Verified Implementation of GRAPE Pulse Optimization for Quantum Gates with Hardware-Representative Noise Models

Abstract: Gate fidelity in noisy intermediate-scale quantum (NISQ) computers remains the primary bottleneck limiting practical quantum computation, constrained by decoherence and control noise. Quantum optimal control (QOC) techniques, such as the gradient ascent pulse engineering (GRAPE) algorithm, offer a powerful approach to designing noise-robust pulses that actively mitigate these effects. However, most QOC implementations operate in idealized simulation environments that fail to capture the real-time parameter drift inherent to physical quantum hardware, creating a critical sim-to-real'' gap. In this work, I present QubitPulseOpt, an open-source, rigorously-tested Python framework designed to bridge this gap through hardware-representative optimal control. The framework demonstrates API connectivity to IQM's Garnet quantum processor (20-qubit superconducting device) and implements a workflow that constructs a high-fidelitydigital twin'' using hardware-representative parameters. Using this simulation framework, I demonstrate that GRAPE-optimized pulses achieve a simulated gate error reduction of 77$\times$ compared to standard Gaussian pulses. The framework's reliability is ensured through a 659-test verification suite (59\% code coverage) and adherence to NASA JPL Power-of-10 safety-critical coding standards, establishing a new paradigm for trustworthy quantum control software. All results are from verified GRAPE optimizations with full provenance documentation.