New notions of tail and non-tail dependence are used to characterize separately extremal and non-extremal information, including tail log-exceedances and events, and tail-trimmed levels. We prove Near Epoch Dependence (McLeish 1975, Gallant and White 1988) and L0-Approximability (Pötscher and Prucha 1991) are equivalent for tail events and tail-trimmed levels, ensuring a Gaussian central limit theory for important extreme value and robust (tail-trimmed) statistics under general conditions of memory and heterogeneity. We apply the theory to characterize the extremal and non-extremal memory properties of possibly very heavy-tailed GARCH processes and distributed lags, including Asymmetric GARCH and Nonlinear Autoregressions. Finally, we prove asymptotic normality of tail index and tail dependence estimators, and a tail-trimmed sum of these persistent, heterogeneous heavy-tailed data resulting in some of the most general limit theory available in the extreme value and robust estimation literatures.

We develop a portmanteau test of extremal serial dependence. The test statistic is asymptotically chi-squared under a null of "extremal white noise", as long as extremes are Near-Epoch-Dependent, covering linear and nonlinear distributed lags, stochastic volatility, and GARCH processes with possibly unit or explosive roots. We apply tail specific tests to equity market and exchange rate returns.

We derive the exact joint tail shape of multivariate stochastic volatility processes with shocks that have a regularly varying distribution tail. Tail dependence is a function of linear volatility memory parametrically represented by tail scales, while tail power indices do not provide any relevant dependence information. Further, a linear function of tail events and exceedances is itself linearly independent, implying tail index inference is identical to the iid case. The results are also applied to non-parametric tail dependence estimation. Both applications hold for a large array of linear and nonlinear volatility data generating processes. 

Dependence between extreme values is predominantly measured by first assuming a parametric joint distribution function, and almost always for otherwise marginally iid processes. We develop semi-nonparametric and nonparametric measures, estimators and tests of bivariate tail dependence for non-iid data based on tail exceedances and events. The measures and estimators capture extremal dependence decay over time and can be re-scaled to provide robust estimators of canonical conditional tail probability and tail copula notions of tail dependence. Unlike extant offerings, the tests obtain asymptotic power of one against infinitessimal deviations from tail independence. Further, the estimators apply to dependent, heterogeneous processes with or without extremal dependence and irrespective of non-extremal properties and joint distribution specifications. Finally, we study the extremal associations within and between equity returns in the U.S., U.K. and Japan.

We develop a new nonparametric test of common values in first-price auctions with a binding reserve price. The test is based on the behavior of the CDF of bids near the reserve price. We show that this behavior is drastically different under private values (PV) and common values (CV). Next, we show that the problem of discriminating between PV and CV is equivalent to the problem of estimating the lower tail index of the bids distribution. Our approach allows for unobserved auction heterogeneity of an arbitrary form, and in particular doesn't require the number of potential bidders to be observable. Drawing on the existing and recent literature on tail index estimation, we characterize the B. Hill (1975) tail index estimator for panels with stochastic dimension and develop semi- and nonparametric estimators of the asymptotic variance for robust inference. We implement the test on a sample of British Columbia timber auctions and find strong support for CV.

We develop a new consistent conditional moment test of functional form based on nuisance parameter indexed sample moments. We reduce the nuisance parameter space to known countable sets, provide a new vantage into why existing parametric moment condition tests work, and uncover a new class of revealing weights. These results are exploited to construct a weighted average conditional moment test, where the weights are possibly stochastic in an arbitrary way, integer-indexed and flexible enough to cover a range of tests from Crámer-von Mises to Kolmogorov-Smirnov. Using a variety of weights the test statistic obtains power that nearly matches most powerful tests against a variety of alternatives.

Although robust estimation methods were formalized by the late 1800's, data trimming and truncation for non-iid data has received little attention. We establish sufficient conditions for weak laws of large numbers and Gaussian central limit theorems for tail-trimmed sums of dependent heterogeneous data, where the trimmed process itself satisfies a mixingale condition. The sum is self-normalized with a consistent kernel variance estimator for the central limit, so the rate of convergence, tail thickness and memory persistence do not need to be specified beyond fairly minimal regulatory conditions, hence robust inference is available. The theory applies to martingale differences, mixing, geometrically ergodic, and mixingale processes, including linear and nonlinear distributed lags, and linear and nonlinear random volatility. We show how the results imply asymptotic normality for a Tail Trimmed Least Squares estimator for models of infinite variance data.