General and Specific Facets of Anxiety: Psychometric Analysis and Impact on Cognitive Performance

Anxiety is a multidimensional construct that influences cognitive performance in complex ways, yet its factor structure and domain-specific effects remain unclear. This study examined (1) the psychometric structure of general and specific anxiety measures, (2) their associations with cognitive performance across different domains, and (3) the predictive power of machine learning models in classifying cognitive performance based on specific anxiety in different domains. A two-stage design was employed: Stage 1 (N = 500) assessed self-reported anxiety (trait, state, generalized, social, spatial, and math anxiety) via questionnaires, while Stage 2 (N = 104) involved a set of experiments measuring cognitive performance (accuracy and reaction time) across numerical, social, spatial, and control tasks. As a result, factor analyses revealed a correlated yet distinct structure, with the best-fitting model treating anxiety measures in different domains as independent factors. Regression analyses also demonstrated domain-specific effects: trait anxiety improved emotion recognition and spatial reasoning but did not affect math or color processing. Machine learning models (Random Forest, Decision Trees, SVM) achieved modest but meaningful predictive accuracy, with ensemble methods outperforming linear models. Prediction of reaction time in cognitive tasks, based on anxiety measures, was less powerful, suggesting that non-anxiety factors play a larger role in cognitive performance. These findings highlight the importance of distinguishing between general and domain-specific anxieties in cognitive research and demonstrate the potential of a machine learning approach in modeling anxiety-performance relationships.