Stochastic equicontinuity

Let ${\displaystyle \{H_{n}(\theta ):n\geq 1\}}$  be a family of random functions defined from ${\displaystyle \Theta \rightarrow \mathbb {R} }$ , where ${\displaystyle \Theta }$  is any normed metric space. Here ${\displaystyle \{H_{n}(\theta )\}}$  might represent a sequence of estimators applied to datasets of size n, given that the data arises from a population for which the parameter indexing the statistical model for the data is θ. The randomness of the functions arises from the data generating process under which a set of observed data is considered to be a realisation of a probabilistic or statistical model. However, in ${\displaystyle \{H_{n}(\theta )\}}$ , θ relates to the model currently being postulated or fitted rather than to an underlying model which is supposed to represent the mechanism generating the data. Then ${\displaystyle \{H_{n}\}}$  is stochastically equicontinuous if, for every ${\displaystyle \epsilon >0}$  and ${\displaystyle \eta >0}$ , there is a ${\displaystyle \delta >0}$  such that:

${\displaystyle \limsup _{n\rightarrow \infty }\Pr \left(\sup _{\theta \in \Theta }\sup _{\theta '\in B(\theta ,\delta )}|H_{n}(\theta ')-H_{n}(\theta )|>\epsilon \right)<\eta .}$ 

Here B(θ, δ) represents a ball in the parameter space, centred at θ and whose radius depends on δ.

• M-Estimators: Stochastic equicontinuity is needed to prove the consistency and asymptotic normality of M-estimators.^[3]

 Example: Consider an M-estimator defined by minimizing a sample objective function ${\displaystyle Q_{n}(\theta )}$ . Stochastic equicontinuity helps in showing that ${\displaystyle Q_{n}(\theta )}$  converges uniformly to its population counterpart ${\displaystyle Q(\theta )}$ , ensuring that the estimator ${\displaystyle {\hat {\theta }}_{n}}$  converges to the true parameter ${\displaystyle \theta _{0}}$ .[3]

• Nonparametric Estimation: In nonparametric estimation, stochastic equicontinuity is needed in establishing the uniform convergence of nonparametric estimators. Like - kernel density estimators or spline regressions.^[4]

 Example: For a kernel density estimator ${\displaystyle {\hat {f}}_{n}(x)}$ , stochastic equicontinuity ensures that ${\displaystyle {\hat {f}}_{n}(x)}$  converges uniformly to the true density function ${\displaystyle f(x)}$  as the sample size ${\displaystyle n}$  increases.[4]

• Nonlinear Time Series Models: In nonlinear time series models, stochastic equicontinuity ensures the stability and consistency of estimators.

 Example: Consider a GARCH model used to model volatility in financial time series. Stochastic equicontinuity helps the estimated parameters of the GARCH model converge to the true parameters as the sample size increases, despite the model’s nonlinear nature.[5]

• Consistency of Estimators: Stochastic equicontinuity is a key condition for proving the consistency of estimators in time series models.

• Pollard, David (1984). "Stochastic Equicontinuity". Convergence of Stochastic Processes. New York: Springer. pp. 138–142. ISBN 0-387-90990-7.