Rock the QASBA: Quantum Error Correction Acceleration via the Sparse Blossom Algorithm on FPGAs

Quantum computing is a new paradigm of computation that exploits principles from quantum mechanics to achieve an exponential speedup compared to classical logic. However, noise strongly limits current quantum hardware, reducing achievable performance and limiting the scaling of the applications. For this reason, current errors occurring in the computation and correct them in real time. Nevertheless, the high computational complexity of QEC algorithms is incompatible with the tight time constraints of quantum devices. Thus, hardware acceleration is paramount to achieving real-time QEC. This work presents QASBA, an FPGAbased hardware accelerator for the Sparse Blossom Algorithm (SBA), a state-of-the-art decoding algorithm. After profiling the state-of-the-art software counterpart, we developed a design methodology for hardware development based on the SBA. We also devised an automation process to help users without expertise in hardware design in deploying architectures based on QASBA. We implement QASBA on different FPGA architectures and experimentally evaluate resource usage, execution time, and energy efficiency of our solution. Our solution attains up to 25.05x speedup and 304.16x improvement in energy efficiency compared to the software baseline.