Probability is a concept that is generally easy to understand intuitively, but can be difficult to define rigorously. When it is defined and studied carefully, it can lead to counter-intuitive results. Even elementary ideas of probability can be widely misunderstood, making it a good way to dishonestly bolster a weak argument.
When properly used, probability and its more "applied" cousin, statistics, can be powerful tools for discerning empirical truth. Indeed, essentially every field of modern science relies heavily on statistical analysis of data, which in turn relies on probability.
Definitions of probability
There are two main interpretations of probability, each of which leads to a different definition of probability:
- Relative frequency
- The long-run relative frequency of occurrence of a random event (the fraction of the time it happens in a long run of repeated "trials") can be defined as the probability of the event.
- Example: "A 'fair' coin has a 50% probability of coming up 'heads'."
- More information: Wikipedia:Frequency probability
- Degree of belief (a.k.a., personal probability)
- The degree to which one believes a statement to be true can be defined as the probability of that statement.
Although the degree-of-belief "definition" might seem quite weak, it can be made rigorous by carefully considering, for example, how much one would be willing to bet in a game where one would gain a certain amount of money if the statement turns out to be true. It can be shown that any internally consistent method of choosing one's wager must obey the laws of probability.
One of the most widely misunderstood concepts in probability has to do with conditional probability, the probability of one thing happening (or being true) given that something else definitely happens (or is true).
- Example: "The probability that a king has been drawn from a well-shuffled deck of playing cards given that you know it is a face card is one-third."
This is because once you know a face card has been drawn, 4 out of the 12 face cards are kings, giving a probability of 4/12, or 1/3.
Conditional probabilities are often the result of narrowing the population of interest. Consider the following two statements (using made-up figures):
- "10% of convicted criminals are atheists."
- "Only 5% of theists have ever been convicted of a crime."
Given this information, does it look like atheists are more likely to be criminals than theists? Maybe twice as likely? On first glance, it might seem so. However, notice that the two percentages treat criminal conviction quite differently. In the first statement, the population of interest is convicted criminals and we are looking at what fraction of that population are atheists. In the second statement, the population of interest is theists and we are looking at what fraction of that population have the characteristic of being convicted criminals. In other words, each percent is calculated as a fraction of a population having a certain characteristic, but neither the population nor the characteristic is the same in both statements. This means the figures are not directly comparable.
Now consider the additional statement:
- "90% of convicted criminals are theists."
You can compare this figure directly with statement #1 above, because they are using the same population: convicted criminals. But the comparison is not very informative because the two statements give exactly the same information (if 10% of criminals are atheists, then 90% must be non-atheists, or what we're calling "theists" for convenience sake). So we still don't know whether atheism or theism is associated with criminal conviction.
To get an accurate impression of what's going on, the question we really need to ask is:
- What percent of atheists are convicted criminals?
If we can answer that, then we can directly compare the probability of an atheist being a criminal with the probability of a theist being a criminal. Those probabilities (percents) will be calculated for two different populations (and thus need not add to 100%), but they will reflect the prevalence of the same characteristic in those two populations.
Unfortunately, we need one more piece of information to answer the latter question:
- What percent of the population are convicted criminals?
Actually, we can get the answer just as easily from knowing what percent are atheists or theists, but let's go with the above question. Anyway, the answer to this last question, which is also being pulled out of thin air for the purpose of this example, is:
- 3. "10% of the population are convicted criminals."
So here's a table that matches all the information we've been given. All percents are calculated out of the total population.
To be finished later...