A function of the form g(θ,x) and which returns a n \times q matrix with typical element g_i(θ,x_t) for i=1,...q and t=1,...,n. This matrix is then used to build the q sample moment conditions. It can also be a formula if the model is linear (see details below).

A k \times 1 vector of starting values. If the dimension of θ is one, see the argument "optfct". In the linear case, if tet0=NULL, the 2-step gmm estimator is used as starting value. However, it has to be provided when eqConst is not NULL

The matrix or vector of data from which the function g(θ,x) is computed. If "g" is a formula, it is an n \times Nh matrix of instruments (see details below).

A function of the form G(θ,x) which returns a q\times k matrix of derivatives of \bar{g}(θ) with respect to θ. By default, the numerical algorithm numericDeriv is used. It is of course strongly suggested to provide this function when it is possible. This gradiant is used compute the asymptotic covariance matrix of \hat{θ}. If "g" is a formula, the gradiant is not required (see the details below).

If set to TRUE, the moment function is smoothed as proposed by Kitamura(1997)

"EL" for empirical likelihood, "ET" for exponential tilting, "CUE" for continuous updated estimator, "ETEL" for exponentially tilted empirical likelihood of Schennach(2007), "HD" for Hellinger Distance of Kitamura-Otsu-Evdokimov (2013), and "ETHD" for the exponentially tilted Hellinger distance of Antoine-Dovonon (2015). "RCUE" is a restricted version of "CUE" in which the probabilities are bounded below by zero. In that case, an analytical Kuhn-Tucker method is used to find the solution.

type of kernel used to compute the covariance matrix of the vector of sample moment conditions (see kernHAC for more details) and to smooth the moment conditions if "smooth" is set to TRUE. Only two types of kernel are available. The truncated implies a Bartlett kernel for the HAC matrix and the Bartlett implies a Parzen kernel (see Smith 2004).

The method to compute the bandwidth parameter. By default it is bwAndrews which is proposed by Andrews (1991). The alternative is bwNeweyWest of Newey-West(1994).

logical or integer. Should the estimating functions be prewhitened? If TRUE or greater than 0 a VAR model of order as.integer(prewhite) is fitted via ar with method "ols" and demean = FALSE.

character. The method argument passed to ar for prewhitening.

a character specifying the approximation method if the bandwidth has to be chosen by bwAndrews.

numeric. Weights that exceed tol are used for computing the covariance matrix, all other weights are treated as 0.

Tolerance for λ between two iterations. The algorithm stops when \|λ_i -λ_{i-1}\| reaches tol_lamb (see getLamb)

The algorithm to compute λ stops if there is no convergence after "maxiterlam" iterations (see getLamb).

Tolerance for the gradiant of the objective function to compute λ (see getLamb).

Only when the dimension of θ is 1, you can choose between the algorithm optim or optimize. In that case, the former is unreliable. If optimize is chosen, "t0" must be 1\times 2 which represents the interval in which the algorithm seeks the solution.It is also possible to choose the nlminb algorithm. In that case, borns for the coefficients can be set by the options upper= and lower=.

If set to TRUE, the constraint optimization algorithm is used. See constrOptim to learn how it works. In particular, if you choose to use it, you need to provide "ui" and "ci" in order to impose the constraint ui θ - ci ≥q 0.

It is the tolerance for the moment condition ∑_{t=1}^n p_t g(θ(x_t)=0, where p_t=\frac{1}{n}Dρ(<g_t,λ>) is the implied probability. It adds a penalty if the solution diverges from its goal.

Algorithm used to solve for the lagrange multiplier in getLamb. The algorithm Wu is only for type="EL". The value of optlam is ignored for "CUE" because in that case, the analytical solution exists.

A data.frame or a matrix with column names (Optional).

Controls for the optimization of the vector of Lagrange multipliers used by either optim, nlminb or constrOptim

logicals. If TRUE the corresponding components of the fit (the model frame, the model matrix, the response) are returned if g is a formula.

The name of the class object created by the method getModel. It allows developers to extand the package and create other GEL methods.

Regularization coefficient for discrete CGEL estimation (experimental). By setting alpha to any value, the model is estimated by CGEL of type specified by the option type. See Chausse (2011)

Either a named vector (if "g" is a function), a simple vector for the nonlinear case indicating which of the θ_0 is restricted, or a qx2 vector defining equality constraints of the form θ_i=c_i. See gmm for an example.

If FALSE, the constrained coefficients are assumed to be fixed and only the covariance of the unconstrained coefficients is computed. If TRUE, the covariance matrix of the full set of coefficients is computed.

If TRUE, only the vector of coefficients and Lagrange multipliers are returned

More options to give to optim, optimize or constrOptim.

k\times 1 vector of parameters

the residuals, that is response minus fitted values if "g" is a formula.

the fitted mean values if "g" is a formula.

q \times 1 vector of Lagrange multipliers.

the covariance matrix of "coefficients"

the covariance matrix of "lambda"

The implied probabilities

the value of the objective function

Convergence code for "lambda" (see getLamb)

Convergence message for "lambda" (see getLamb)

Convergence code for "coefficients" (see optim, optimize or constrOptim)

the terms object used when g is a formula.

the matched call.

if requested, the response used (if "g" is a formula).

if requested, the model matrix used if "g" is a formula or the data if "g" is a function.

if requested (the default), the model frame used if "g" is a formula.