Smolyak method for solving dynamic economic models: Lagrange interpolation, anisotropic grid and adaptive domain

Judd, Kenneth L.; Maliar, Lilia; Maliar, Serguei; Valero, Rafael Rodríguez

doi:10.1016/j.jedc.2014.03.003

Cited by 150 publications

(114 citation statements)

References 49 publications

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“…The model is solved for a minimum state variable solution using a projection method similar to Christiano and Fisher 2000and Judd, Maliar, Maliar, and Valero (2014), and the details of the method are provided in a Technical Appendix. 3 Because we are estimating the model, it might be tempting to use a computationally-efficient solution algorithm that respects the nonlinearity in the Taylor rule but log-linearizes the remaining equilibrium conditions.…”

Section: Model Solutionmentioning

confidence: 99%

The Empirical Implications of the Interest-Rate Lower Bound

Gust

Herbst

López‐Salido

et al. 2017

American Economic Review

165

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Using Bayesian methods, we estimate a nonlinear DSGE model in which the interest-rate lower bound is occasionally binding. We quantify the size and nature of disturbances that pushed the US economy to the lower bound in late 2008 as well as the contribution of the lower bound constraint to the resulting economic slump. We find that the interest-rate lower bound was a significant constraint on monetary policy that exacerbated the recession and inhibited the recovery, as our mean estimates imply that the zero lower bound (ZLB) accounted for about 30 percent of the sharp contraction in US GDP that occurred in 2009 and an even larger fraction of the slow recovery that followed. (JEL C11, C32, E12, E23, E32, E43, E52, G01)

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Section: Model Solutionmentioning

confidence: 99%

The Empirical Implications of the Interest-Rate Lower Bound

Gust

Herbst

López‐Salido

et al. 2017

American Economic Review

165

View full text Add to dashboard Cite

show abstract

“…To cope with the curse of dimensionality, as we know, the Smolyak sparse grid method [25] is an efficient method of integrating/interpolating multidimensional functions based on a univariate quadrature rule. This sparse grid method has been widely applied in various applications [26,27,28], including numerical integration [29], partial differential equations [30], economics [31,32], stochastic natural convection problems [33], sensitivity analysis [34], portfolio problems [35] and high dimensional interpolation [36].…”

Section: Introductionmentioning

confidence: 99%

Non-intrusive reduced order modelling of the Navier–Stokes equations

Xiao

Fang²,

Buchan³

et al. 2015

Computer Methods in Applied Mechanics and Engineering

134

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“…To solve for self-justied equlibria in general, we need to repeatedly approximate and interpolate multi-variate policy function on irregularly-shapedthat is, non-hypercubic domains. In such environments, standard grid-based methods such as Smolyak (see, e.g., Krueger and Kubler (2004) and Judd et al (2014)) or adaptive sparse grids (see, e.g., Brumm and Scheidegger (2017) and Brumm et al (2015)), will fail. To this end, we will follow closely Scheidegger and Bilionis (2017) and use Gaussian process regression (GPR) (see, e.g., Rasmussen and Williams (2005) and Sec.…”

Section: Function Approximation On High-dimensional and Irregularly-smentioning

confidence: 99%

Self-Justified Equilibria: Existence and Computation

Kübler

Scheidegger

2019

SSRN Journal

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In this paper we introduce "self-justified" equilibrium as a solution concept in stochastic general equilibrium models with a large number of heterogeneous agents. In each period agents trade in assets to maximize the sum of current utility and forecasted future utility. Current prices ensure that markets clear and agents forecast the probability distribution of future prices and consumption on the basis of current endogenous variables and the current exogenous shock. The forecasts are self-justfied in the sense that agents use forecasting functions that are optimal within a given class of functions and that can be viewed as optimally trading o˙the accuracy of the forecast and its complexity. We show that self-justified equilibria always exist and we develop a computational method to approximate them numerically. By restricting the complexity of agents' forecasts we can solve models with a very large number of heterogeneous agents. Errors can be directly interpreted.

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Smolyak method for solving dynamic economic models: Lagrange interpolation, anisotropic grid and adaptive domain

Cited by 150 publications

References 49 publications

The Empirical Implications of the Interest-Rate Lower Bound

The Empirical Implications of the Interest-Rate Lower Bound

Non-intrusive reduced order modelling of the Navier–Stokes equations

Self-Justified Equilibria: Existence and Computation

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