English

Reliability-Targeted Simulation of Item Response Data: Solving the Inverse Design Problem

Methodology 2026-01-14 v2 Computation

Abstract

Monte Carlo simulations are the primary methodology for evaluating Item Response Theory (IRT) methods, yet marginal reliability - the fundamental metric of data informativeness - is rarely treated as an explicit design factor. Unlike in multilevel modeling where the intraclass correlation (ICC) is routinely manipulated, IRT studies typically treat reliability as an incidental outcome, creating a "reliability omission" that obscures the signal-to-noise ratio of generated data. To address this gap, we introduce a principled framework for reliability-targeted simulation, transforming reliability from an implicit by-product into a precise input parameter. We formalize the inverse design problem, solving for a global discrimination scaling factor that uniquely achieves a pre-specified target reliability. Two complementary algorithms are proposed: Empirical Quadrature Calibration (EQC) for rapid, deterministic precision, and Stochastic Approximation Calibration (SAC) for rigorous stochastic estimation. A comprehensive validation study across 960 conditions demonstrates that EQC achieves essentially exact calibration, while SAC remains unbiased across non-normal latent distributions and empirical item pools. Furthermore, we clarify the theoretical distinction between average-information and error-variance-based reliability metrics, showing they require different calibration scales due to Jensen's inequality. An accompanying open-source R package, IRTsimrel, enables researchers to standardize reliability as a controlled experimental input.

Keywords

Cite

@article{arxiv.2512.16012,
  title  = {Reliability-Targeted Simulation of Item Response Data: Solving the Inverse Design Problem},
  author = {JoonHo Lee},
  journal= {arXiv preprint arXiv:2512.16012},
  year   = {2026}
}
R2 v1 2026-07-01T08:30:20.577Z