Error exponents in hypothesis testing

In statistical hypothesis testing, the error exponent of a hypothesis testing procedure is the rate at which the probabilities of Type I and Type II decay exponentially with the size of the sample used in the test. For example, if the probability of error of a test decays as , where is the sample size, the error exponent is .

Formally, the error exponent of a test is defined as the limiting value of the ratio of the negative logarithm of the error probability to the sample size for large sample sizes: . Error exponents for different hypothesis tests are computed using Sanov's theorem and other results from large deviations theory.

Error exponents in binary hypothesis testing

Consider a binary hypothesis testing problem in which observations are modeled as independent and identically distributed random variables under each hypothesis. Let denote the observations. Let denote the probability density function of each observation under the null hypothesis and let denote the probability density function of each observation under the alternate hypothesis .

In this case there are two possible error events. Error of type 1, also called false positive, occurs when the null hypothesis is true and it is wrongly rejected. Error of type 2, also called false negative, occurs when the alternate hypothesis is true and null hypothesis is not rejected. The probability of type 1 error is denoted and the probability of type 2 error is denoted .

Optimal error exponent for Neyman–Pearson testing

In the Neyman–Pearson[1] version of binary hypothesis testing, one is interested in minimizing the probability of type 2 error subject to the constraint that the probability of type 1 error is less than or equal to a pre-specified level . In this setting, the optimal testing procedure is a likelihood-ratio test.[2] Furthermore, the optimal test guarantees that the type 2 error probability decays exponentially in the sample size according to .[3] The error exponent is the Kullback–Leibler divergence between the probability distributions of the observations under the two hypotheses. This exponent is also referred to as the Chernoff–Stein lemma exponent.

Optimal error exponent for average error probability in Bayesian hypothesis testing

In the Bayesian version of binary hypothesis testing one is interested in minimizing the average error probability under both hypothesis, assuming a prior probability of occurrence on each hypothesis. Let denote the prior probability of hypothesis . In this case the average error probability is given by . In this setting again a likelihood ratio test[4] is optimal and the optimal error decays as where represents the Chernoff-information between the two distributions defined as

gollark: How does *that* work?
gollark: Oh, you have a weirdly named macron to automatically write macrons for all OOP design principles?
gollark: BRB, implementing Macron then making an inheritance macron.
gollark: Actually, thanks to new numerical algorithms, the speed of convergence of the bees is substantially higher now.
gollark: According to apiophysics, infinitely many bees approach.

References

  1. Neyman, J.; Pearson, E. S. (1933), "On the problem of the most efficient tests of statistical hypotheses" (PDF), Philosophical Transactions of the Royal Society of London A, 231 (694–706): 289–337, Bibcode:1933RSPTA.231..289N, doi:10.1098/rsta.1933.0009, JSTOR 91247
  2. Lehmann, E. L.; Romano, Joseph P. (2005). Testing Statistical Hypotheses (3 ed.). New York: Springer. ISBN 978-0-387-98864-1.
  3. Cover, Thomas M.; Thomas, Joy A. (2006). Elements of Information Theory (2 ed.). New York: Wiley-Interscience.
  4. Poor, H. V. (2010). An Introduction to Signal Detection and Estimation (2 ed.). New York: Springer.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.