What Is Bayes' Theorem?
Bayes' Theorem, named after 18th-century British mathematician Thomas Bayes, is a mathematical formula for determining conditional probability. Conditional probability is the likelihood of an outcome occurring, based on a previous outcome having occurred in similar circumstances. Bayes' theorem provides a way to revise existing predictions or theories (update probabilities) given new or additional evidence.
In finance, Bayes' Theorem can be used to rate the risk of lending money to potential borrowers. The theorem is also called Bayes' Rule or Bayes' Law and is the foundation of the field of Bayesian statistics.
- Bayes' Theorem allows you to update the predicted probabilities of an event by incorporating new information.
- Bayes' Theorem was named after 18th-century mathematician Thomas Bayes.
- It is often employed in finance in calculating or updating risk evaluation.
- The theorem has become a useful element in the implementation of machine learning.
- The theorem was unused for two centuries because of the high volume of calculation capacity required to execute its transactions.
Understanding Bayes' Theorem
Applications of Bayes' Theorem are widespread and not limited to the financial realm. For example, Bayes' theorem can be used to determine the accuracy of medical test results by taking into consideration how likely any given person is to have a disease and the general accuracy of the test. Bayes' theorem relies on incorporating prior probability distributions in order to generate posterior probabilities.
Prior probability, in Bayesian statistical inference, is the probability of an event occurring before new data is collected. In other words, it represents the best rational assessment of the probability of a particular outcome based on current knowledge before an experiment is performed.
Posterior probability is the revised probability of an event occurring after taking into consideration the new information. Posterior probability is calculated by updating the prior probability using Bayes' theorem. In statistical terms, the posterior probability is the probability of event A occurring given that event B has occurred.
Bayes' Theorem thus gives the probability of an event based on new information that is, or may be, related to that event. The formula can also be used to determine how the probability of an event occurring may be affected by hypothetical new information, supposing the new information will turn out to be true.
For instance, consider drawing a single card from a complete deck of 52 cards.
The probability that the card is a king is four divided by 52, which equals 1/13 or approximately 7.69%. Remember that there are four kings in the deck. Now, suppose it is revealed that the selected card is a face card. The probability the selected card is a king, given it is a face card, is four divided by 12, or approximately 33.3%, as there are 12 face cards in a deck.
Formula for Bayes' Theorem
P(A∣B)=P(B)P(A⋂B)=P(B)P(A)⋅P(B∣A)where:P(A)= The probability of A occurringP(B)= The probability of B occurringP(A∣B)=The probability of A given BP(B∣A)= The probability of B given AP(A⋂B))= The probability of both A and B occurring
Examples of Bayes' Theorem
Below are two examples of Bayes' Theorem in which the first example shows how the formula can be derived in a stock investing example using Amazon.com Inc. (AMZN). The second example applies Bayes' theorem to pharmaceutical drug testing.
Deriving the Bayes' Theorem Formula
Bayes' Theorem follows simply from the axioms of conditional probability. Conditional probability is the probability of an event given that another event occurred. For example, a simple probability question may ask: "What is the probability of Amazon.com's stock price falling?" Conditional probability takes this question a step further by asking: "What is the probability of AMZN stock price falling given that the Dow Jones Industrial Average (DJIA) index fell earlier?"
The conditional probability of A given that B has happened can be expressed as:
If A is: "AMZN price falls" then P(AMZN) is the probability that AMZN falls; and B is: "DJIA is already down," and P(DJIA) is the probability that the DJIA fell; then the conditional probability expression reads as "the probability that AMZN drops given a DJIA decline is equal to the probability that AMZN price declines and DJIA declines over the probability of a decrease in the DJIA index.
P(AMZN|DJIA) = P(AMZN and DJIA) / P(DJIA)
P(AMZN and DJIA) is the probability of both A and B occurring. This is also the same as the probability of A occurring multiplied by the probability that B occurs given that A occurs, expressed as P(AMZN) x P(DJIA|AMZN). The fact that these two expressions are equal leads to Bayes' theorem, which is written as:
if, P(AMZN and DJIA) = P(AMZN) x P(DJIA|AMZN) = P(DJIA) x P(AMZN|DJIA)
then, P(AMZN|DJIA) = [P(AMZN) x P(DJIA|AMZN)] / P(DJIA).
Where P(AMZN) and P(DJIA) are the probabilities of Amazon and the Dow Jones falling, without regard to each other.
The formula explains the relationship between the probability of the hypothesis before seeing the evidence that P(AMZN), and the probability of the hypothesis after getting the evidence P(AMZN|DJIA), given a hypothesis for Amazon given evidence in the Dow.
Numerical Example of Bayes' Theorem
As a numerical example, imagine there is a drug test that is 98% accurate, meaning that 98% of the time, it shows a true positive result for someone using the drug, and 98% of the time, it shows a true negative result for nonusers of the drug.
Next, assume 0.5% of people use the drug. If a person selected at random tests positive for the drug, the following calculation can be made to determine the probability the person is actually a user of the drug.
(0.98 x 0.005) / [(0.98 x 0.005) + ((1 - 0.98) x (1 - 0.005))] = 0.0049 / (0.0049 + 0.0199) = 19.76%
Bayes' Theorem shows that even if a person tested positive in this scenario, there is a roughly 80% chance the person does not take the drug.
Frequently Asked Questions.
What Is the History of Bayes' Theorem?
The theorem was discovered among the papers of the English Presbyterian minister and mathematician Thomas Bayes and published posthumously by being read to the Royal Society in 1763. Long ignored in favor of Boolean calculations, Bayes' Theorem has recently become more popular due to increased calculation capacity for performing its complex calculations.
These advances have led to an increase in applications using Bayes' theorem. It is now applied to a wide variety of probability calculations, including financial calculations, genetics, drug use, and disease control.
What Does Bayes' Theorem State?
Bayes' Theorem states that the conditional probability of an event, based on the occurrence of another event, is equal to the likelihood of the second event given the first event multiplied by the probability of the first event.
What Is Calculated in Bayes' Theorem?
Bayes' Theorem calculates the conditional probability of an event, based on the values of specific related known probabilities.
What Is a Bayes' Theorem Calculator?
A Bayes’ Theorem Calculator figures the probability of an event A conditional on another event B, given the prior probabilities of A and B, and the probability of B conditional on A. It calculates conditional probabilities based on known probabilities.
How Is Bayes' Theorem Used in Machine Learning?
Bayes Theorem provides a useful method for thinking about the relationship between a data set and a probability. In other words, the theorem says that the probability of a given hypothesis being true based on specific observed data can be stated as finding the probability of observing the data given the hypothesis multiplied by the probability of the hypothesis being true regardless of the data, divided by the probability of observing the data regardless of the hypothesis.
The Bottom Line
At its simplest, Bayes' Theorem takes a test result and relates it to the conditional probability of that test result given other related events. For high probability false positives, the Theorem gives a more reasoned likelihood of a particular outcome.