We propose a gradient-based simulated maximum likelihood estimation to estimate unknown parameters in a stochastic model without assuming that the likelihood function of the observations is available in closed form. A key element is to develop Monte Carlo-based estimators for the density and its derivatives for the output process, using only knowledge about the dynamics of the model. We present the theory of these estimators and demonstrate how our approach can handle various types of model structures. We also support our findings and illustrate the merits of our approach with numerical results
We present a computational approach to the method of moments using Monte Carlo simulation. Simple al...
Standard methods for maximum likelihood parameter estimation in latent variable models rely on the E...
Maximum likelihood estimation and likelihood ratio tests for nonlinear, non-Gaussian state-space mod...
This paper introduces a Monte Carlo method for maximum likelihood inference in the context of discre...
We present a sequential Monte Carlo (SMC) method for maximum likelihood (ML) parameter estimation in...
A method for estimating the parameters of stochastic differential equations (SDEs) by simulated maxi...
Nonlinear stochastic parametric models are widely used in various fields. However, for these models,...
A maximum likelihood methodology for the parameters of models with an intractable likelihood is intr...
We carry on an exploration of Lévy processes, focusing on instrumental definitions that ease our way...
State space models are considered for observations which have non-Gaussian distri-butions. We obtain...
Multilevel Monte Carlo is a novel method for reducing the computational cost when computing conditio...
The objective of the paper is to present a novel methodology for likelihood-based inference for disc...
The objective of this paper is parametric inference for stochastic volatility models. We consider a ...
We consider the problem of efficiently estimating gradients from stochastic simulation. Although the...
We present a sequential Monte Carlo (SMC) method for maximum likelihood (ML) parameter estimation i...
We present a computational approach to the method of moments using Monte Carlo simulation. Simple al...
Standard methods for maximum likelihood parameter estimation in latent variable models rely on the E...
Maximum likelihood estimation and likelihood ratio tests for nonlinear, non-Gaussian state-space mod...
This paper introduces a Monte Carlo method for maximum likelihood inference in the context of discre...
We present a sequential Monte Carlo (SMC) method for maximum likelihood (ML) parameter estimation in...
A method for estimating the parameters of stochastic differential equations (SDEs) by simulated maxi...
Nonlinear stochastic parametric models are widely used in various fields. However, for these models,...
A maximum likelihood methodology for the parameters of models with an intractable likelihood is intr...
We carry on an exploration of Lévy processes, focusing on instrumental definitions that ease our way...
State space models are considered for observations which have non-Gaussian distri-butions. We obtain...
Multilevel Monte Carlo is a novel method for reducing the computational cost when computing conditio...
The objective of the paper is to present a novel methodology for likelihood-based inference for disc...
The objective of this paper is parametric inference for stochastic volatility models. We consider a ...
We consider the problem of efficiently estimating gradients from stochastic simulation. Although the...
We present a sequential Monte Carlo (SMC) method for maximum likelihood (ML) parameter estimation i...
We present a computational approach to the method of moments using Monte Carlo simulation. Simple al...
Standard methods for maximum likelihood parameter estimation in latent variable models rely on the E...
Maximum likelihood estimation and likelihood ratio tests for nonlinear, non-Gaussian state-space mod...