Inference in Tightly Identified and Large-Scale Sign-Restricted SVARs
Markku Lanne, Jani Luoto, Adam Rybarczyk
TLDR
This paper introduces a novel reparameterization and HMC method for efficient inference in large-scale, sign-restricted structural VARs.
Key contributions
- Introduces a reparameterization for imposing diverse inequality restrictions in structural VARs.
- Enables continuously differentiable mappings for restrictions, compatible with Hamiltonian Monte Carlo.
- Facilitates rapid posterior density evaluation, improving inference in high-dimensional SVARs.
- Achieves lower serial dependence and faster computation than existing SVAR inference methods.
Why it matters
This paper significantly advances inference in complex structural VAR models by providing a more efficient and robust computational framework. It allows for a wider range of economically relevant restrictions, making SVARs more applicable to large-scale economic data. The method's improved performance makes high-dimensional SVAR analysis more practical.
Original Abstract
We propose a new approach to inference in tightly identified and large-scale structural vector autoregressions based on a reparameterization that enables imposing identifying inequality restrictions through continuously differentiable mappings. Permitted inequality restrictions include shape and ranking restrictions as well as bounds on economically relevant elasticities, and the approach is also able to accommodate zero restrictions in a straightforward manner. We implement a Hamiltonian Monte Carlo algorithm and show how the posterior density can be rapidly evaluated under the reparameterization, thus facilitating inference in high-dimensional settings. Two empirical applications demonstrate that our approach tends to result in lower serial dependence in Markov chains, larger effective sample sizes and reduced computation time relative to existing methods.
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