Making the Decision: Comparing and Contrasting

Comparative Characteristics of Bayesian Methods

Bayesian analysis can have some advantages where the data do not provide much information with which to estimate parameters (namely due to the lack of prior information being included in frequentist analysis). One instance of this is when examining data with small sample sizes. Xie et al. address the small sample size question and compare the results from the Bayesian analysis to a frequentist analysis.¹¹³

The authors performed their comparison in the context of an ordered probit model.¹¹⁴ The authors find that when using the full sample of 76,994 observations, a Bayesian model with uninformative priors (i.e., p(θ) contains very little information and the data is relied upon to provide almost all of the information about θ) is almost identical to the frequentist model. A variety of other priors were fit to the entire sample and all models provided similar results to the frequentist model. The authors then examined the models on a subsample of 100 records. A frequentist model and a Bayesian model with an informative prior were fit to this small sample and compared to the full sample results. The Bayesian model with the informative prior provided results that were significantly closer to those observed on the entire sample.

This study reveals two important points regarding the use of Bayesian in an applied sense. First, Bayesian methods can provide real gains when examining small samples. While this may not be a relevant advantage given the current objective of modeling incursion severity across the many thousands of incursions-to-date, further rounds of research may wish to analyze small subsamples. Secondly, the advantages of Bayesian hinge upon the definition of the priors. Given an uninformative prior, the Bayesian results mimicked the frequentist results. Thus, when examining runway incursion severity, a relatively unexplored field with few prior beliefs about the impacts of variables, Bayesian methods may not provide a substantial advantage.

In addition to the beneficial small sample properties, Bayesian analysis is more theoretically pleasing. As an example, consider Griffiths et al; the authors compare Bayesian estimation with a variety of priors to the standard frequentist estimation results in the context of a probit model of mortgage types.¹¹⁵ In this case, the researchers used a truncated uniform prior distribution. That is, the authors had the prior belief that a coefficient is positive, and all positive values are equally likely. The mean and variance of the posterior distribution were similar to the results from the frequentist estimation. However, the Bayesian results were truncated at zero, whereas the frequentist results imply a distribution that normally distributed around the estimate, regardless of where it falls. For a variable that must be positive, this frequentist result may be incorrect. This may be especially true for variables with small effects, that is, for variables with estimated effects that are not very different from zero. The Bayesian estimates, by virtue of being truncated at zero, have a slightly different distribution – the mean and variance may be similar, but impossible values will have zero probability. Figure 67 demonstrates this graphically.

0

1

θ
Figure - Bayesian versus Frequentist Parameter Estimates

The red bar (top) displays a hypothetical Bayesian estimate. The width of the bar represents the distribution for the parameter estimated. Note that the bar is truncated at zero, indicating that the distribution of  does not extend past zero in that direction. The blue bar (bottom) represents the variance around a frequentist point estimate, . The variance can extend outside of the reasonable range for the parameter, in this case extending to negative values. Finally, note that the point estimate  is equal to the mean of the distribution of  (represented by a vertical line in the bar). This need not be the case in general.

This discrepancy – truncated versus unconstrained – extends to predicted probabilities, as well. The use of a probit model confines the frequentist point estimate of the probability to be between zero and one. However, there is some variance about that point which may include illegitimate values (probabilities outside the zero to one range).¹¹⁶ The predicted probabilities obtained from the Bayesian estimation were truncated at zero and one respectively, constraining results to be within the valid interval. Figure 68 provides a simplified graphical explanation of this phenomenon. Griffiths et al. note that this is not a result of using a truncated prior but rather to the differences in how estimations are generated for Bayesian and frequentist methods.¹¹⁷

P_f

P_b

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Figure - Bayesian versus Frequentist Probability Estimates

The ability to confine predicted probabilities to the appropriate bounded interval is advantageous. Additionally, if priors about the sign but not magnitude of a coefficient exist, Bayesian methods offer superior estimation results. However, as noted earlier, few if any priors exist in the runway incursion context.¹¹⁸ It is also unclear how useful predicted probabilities may be in this context. Regardless, Bayesian methods will likely provide results that are theoretically superior compared to the frequentist methods. The degree of superiority will however vary, and in some situations, can be quite small.

However, Bayesian methods are more difficult to implement than frequentist methods. First, inference about the effects of individual components of θ is difficult using the posterior distribution, leading to less clear policy direction. Further complicating matters is that p(θ|y) may not be written as a simple formula (i.e., there is no closed form for p(θ|y)). In these cases, simulation is required to deduce p(θ|y), requiring additional programming, computing resources, and time.

Comparative Characteristics of Frequentist Models

Frequentist methods also have advantages in terms of implementation. Many common statistical packages implement frequentist methods for the models under consideration. Though they may require significant computing power, the requirements are substantially less than those required by Bayesian methods with simulation. The availability of “canned” implementations of frequentist methods also allows different model specifications to be tested quickly. Conversely, a significant portion of resources would be dedicated to implementing Bayesian methods, restricting the focus to a single model with one or two sets of explanatory variables that, given the lack of informative priors for runway incursions, would likely return the same results as frequentist methods.

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