Architecting efficiency, performance, and scalability for quantum computers
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This thesis addresses the design of a quantum computer (QC) architecture. Quantum error correction is a dominant factor as it is required to protect quantum bits (qubits) from decoherence. However, error correction's costs are substantial and call for a scale-up of 100X more qubits and instruction-level parallelism (ILP) on the order of 10,000 simultaneous operations per cycle. These are daunting challenges for a QC architect, who must balance demands in performance, control efficiency, and scalability of design.
Error modeling is important for designing a QC so that error correction implementations and microarchitecture designs may be evaluated for effectiveness. This thesis presents a new deterministic approach to error modeling that is on the order of 1000X faster than previous Monte Carlo error models. While the deterministic error model is memory limited, it is capable of evaluating useful problems containing on the order of a dozen logical qubits encoded in the [[7,1,3]] quantum error correcting code (QECC).
This dissertation presents a new QC processor architecture that leverages highly mobile qubits found in some QC technologies such as electron-spins on liquid helium (eSHe). The processor architecture presented here is designed to efficiently handle at least an order of magnitude more ILP than previously proposed designs, and it accommodates increasing ILP with size and latency costs scaling only linearly. Compilers are also crucial to a computer's performance and efficiency, and this dissertation describes new compiler optimizations including one that reduces hardware requirements by 25% with no performance loss.
Multiple QC processors may be organized into a tiled configuration to provide sufficient ILP across the entire QC. This dissertation proposes a new distributed block tiling strategy that distributes encoded block qubits across arrays of data tiles and offloads non-critical path error correction routines to separate ancilla tiles. This strategy reduces tile capacity requirements by over 100X with the [[21,3,5]] QECC and achieves a simulated speedup of 2.8X for the eSHe QC when compared to the traditional tiling approach.
In summary, this dissertation presents a novel QC architecture and design tools that improve performance and scalability while making efficient use of both control and qubit resources.