Abstract
The cerebellar granular layer plays a central role in sensory processing and pattern separation through its distinctive feedforward architecture. Here, we present a biologically realistic computational model of the granular layer designed to explore the functional impact of synaptic inhibition mediated by Golgi cells. The model integrates anatomical and physiological constraints to simulate realistic mossy fiber activity patterns, including spatial correlations and varying activation levels. We validate the model by replicating key findings from recent in vivo experiments, such as the role of inhibition in shaping granule cell responsiveness and the emergence of nonlinear suppression during multisensory integration. Beyond validation, the model provides a robust computational tool for studying how inhibition contributes to energy-efficient and noise-resilient sensory encoding. Mechanistic analyses revealed that moderate inhibition levels optimize pattern separation performance, with feedforward and feedback inhibitory circuits exerting distinct effects on coding expansion and decorrelation. All model code and simulation scripts are openly available, offering a framework for generating testable hypotheses and further investigating cerebellar computation and learning mechanisms in divergent feedforward networks.