Let
This is the relative frequency interpretation of probability, which says that the probability of an event is equal to its relative frequency in a large number of trials.
When the weather forecaster tells us that tomorrow there is a 20% chance of rain, we understand that to mean that if we could repeat today's conditions—the air pressure, temperature, wind speed, etc.—over and over again, then 20% of the resulting “tomorrows” will result in rain. Closer to what weather forecasters actually do in coming up with that 20% number, together with using satellite and radar information along with sophisticated computational models, is to go back in the historical record and find other days that match up closely with today's conditions and see what proportion of those days resulted in rain on the following day.
There are definite limitations to constructing a rigorous mathematical theory out of this intuitive and empirical view of probability. One cannot actually repeat an experiment infinitely many times. To define probability carefully, we need to take a formal, axiomatic, mathematical approach. Nevertheless, the relative frequency viewpoint will still be useful in order to gain intuitive understanding. And by the end of the book, we will actually derive the relative frequency viewpoint as a consequence of the mathematical theory.
1.3 PROBABILITY FUNCTION
We assume for the next several chapters that the sample space is discrete. This means that the sample space is either finite or countably infinite.
A set is countably infinite if the elements of the set can be arranged as a sequence. The natural numbers
If the sample space is finite, it can be written as
The set of all real numbers is an infinite set that is not countably infinite. It is called uncountable. An interval of real numbers, such as (0,1), the numbers between 0 and 1, is also uncountable. Probability on uncountable spaces will require differential and integral calculus and will be discussed in the second half of this book.
A probability function assigns numbers between 0 and 1 to events according to three defining properties.
PROBABILITY FUNCTION
Given a random experiment with discrete sample space
1
2 (1.1)
3 For all events ,(1.2)
You may not be familiar with some of the notation in this definition. The symbol
In the case of a finite sample space
And in the case of a countably infinite sample space
In simple language, probabilities sum to 1. The third defining property of a probability function says that the probability of an event is the sum of the probabilities of all the outcomes contained in that event. We might describe a probability function with a table, function, graph, or qualitative description. Multiple representations are possible, as shown in the next example.
Example 1.5 A type of candy comes in red, yellow, orange, green, and purple colors. Choose a piece of candy at random. What color is it? The sample