Announcement

\begin{eqnarray}
\Delta y_{it} &=& \Delta x_{it}'\beta_1 + \Delta y_{i(t-1)} + \Delta \varepsilon_{it} \\
E\left( \Delta y_{i(t-1)} \Delta \varepsilon_{it} \right) &\neq & 0
\end{eqnarray}

\begin{eqnarray}
\Delta y_{it} &=& \Delta x_{it}'\beta_1 + \Delta y_{i(t-1)} + \Delta \varepsilon_{it} \\
E\left( \Delta y_{i(t-1)} \Delta \varepsilon_{it} \right) & \neq & 0
\end{eqnarray}

\begin{eqnarray}
\Delta y_{it} &=& \Delta x_{it}'\beta_1 + \Delta y_{i(t-1)} + \Delta \varepsilon_{it} \\
E\left( \Delta y_{i(t-1)} \Delta \varepsilon_{it} \right) & = & 0
\end{eqnarray}

\begin{equation}
\Delta \varepsilon_{it} = \Delat \nu_{it}
\end{equation}

But we are in trouble if:

\begin{equation}
\Delta \varepsilon_{it} = \Delta \nu_{it} + \Delta \nu_{i(t-1)}
\end{equation}

Hello Philipp,

Jorge Eduardo is correct in pointing out that you have a dynamic panel data model. You could use an Arellano-Bond xtabond specification or you could try using xtdpd which allows you to have different correlation structures for the unobserved time-invariant components of your model. Arellano-Bond is very popular but one has to be careful to verify that the assumptions of the model are satisfied. The documentation is a great source of information to get acquainted with the assumptions and the tests on this subject. That being said, I also want to provide answers to some frequently asked questions:

1. xtabond and xtdpd use GMM to estimate the parameters of the model. It is common for people to ask where the instruments are coming from and what the intuition behind them is. This is what I have to say:

The relationship of interest is given by:

\begin{equation}
y_{it} = x_{it}'\beta_1 + y_{i(t-1)}\beta_2 + \alpha_i + \varepsilon_{it}
\end{equation}

As in the conventional linear panel data model the time-invariant unobserved component is related to the regressors but the strategy of taking first differences does not work because of an endogeneity problem. In particular:

\begin{eqnarray}
\Delta y_{it} &=& \Delta x_{it}'\beta_1 + \Delta y_{i(t-1)} + \Delta \varepsilon_{it} \\
E\left( \Delta y_{i(t-1)} \Delta \varepsilon_{it} \right) &\neq & 0
\end{eqnarray}

The second equality above defines the endogeneity problem. The solution is instrumental variables. Which instrumental variables? Arellano-Bond suggest the second lags of the dependent variable and all the lags thereafter. This generates the set of moment conditions defined by:

\begin{eqnarray}
E\left( \Delta y_{i(t-2)} \Delta \varepsilon_{it} \right) &=& 0 \\
E\left( \Delta y_{i(t-3)} \Delta \varepsilon_{it} \right) &=& 0 \\
\ldots & &
\end{eqnarray}

If you have 6 time periods then your instrument set will look like :
\begin{eqnarray} t=6 & \quad y_{t-4}, y_{t-3}, y_{t-2}, y_{t-1} \\ t=5 & \quad y_{t-3}, y_{t-2}, y_{t-1} \\ t=4 & \quad y_{t-2}, y_{t-1} \\ t=3 & \quad y_{t-1} \end{eqnarray} Below I show an example with 9 periods which, following the logic above, should give you 28 lagged instruments.
2. How should I interpret my estat abond results ?

The key for the instrument set in Arellano-Bond to work is that

\begin{equation}
E\left( \Delta y_{i(t-j)} \Delta \varepsilon_{it} \right) = 0 \quad j \geq 2
\end{equation}

estat abond is testing these conditions. In essence, the differenced unobserved time-invariant component should be unrelated to the second lag of the dependent variable and the lags thereafter. If this is not the case, we are back to the initial problem, endogeneity. Essentially:

All is well if:

\begin{equation}
\Delta \varepsilon_{it} = \Delta \nu_{it}
\end{equation}

But we are in trouble if:

\begin{equation}
\Delta \varepsilon_{it} = \Delta \nu_{it} + \Delta \nu_{i(t-1)}
\end{equation}

If the latter case is true, then the second lag of the dependent variable will be related to the differenced time-varying component. This happens in general if the differenced time-varying unobserved component is serially correlated with an order greater than one. In the first equation above, the unobservable is serially correlated of order one but not serially correlated of orders 2 or beyond. Therefore, we are fine. This is what estat abond tests. For the example above:

We are golden. We reject no autocorrelation of order one and cannot reject no autocorrelation of order 2. If this were not the case, we would have to look for different instruments. This is what xtdpd does. The following example shows a case were the serial correlation structure of Arellano-Bond is not satisfied:

In this case we reject the no serial correlation for a second order of the differenced unobservables.

\begin{equation}
y = \beta_0 + \beta_1dm + \beta_2dt + \beta_3 dt \dot dm + \varepsilon
\end{equation}

\begin{equation}
y = \beta_0 + \beta_1dm + \beta_2dt + \beta_3 dt \times dm + \varepsilon
\end{equation}

\begin{equation}
y_t = x_t\beta
\end{equation}

Anne,

Using factor variable notation when you have a nonlinear model like probit is important to get the marginal effects you want. Suppose, the variable x1 is categorical variable with two values and when introducing it in your list of covariates instead of typing
you type
The marginal effect ( dydx(x1)) in the first case is

\begin{equation}
\Phi\left(\beta_0 + 1 + \beta_2x_2 \ldots \right) - \Phi\left(\beta_0 + 0 + \beta_2x_2 \ldots \right)
\end{equation}

In the second case it is given by:

\begin{equation}
\phi \left(\beta_0 + \beta_1x1 + \beta_2x_2 + \ldots \right)\beta_1
\end{equation}