# The nls() function in R

The hybrid New Keynesian Phillips Curve is:

$\pi_{t} = a \pi_{t-1} - b E_{t}\pi_{t+1} - cx_{t} + u_{t}$

After a few manipulations, we obtain the following estimable model:

$\pi_{t} = \frac{1}{b} \pi_{t-1} - \frac{a}{b}\pi_{t-2} - \frac{c}{b}x_{t-1} + \varepsilon _{t}$

where '$\pi$' is inflation rate and 'x' is a measure of output gap (= the cyclical component of GDP using the Hodrick-Prescott filter).The explanatory variables of the model '$\pi$' and 'x' are observable.

I am required to estimate this model using nonlinear least squares; however, this model looks linear to me. Also, my attempts to use the `nls()` function in R have failed.

Also, my research on nonlinear regression led me to logistic population growth, but I'm not able to find a way to relate what I learnt to this exercise, especially when it comes to deriving the starting values.

Any help will be appreciated. Thanks :)

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we need a little more information/context, and a reproducible example wouldn't hurt. In particular: are both pi and x observed, or just x? What would a typical data set look like? And why are you "required" to use nonlinear least squares -- is this homework? (Offhand, it looks like a state-space model to me -- e.g. check out the `dynlm` package) –  Ben Bolker Feb 22 '13 at 20:07
@BenBolker are there tools in the dynlm package for nonlinear regressions? I have been using it for linear regressions using time series data. And yes, pi and x are observable. And also yes, this is the last part of my homework. All the variables in the model were previously derived. –  SavedByJESUS Feb 22 '13 at 20:14
if (as your edited version says) `pi` and `x` are both observable, then this ought to be perfectly easily fitted with `lm()`. The one argument for `nls`-fitting would be as one way of getting the variables `a`, `b`, and `c` directly, rather than having to back-calculate them (and use something like the delta method to approximate their uncertainties). I would suggest that you (1) use `lm()` fit the model; (2) obtain starting values from the `nls` fit by back-calculating from those coefficients. If you want help on homework you will definitely have to show us what you've already tried ... –  Ben Bolker Feb 22 '13 at 20:18
Thank you very much @BenBolker –  SavedByJESUS Feb 22 '13 at 20:24
I meant of course "obtain starting values for the `nls` fit" above ... the simplest way to get lagged variables for the linear regression is to make copies and prepend `NA` values/trim end values appropriately, e.g. lag-1 of `x` = `c(NA,x[-length(x)])` –  Ben Bolker Feb 22 '13 at 21:14

Using ordinary least squares (OLS) with the `lm()` function to estimate equation (2) in the question would lead to the estimation of the coefficients $\frac{1}{b}$, $\frac{a}{b}$ and $\frac{c}{b}$.

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.

The `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 '$\pi$'

``````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 $\frac{1}{b}$, $\frac{a}{b}$ and $\frac{c}{b}$, 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'
``````

`A`, `B` and `C` are then used as the starting values in the `nls()` function

(ii) Use the `nls()` function

``````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:

``````summary(nlreg)
``````

Thanks to Ben Bolker for providing the insight :)

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