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18 results on '"Weiden, Mathias"'

1. High Precision Fault-Tolerant Quantum Circuit Synthesis by Diagonalization using Reinforcement Learning

Author

Weiden, Mathias, Kalloor, Justin, Younis, Ed, Kubiatowicz, John, and Iancu, Costin

Subjects
Quantum Physics
Abstract

Resource efficient and high precision compilation of programs into quantum circuits expressed in Fault-Tolerant gate sets, such as the Clifford+T gate set, is vital for the success of quantum computing. Optimal analytical compilation methods are known for restricted classes of unitaries, otherwise the problem is intractable. Empirical search-based synthesis methods, including Reinforcement Learning and simulated annealing, can generate good implementations for a more extensive set of unitaries, but require trade-offs in approximation precision and resource use. We leverage search-based methods to reduce the general unitary synthesis problem to one of synthesizing diagonal unitaries; a problem solvable efficiently in general and optimally in the single-qubit case. We demonstrate how our approach improves the implementation precision attainable by Fault-Tolerant synthesis algorithms on an array of unitaries taken from real quantum algorithms. On these benchmarks, many of which cannot be handled by existing approaches, we observe an average of 95% fewer resource-intensive non-Clifford gates compared to the more general Quantum Shannon Decomposition. On a subset of algorithms of interest for future term applications, diagonalization can reduce T gate counts by up to 16.8% compared to other methods., Comment: 22 pages, 11 figures

Published
2024

2. Quantum Hardware Roofline: Evaluating the Impact of Gate Expressivity on Quantum Processor Design

Author

Kalloor, Justin, Weiden, Mathias, Younis, Ed, Kubiatowicz, John, De Jong, Bert, and Iancu, Costin

Subjects
Quantum Physics, Computer Science - Hardware Architecture, Computer Science - Performance
Abstract

The design space of current quantum computers is expansive with no obvious winning solution. This leaves practitioners with a clear question: "What is the optimal system configuration to run an algorithm?". This paper explores hardware design trade-offs across NISQ systems to guide algorithm and hardware design choices. The evaluation is driven by algorithmic workloads and algorithm fidelity models which capture architectural features such as gate expressivity, fidelity, and crosstalk. We also argue that the criteria for gate design and selection should be extended from maximizing average fidelity to a more comprehensive approach that takes into account the gate expressivity with respect to algorithmic structures. We consider native entangling gates (CNOT, ECR, CZ, ZZ, XX, Sycamore, $\sqrt{\text{iSWAP}}$), proposed gates (B Gate, $\sqrt[4]{\text{CNOT}}$, $\sqrt[8]{\text{CNOT}}$), as well as parameterized gates (FSim, XY). Our methodology is driven by a custom synthesis driven circuit compilation workflow, which is able to produce minimal circuit representations for a given system configuration. By providing a method to evaluate the suitability of algorithms for hardware platforms, this work emphasizes the importance of hardware-software co-design for quantum computing.

Published
2024

3. Improving Quantum Circuit Synthesis with Machine Learning

Author

Weiden, Mathias, Younis, Ed, Kalloor, Justin, Kubiatowicz, John, and Iancu, Costin

Subjects
Quantum Physics, Computer Science - Machine Learning
Abstract

In the Noisy Intermediate Scale Quantum (NISQ) era, finding implementations of quantum algorithms that minimize the number of expensive and error prone multi-qubit gates is vital to ensure computations produce meaningful outputs. Unitary synthesis, the process of finding a quantum circuit that implements some target unitary matrix, is able to solve this problem optimally in many cases. However, current bottom-up unitary synthesis algorithms are limited by their exponentially growing run times. We show how applying machine learning to unitary datasets permits drastic speedups for synthesis algorithms. This paper presents QSeed, a seeded synthesis algorithm that employs a learned model to quickly propose resource efficient circuit implementations of unitaries. QSeed maintains low gate counts and offers a speedup of $3.7\times$ in synthesis time over the state of the art for a 64 qubit modular exponentiation circuit, a core component in Shor's factoring algorithm. QSeed's performance improvements also generalize to families of circuits not seen during the training process., Comment: 11 pages, 10 figures

Published
2023

4. Tackling the Qubit Mapping Problem with Permutation-Aware Synthesis

Author

Liu, Ji, Younis, Ed, Weiden, Mathias, Hovland, Paul, Kubiatowicz, John, and Iancu, Costin

Subjects
Quantum Physics, Computer Science - Emerging Technologies
Abstract

We propose a novel hierarchical qubit mapping and routing algorithm. First, a circuit is decomposed into blocks that span an identical number of qubits. In the second stage permutation-aware synthesis (PAS), each block is optimized and synthesized in isolation. In the third stage a permutation-aware mapping (PAM) algorithm maps the blocks to the target device based on the information from the second stage. Our approach is based on the following insights: (1) partitioning the circuit into blocks is beneficial for qubit mapping and routing; (2) with PAS, any block can implement an arbitrary input-output qubit mapping that reduces the gate count; and (3) with PAM, for two adjacent blocks we can select input-output permutations that optimize each block together with the amount of communication required at the block boundary. Whereas existing mapping algorithms preserve the original circuit structure and only introduce "minimal" communication via inserting SWAP or bridge gates, the PAS+PAM approach can additionally change the circuit structure and take full advantage of hardware-connectivity. Our experiments show that we can produce better-quality circuits than existing mapping algorithms or commercial compilers (Qiskit, TKET, BQSKit) with maximum optimization settings. For a combination of benchmarks we produce circuits shorter by up to 68% (18% on average) fewer gates than Qiskit, up to 36% (9% on average) fewer gates than TKET, and up to 67% (21% on average) fewer gates than BQSKit. Furthermore, the approach scales, and it can be seamlessly integrated into any quantum circuit compiler or optimization infrastructure., Comment: 12 pages, 9 figures, 5 tables

Published
2023

5. Wide Quantum Circuit Optimization with Topology Aware Synthesis

Author

Weiden, Mathias, Kalloor, Justin, Kubiatowicz, John, Younis, Ed, and Iancu, Costin

Subjects
Quantum Physics, Computer Science - Emerging Technologies
Abstract

Unitary synthesis is an optimization technique that can achieve optimal multi-qubit gate counts while mapping quantum circuits to restrictive qubit topologies. Because synthesis algorithms are limited in scalability by their exponentially growing run time and memory requirements, application to circuits wider than 5 qubits requires divide-and-conquer partitioning of circuits into smaller components. In this work, we will explore methods to reduce the depth (program run time) and multi-qubit gate instruction count of wide (16-100 qubit) mapped quantum circuits optimized with synthesis. Reducing circuit depth and gate count directly impacts program performance and the likelihood of successful execution for quantum circuits on parallel quantum machines. We present TopAS, a topology aware synthesis tool built with the \emph{BQSKit} framework that preconditions quantum circuits before mapping. Partitioned subcircuits are optimized and fitted to sparse qubit subtopologies in a way that balances the often opposing demands of synthesis and mapping algorithms. This technique can be used to reduce the depth and gate count of wide quantum circuits mapped to the sparse qubit topologies of Google and IBM. Compared to large scale synthesis algorithms which focus on optimizing quantum circuits after mapping, TopAS is able to reduce depth by an average of 35.2% and CNOT gate count an average of 11.5% when targeting a 2D mesh topology. When compared with traditional quantum compilers using peephole optimization and mapping algorithms from the Qiskit or $t|ket\rangle$ toolkits, our approach is able to provide significant improvements in performance, reducing CNOT counts by 30.3% and depth by 38.2% on average., Comment: 12 pages, 11 figures

Published
2022

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