \\ r \\ \end{array}\right)=\frac{n!}{r!(n-r)!} \end{displaymath}}}$
We might want to select objects from without regard to order.
These selections are called combinations. Combinations are used when we are sampling without replacement and order does NOT matter.
A combination is a partition with two cells,
- the one containing objects selected
- the one containing the objects that are left
The number of such combinations,

$\begin{displaymath} \left( \begin{array}{c} n \\ r,n-r \\ \end{array}\right... ...rrow \left( \begin{array}{c} n \\ r \\ \end{array}\right) \end{displaymath}$

The number of permutations of distinct objects is .
The number of permutations of distinct objects taken at a time is

$\displaystyle P(n,r)=\frac{n!}{(n-r)!}$
The number of permutations of distinct objects arranged in a circle is

$\displaystyle \frac{n!}{n}=(n-1)!$
The number of permutations of things of which are of one kind, of a second kind, $\ldots$ , and of a $k^{th}$ kind is

$\displaystyle \frac{n!}{n_1!n_2!\ldots n_k!}$
The number of arrangements of partitioning a set of objects into cells with elements in the first cell, elements in the second, and so forth, is

$\begin{displaymath} \left( \begin{array}{c} n \\ n_1,n2_,\ldots ,n_r \\ \en... ...)=\frac{n!}{n_1!n_2!\ldots n_r!},(where n_1+n_2+\ldots +n_r=n) \end{displaymath}$
The number of combinations of distinct objects taken at a time is

$\begin{displaymath} C(n,r)=\left( \begin{array}{c} n \\ r \\ \end{array}\right)=\frac{n!}{r!(n-r)!} \end{displaymath}$

Cem Ozdogan 2012-02-15