Related papers: QSRA: A QPU Scheduling and Resource Allocation Approach for Cloud-Based Quantum Computing

QSRA: A QPU Scheduling and Resource Allocation Approach for Cloud-Based Quantum Computing

URL: http://arxiv.org/abs/2411.05283v1
Date: Fri, 08 Nov 2024 02:25:46 GMT
Title: QSRA: A QPU Scheduling and Resource Allocation Approach for Cloud-Based Quantum Computing
Authors: Binhan Lu, Zhaoyun Chen, Yuchun Wu,
Abstract summary: Quantum cloud platforms rely on Noisy Intermediate-Scale Quantum (NISQ) devices. This paper proposes a QPU Scheduling and Resource Allocation (QSRA) approach to address these challenges.
Score: 1.1481775081593757
License:
Abstract: Quantum cloud platforms, which rely on Noisy Intermediate-Scale Quantum (NISQ) devices, face significant challenges in efficiently managing quantum programs. This paper proposes a QPU Scheduling and Resource Allocation (QSRA) approach to address these challenges. QSRA enhances qubit utilization and reduces turnaround time by adapting CPU scheduling techniques to Quantum Processing Units (QPUs). It incorporates a subroutine for qubit allocation that takes into account qubit quality and connectivity, while also merging multiple quantum programs to further optimize qubit usage. Our evaluation of QSRA against existing methods demonstrates its effectiveness in improving both qubit utilization and turnaround time.

Related papers

Noise-Aware Distributed Quantum Approximate Optimization Algorithm on Near-term Quantum Hardware [2.753858051267023]
This paper introduces a noise-aware distributed Quantum Approximate Optimization Algorithm (QAOA) tailored for execution on near-term quantum hardware. We address the limitations of current Noisy Intermediate-Scale Quantum (NISQ) devices, which are hindered by limited qubit counts and high error rates.
arXiv Detail & Related papers (2024-07-24T14:50:01Z)
Benchmarking Quantum Annealers with Near-Optimal Minor-Embedded Instances [0.0]
This paper establishes a new protocol to generate graph instances with their associated near-optimal minor-embedding mappings to D-Wave Quantum Annealers. We use this method to benchmark QA on large instances of unconstrained and constrained optimization problems and compare the performance of the QPU with efficient classical solvers.
arXiv Detail & Related papers (2024-05-02T15:19:39Z)
On Reducing the Execution Latency of Superconducting Quantum Processors via Quantum Program Scheduling [48.142860424323395]
We introduce the Quantum Program Scheduling Problem (QPSP) to improve the utility efficiency of quantum resources. Specifically, a quantum program scheduling method concerning the circuit width, number of measurement shots, and submission time of quantum programs is proposed to reduce the execution latency.
arXiv Detail & Related papers (2024-04-11T16:12:01Z)
Elastic Entangled Pair and Qubit Resource Management in Quantum Cloud Computing [73.7522199491117]
Quantum cloud computing (QCC) offers a promising approach to efficiently provide quantum computing resources. The fluctuations in user demand and quantum circuit requirements are challenging for efficient resource provisioning. We propose a resource allocation model to provision quantum computing and networking resources.
arXiv Detail & Related papers (2023-07-25T00:38:46Z)
Matching Game for Optimized Association in Quantum Communication Networks [65.16483325184237]
This paper proposes a swap-stable request-QS association algorithm for quantum switches. It achieves a near-optimal (within 5%) performance in terms of the percentage of served requests. It is shown to be scalable and maintain its near-optimal performance even when the size of the QCN increases.
arXiv Detail & Related papers (2023-05-22T03:39:18Z)
Iterative Qubits Management for Quantum Index Searching in a Hybrid System [56.39703478198019]
IQuCS aims at index searching and counting in a quantum-classical hybrid system. We implement IQuCS with Qiskit and conduct intensive experiments. Results demonstrate that it reduces qubits consumption by up to 66.2%.
arXiv Detail & Related papers (2022-09-22T21:54:28Z)
Optimal Stochastic Resource Allocation for Distributed Quantum Computing [50.809738453571015]
We propose a resource allocation scheme for distributed quantum computing (DQC) based on programming to minimize the total deployment cost for quantum resources. The evaluation demonstrates the effectiveness and ability of the proposed scheme to balance the utilization of quantum computers and on-demand quantum computers.
arXiv Detail & Related papers (2022-09-16T02:37:32Z)
Simultaneous execution of quantum circuits on current and near-future NISQ systems [1.0312968200748118]
We introduce palloq (parallel allocation of QCs) for improving the performance of quantum multi-programming on NISQ processors. We also propose a software-based crosstalk detection protocol that efficiently and successfully characterizes the hardware's suitability for multi-programming.
arXiv Detail & Related papers (2021-12-14T01:18:49Z)
Quantum circuit architecture search for variational quantum algorithms [88.71725630554758]
We propose a resource and runtime efficient scheme termed quantum architecture search (QAS) QAS automatically seeks a near-optimal ansatz to balance benefits and side-effects brought by adding more noisy quantum gates. We implement QAS on both the numerical simulator and real quantum hardware, via the IBM cloud, to accomplish data classification and quantum chemistry tasks.
arXiv Detail & Related papers (2020-10-20T12:06:27Z)
SQUARE: Strategic Quantum Ancilla Reuse for Modular Quantum Programs via Cost-Effective Uncomputation [7.92565122267857]
We present a compilation infrastructure that tackles allocation and reclamation of scratch qubits (called ancilla) in quantum programs. At its core, SQUARE strategically performs uncomputation to create opportunities for qubit reuse. Our results show that SQUARE improves the average success rate of NISQ applications by 1.47X.
arXiv Detail & Related papers (2020-04-18T06:34:37Z)

This list is automatically generated from the titles and abstracts of the papers in this site.