 The Unit-Root Revolution Revisited: Where Do Non-Standard Sampling Distributions and Related Conundrums Stem From?Spanos Aris ()
Journal of Time Series Econometrics, 2025, vol. 17, issue 2, 69-117 Abstract: The primary objective of the paper is twofold. First, to answer the question posed in the title by arguing that the conundrums: [C1] the non-standard sampling distributions, [C2] the low power of unit-root tests for α 1 ∈ [0.9, 1], and [C3] their size distortions, [C4] issues in handling Y 0, and [C5] the framing of H 0 and H 1 in testing α 1 = 1, as well as [C6] two competing parametrizations for the AR(1) models, (B) Y t = α 0 + α 1 Y t−1 + ɛ t , (C) Y t = α 0 + γt + α 1 Y t−1 + ɛ t , stem from viewing these models as aPriori Postulated (aPP) stochastic difference equations driven by the error process { ε t , t ∈ N ≔ ( 1,2 , … , n , … ) } $\left\{{\varepsilon }_{t}, t\in \mathbb{N}{:=}\left(1,2,\dots ,n,\dots \right)\right\}$ . Second, to use R.A. Fisher’s model-based statistical perspective to unveil the statistical models implicit in each of the AR(1): (B)-(C) models, specified entirely in terms of probabilistic assumptions assigned to the observable process { Y t , t ∈ N } $\left\{{Y}_{t}, t\in \mathbb{N}\right\}$ underlying the data y 0, which is all that matters for inference. The key culprit behind [C1]–[C6] is the presumption that the AR(1) nests the unit root [UR(1)] model when α 1 = 1, which is shown to belie Kolmogorov’s existence theorem as it relates to { Y t , t ∈ N } $\left\{{Y}_{t}, t\in \mathbb{N}\right\}$ . Fisher’s statistical perspective reveals that the statistical AR(1) and UR(1) models are grounded on (i) two distinct processes { Y t , t ∈ N } $\left\{{Y}_{t}, t\in \mathbb{N}\right\}$ , with (ii) different probabilistic assumptions and (iii) statistical parametrizations, (iv) rendering them non-nested, and (v) their respective likelihood-based inferential components are free from conundrums [C1]–[C6]. The claims (i)–(v) are affirmed by analytical derivations, simulations, as well as proposing a non-stationary AR(1) model that nests the related UR(1) model, where testing α 1 = 1 relies on likelihood-based tests free from conundrums [C1]–[C6]. Keywords: stochastic difference equations; Dickey-Fuller unit root testing; non-standard sampling distributions; Brownian motion process; statistical model and its adequacy; non-nested models (search for similar items in EconPapers) Downloads: (external link) Related works: Export reference: BibTeX RIS (EndNote, ProCite, RefMan) HTML/Text Persistent link: https://EconPapers.repec.org/RePEc:bpj:jtsmet:v:17:y:2025:i:2:p:69-117:n:1001 Ordering information: This journal article can be ordered from Access Statistics for this article Journal of Time Series Econometrics is currently edited by Javier Hidalgo More articles in Journal of Time Series Econometrics from De Gruyter |
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