Perparameters (in all cases, a smaller number means more shrinkage): 1 , which controls the overall rate of shrinkage, 2 , which controls the rate of Anisomycin supplier shrinkage on the monthly predictors relative to the shrinkage on the lags of GDP growth, and 3 , which determines the rate of shrinkage that is associated with longer lags.Realtime NowcastingAt each forecast origin, the prior standard deviation that is associated with the coefficient on variable xi,j,t-l of Xm,t , where i denotes the indicator (employment, etc.), j denotes the month within the quarter at which the indicator has been sampled and l denotes the lag in quarters (whereas we consider a lag of only 1 in this paper, Carriero et al. (2013) included results for models with a lag of 2), is specified as follows: GDP 1 2 sdi,j,t-l = : .3/ i,j l3 For coefficients on lag l of GDP, the prior standard deviation is sdl = 1 =l3 : Finally, for the intercept, the prior is uninformative: sdint = 1000GDP : .5/ In setting these components of the prior, for GDP and i,j we use standard deviations from AR(4) models for GDP growth and xi,j,t estimated with the available sample of data. In all our results, the hyperparameters are set at values that may be considered very common in Minnesota-type priors (see, for example, Litterman (1986)): 1 = 0:2, 2 = 0:2 and 3 = 1. In Carriero et al. (2013), we ran some limited checks (for BMF models with different subsets of our 12 monthly indicators) to see what hyperparameter settings would be optimal in a realtime RMSE minimizing sense. To simplify the optimization, we focused on just 2 . In effect, the parameter 1 can be seen as pinning down the rate of shrinkage for the lags of GDP growth in the model, whereas, given 1 , 2 pins down the rate of shrinkage on the coefficients of the monthly indicators. Specifically, after simply fixing 1 at a conventional value of 0.2, we specified a wide grid of values for 2 and generated time series of forecasts for each corresponding model estimate (for a limited set of models). We then looked at choosing 2 in pseudorealtime to minimize the RMSE of past forecasts, using 5- or 10-year windows. For example, using a model with nine economic indicators and both current quarter and past quarter values of the indicators in the model, at the first evaluation point, in late 1989, the optimal 2 was 0.2. As forecasting moved forwards in time, the optimal setting drifted up a little and then down a little, before ending the sample at values as high as 1. For simplicity, in all the results in the paper, we leave 2 at 0.2 through all our analysis. It is possible that the more computationally intensive approach of optimizing shrinkage at each forecast origin could improve forecast accuracy but, in a VAR context, Carriero et al. (2014) found that the pay-off to optimization over fixed, conventional shrinkage was small. Finally, in the prior for the volatility-related components of the model, our approach is similar to that used in such studies as Clark (2011), Cogley and Sargent (2005) and Primiceri (2005). For the prior on , we use a mean of 0.035 and 5 degrees of RWJ 64809 supplier freedom. For the period 0 value of volatility of each equation i, we use a prior of ^ = log.0,OLS /, .6/ = 4: ^ To obtain log.0,OLS /, we use a training sample of 40 observations preceding the estimation sample to fit an AR(4) model to GDP growth. 3.4. Estimation algorithms The model with constant volatility is estimated with a Gibbs sampler, using the approach for the normal i.Perparameters (in all cases, a smaller number means more shrinkage): 1 , which controls the overall rate of shrinkage, 2 , which controls the rate of shrinkage on the monthly predictors relative to the shrinkage on the lags of GDP growth, and 3 , which determines the rate of shrinkage that is associated with longer lags.Realtime NowcastingAt each forecast origin, the prior standard deviation that is associated with the coefficient on variable xi,j,t-l of Xm,t , where i denotes the indicator (employment, etc.), j denotes the month within the quarter at which the indicator has been sampled and l denotes the lag in quarters (whereas we consider a lag of only 1 in this paper, Carriero et al. (2013) included results for models with a lag of 2), is specified as follows: GDP 1 2 sdi,j,t-l = : .3/ i,j l3 For coefficients on lag l of GDP, the prior standard deviation is sdl = 1 =l3 : Finally, for the intercept, the prior is uninformative: sdint = 1000GDP : .5/ In setting these components of the prior, for GDP and i,j we use standard deviations from AR(4) models for GDP growth and xi,j,t estimated with the available sample of data. In all our results, the hyperparameters are set at values that may be considered very common in Minnesota-type priors (see, for example, Litterman (1986)): 1 = 0:2, 2 = 0:2 and 3 = 1. In Carriero et al. (2013), we ran some limited checks (for BMF models with different subsets of our 12 monthly indicators) to see what hyperparameter settings would be optimal in a realtime RMSE minimizing sense. To simplify the optimization, we focused on just 2 . In effect, the parameter 1 can be seen as pinning down the rate of shrinkage for the lags of GDP growth in the model, whereas, given 1 , 2 pins down the rate of shrinkage on the coefficients of the monthly indicators. Specifically, after simply fixing 1 at a conventional value of 0.2, we specified a wide grid of values for 2 and generated time series of forecasts for each corresponding model estimate (for a limited set of models). We then looked at choosing 2 in pseudorealtime to minimize the RMSE of past forecasts, using 5- or 10-year windows. For example, using a model with nine economic indicators and both current quarter and past quarter values of the indicators in the model, at the first evaluation point, in late 1989, the optimal 2 was 0.2. As forecasting moved forwards in time, the optimal setting drifted up a little and then down a little, before ending the sample at values as high as 1. For simplicity, in all the results in the paper, we leave 2 at 0.2 through all our analysis. It is possible that the more computationally intensive approach of optimizing shrinkage at each forecast origin could improve forecast accuracy but, in a VAR context, Carriero et al. (2014) found that the pay-off to optimization over fixed, conventional shrinkage was small. Finally, in the prior for the volatility-related components of the model, our approach is similar to that used in such studies as Clark (2011), Cogley and Sargent (2005) and Primiceri (2005). For the prior on , we use a mean of 0.035 and 5 degrees of freedom. For the period 0 value of volatility of each equation i, we use a prior of ^ = log.0,OLS /, .6/ = 4: ^ To obtain log.0,OLS /, we use a training sample of 40 observations preceding the estimation sample to fit an AR(4) model to GDP growth. 3.4. Estimation algorithms The model with constant volatility is estimated with a Gibbs sampler, using the approach for the normal i.