11: Quantile Regression

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Ruritanians enjoying Venkovský Park

In the previous chapters, we defined "best" by minimizing the sum of the squared residuals. An even function was required to ensure that the values in the target function were positive. In this chapter, we use the absolute value function.

While this may sound like a trivial move, it is not. Since the magnitude of the slope of the absolute value is constant, optimization is difficult. Furthermore, since it is undefined at its minimum, we can only use an iterative technique to estimate (approximate) our parameters of interest. However, in building this structure, we are able to go beyond just estimating the median, we can estimate any quantile. This allows us to model the tails of the data-generating process.

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Figure \(\PageIndex{1}\): A return to the line of best fit from Chapter 3: Intro to Linear Regression. The pink line above minimizes the sum of squared residuals. The turquoise line minimizes the sum of absolute residuals. Quite the difference!

In the previous sections we examined three types of least squares regressions — ordinary, weighted, and general. These three estimation methods have one thing in common: The estimates were obtained by minimizing the sum of squared residuals (properly weighted). We used the squaring function for two reasons. First, it is everywhere differentiable, especially at its minimum. Second, squaring the residuals ensures that you are adding non-negative values. All even functions attain the second goal. The class of functions that meet the first requirement is more restrictive.

The higher the even power, the more outliers affect the estimates; that is, the outliers will tend to have an increased effect on the estimator when the power is larger. One option to reduce the effect of these outliers is to use a different even function. The absolute value function has been used quite successfully in the past.

Unfortunately, the absolute value function is not everywhere differentiable. Even worse: it is not differentiable at its minimum — the point of interest. This means we cannot obtain a simple set of equations for our estimators. We can still, however, obtain estimators to an arbitrary degree of precision by using a set of equations that get us closer and closer to the true value of the estimate.

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