Case Study: a large physics-based simulation company achieves faster, high-accuracy structural impact simulation with BQP's HQCFM

how Hybrid Quantum-Classical Finite Methods enhance accuracy for structural Impact Analysis

The Large Physics-Based Simulation Company, a major physics-based simulation company, faced significant challenges with its classical solvers, which struggled with accuracy, efficiency, and scalability when running complex structural impact analyses for aerospace and defense applications. The computational complexity, non-linear dynamics, and mesh distortion often caused instability and excessive processing times, hindering large-scale simulation work.

To address this, BQP implemented its BQPhy Hybrid Quantum-Classical Finite Methods (HQCFM) service, leveraging a hybrid quantum-classical approach. This solution integrated quantum variational solvers with classical FEA to enhance parallelization, reduce computational overhead, and maintain solver stability. The results included a reduction in error rates to 10⁻³, stable performance in highly non-linear scenarios, and lower computational costs. This impact enables real-time, high-precision impact analysis for the customer, allowing for better design optimizations in critical engineering applications.