Using ordinary least squares (OLS) with the
lm() function to estimate equation (2) in the question would lead to the estimation of the coefficients , and .
On the other hand, using nonlinear least squares with the
nls() function to estimate the equation would estimate values for the parameters 'a', 'b' and 'c', which are the parameters of interest.
nls() function (nonlinear least squares) in R has two important parameters: First, the
formula parameter and then the
start parameter. Running
?nls in R will provide some details; however, the gist is that the
formula parameter takes in the expression of the non-linear model one wants to estimate (e.g.
y ~ a / (b + c*x), where 'y' and 'x' are variables and 'a', 'b' and 'c' are the parameters of interest) and the
start parameter takes in starting values of the parameters of interest, which R will use in the iteration process (because nonlinear least squares basically iterates calculations until the best values for the parameters are obtained).
Below are the steps:
(i) Obtain the starting values of the parameters 'a', 'b' and 'c'
Here, I used the
lm() function to estimate the coefficient of equation (2). I started by creating lagged variables to use in the function.
NB: 'y' refers to ''
y_1 = c(NA, head(y, head(y, -1) # variable 'y' lagged by one time period
y_2 = c(c(NA, NA), head(y, head(y, -2) # variable 'y' lagged by two time periods
x_1 = c(NA, head(x, head(x, -1) # variable 'x' lagged by one time period
So, to estimate the coefficients of the equation, the following code was used:
reg = lm(y ~ y_1 + y_2 + x_1, na.action = na.exclude) # it is important to tell R to exclude the missing values (NA) that we included as we constructed the lagged variables
Now that we have estimates for , and , we can go ahead and calculate values for 'a', 'b' and 'c' in the following way:
B = 1 / reg$coefficients["y_1"] # Calculates the inverse of the coefficient on the variable 'y_1'
A = B * reg$coefficients["y_2"] # Multiplies 'b' by the coefficient on the variable 'y_2'
C = B * reg$coefficients["x_1"] # Multiplies 'b' by the coefficient on the variable 'x_1'
C are then used as the starting values in the
(ii) Use the
nlreg = nls(y ~ (1/b)*y_1 - (a/b)*y_2 - (c/b)*x_1,
start = list(a = A, b = B, c = C))
The results can be seen with the code:
Thanks to Ben Bolker for providing the insight :)