Abstract
SummaryMixed probit models are widely applied in many fields where prediction of a binary response is of interest. Typically, the random effects are assumed to be independent but this is seldom so for many real applications. In the credit risk application that is considered in the paper, random effects are present at the level of industrial sectors and they are expected to be correlated because of interfirm credit links inducing dependences in the firms’ risk to default. Unfortunately, existing inferential procedures for correlated mixed probit models are computationally very intensive already for a moderate number of effects. Borrowing from the literature on large network inference, we propose an efficient expectation–maximization algorithm for unconstrained and penalized likelihood estimation and derive the asymptotic standard errors of the estimates. An extensive simulation study shows that the approach proposed enjoys substantial computational gains relative to standard Monte Carlo approaches, while still providing accurate parameter estimates. Using data on nearly 64000 accounts for small and medium-sized enterprises in the UK in 2013 across 13 industrial sectors, we find that accounting for network effects via a correlated mixed probit model increases significantly the default prediction power of the model compared with conventional default prediction models, making efficient inferential procedures for these models particularly useful in this field.
Highlights
Discrete choice models with correlated group-specific random effects have wide applicability and practical importance in economics and the social sciences, as they can accommodate unobserved heterogeneity, overdispersion and intracluster as well as intercluster correlation across binary outcomes
We show how penalized inferential procedures can be applied under this framework, enabling us to cover the case where the number of random effects exceeds the number of observations
Using data on around 64000 accounts of unlisted small and medium-sized enterprises (SMEs) based in the UK and observed in the year 2013, we find that incorporating interfirm network dependences in the form of correlated random effects increases the default prediction power of the credit risk model compared with conventional models
Summary
Discrete choice models with correlated group-specific random effects have wide applicability and practical importance in economics and the social sciences, as they can accommodate unobserved heterogeneity, overdispersion and intracluster as well as intercluster correlation across binary outcomes. Using data on around 64000 accounts of unlisted small and medium-sized enterprises (SMEs) based in the UK and observed in the year 2013, we find that incorporating interfirm network dependences in the form of correlated random effects increases the default prediction power of the credit risk model compared with conventional models. For this reason, mixed discrete choice models have been widely adopted to predict firm financial distress for large corporations (see, among others, Jones and Hensher (2004) and Kukuk and Ronnberg (2013)), with few studies specific to SMEs (see, for example Alfo’ et al (2005)) From this literature and considering the importance of interfirm dependences discussed above, in this paper, we allow group effects to be correlated by assigning them a non-diagonal covariance matrix. We formalize the proposed mixed probit model with correlated random effects and describe an inferential procedure that is computationally efficient for data such as those described for which existing mixed probit models are prohibitively slow
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