EmuPlat: A Framework-Agnostic Platform for Quantum Hardware Emulation with Validated Transpiler-to-Pulse Pipeline
- URL: http://arxiv.org/abs/2509.12639v1
- Date: Tue, 16 Sep 2025 03:56:23 GMT
- Title: EmuPlat: A Framework-Agnostic Platform for Quantum Hardware Emulation with Validated Transpiler-to-Pulse Pipeline
- Authors: Jun Ye, Jun Yong Khoo,
- Abstract summary: EmuPlat is a framework-agnostic quantum hardware emulation platform.<n>It addresses the interoperability gap between high-level quantum programming frameworks and hardware-specific pulse control systems.<n>EmuPlat provides a unified infrastructure enabling seamless integration across diverse quantum computing ecosystems.
- Score: 2.0785699263580475
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: We present EmuPlat, a framework-agnostic quantum hardware emulation platform that addresses the interoperability gap between high-level quantum programming frameworks and hardware-specific pulse control systems. Unlike existing solutions that operate within isolated software stacks, EmuPlat provides a unified infrastructure enabling seamless integration across diverse quantum computing ecosystems, including CUDA-Q, Qiskit, and Qibolab. The platform implements a complete transpiler-compiler pipeline that systematically transforms abstract quantum circuits through four validated stages: (1) recursive gate decomposition to a minimal native set $\mathcal{G}_{\text{native}} = \{I, Z, RZ(\theta), \text{GPI2}(\phi), CZ, M\}$, (2) virtual Z optimization implementing phase tracking without physical pulses, (3) connectivity-aware routing with automated SWAP insertion, and (4) deterministic pulse compilation respecting hardware timing constraints. Our modular architecture, based on clean architecture principles with a novel adapter pattern, supports extensible integration of multiple quantum dynamics simulation engines while maintaining consistent interfaces. We demonstrate EmuPlat's capabilities through comprehensive benchmarks on superconducting transmon architectures: Bell state preparation achieves 99.958\% fidelity with hardware-calibrated noise models, while 4-qubit Quantum Fourier Transform implementations successfully demonstrate scalable circuit execution. The platform's production-ready implementation, validated through end-to-end testing with TransformationValidator, establishes EmuPlat as essential infrastructure for accelerating hybrid quantum-classical algorithm development and hardware-software co-design.
Related papers
- Benchmarking Distributed Quantum Computing Emulators [1.031136645551641]
Distributed quantum computing (DQC) addresses this challenge by interconnecting smaller quantum nodes through quantum communication protocols.<n>We introduce a benchmarking framework to evaluate DQC emulators.<n>We benchmark four representative emulators: Qiskit Aer, SquidASM, Interlin-q, and SQUANCH.
arXiv Detail & Related papers (2025-12-01T15:42:06Z) - Platform-Agnostic Modular Architecture for Quantum Benchmarking [1.0654458441169534]
We present a platform-agnostic modular architecture that addresses the increasingly fragmented landscape of quantum computing benchmarking.<n>We support over 20 benchmark variants ranging from simple tests like Bernstein-Vazirani to complex Hamiltonian simulation with observable calculations.<n>This architecture has been developed as a key enhancement to the continually evolving QED-C Application-Oriented Performance Benchmarks for Quantum Computing suite.
arXiv Detail & Related papers (2025-10-09T17:09:56Z) - Scaling Hybrid Quantum-HPC Applications with the Quantum Framework [2.9218462389567823]
Hybrid quantum-high performance computing is emerging as a key strategy for running quantum applications at scale.<n>We extend the Quantum Framework (QFw), a modular and HPC-aware orchestration layer, to integrate multiple local backends and a cloud-based quantum backend.<n>Using this integration, we execute a number of non-variational as well as variational workloads.
arXiv Detail & Related papers (2025-09-17T22:58:43Z) - Optimizing Inter-chip Coupler Link Placement for Modular and Chiplet Quantum Systems [8.766014028665984]
This project introduces InterPlace, a self-adaptive, hardware-aware framework for chip-to-chip distributed quantum systems.<n>InterPlace analyzes qubit noise and error rates to construct a virtual system topology.<n>It guides circuit partitioning and distributed qubit mapping to minimize SWAP overhead and enhance fidelity.
arXiv Detail & Related papers (2025-09-12T17:02:40Z) - The Munich Quantum Software Stack: Connecting End Users, Integrating Diverse Quantum Technologies, Accelerating HPC [5.146763143734571]
We introduce the Munich Quantum Software Stack (MQSS), a modular, open-source, community-driven ecosystem for hybrid quantum-classical applications.<n>MQSS's multi-layer architecture executes high-level applications on heterogeneous quantum back ends and coordinates their coupling with classical workloads.<n>Core elements include front-end adapters for popular frameworks and new programming approaches, an HPC-integrated scheduler, a powerful MLIR-based compiler, and a standardized hardware abstraction layer, the Quantum Device Management Interface (QDMI)
arXiv Detail & Related papers (2025-09-02T18:00:01Z) - Towards System-Level Quantum-Accelerator Integration [3.4486179803947254]
We propose a vertically integrated quantum systems architecture that treats quantum accelerators and processing units as peripheral system components.<n>A central element is the Quantum Abstraction Layer (QAL) at operating system kernel level.<n>We present first results towards such an integrated architecture, including a virtual QPU model based on QEMU.
arXiv Detail & Related papers (2025-07-25T12:30:42Z) - Low-Level and NUMA-Aware Optimization for High-Performance Quantum Simulation [0.6407952035735353]
We introduce an open-source, high-performance extension to the QuEST simulator that brings state-of-the-art low-level and NUMA computation optimizations to modern computers.<n>Experiments demonstrate significant speedups - 5.5-6.5x for single-qubit gate operations, 4.5x for two-qubit gates, 4x for Random Quantum Circuits (RQC), and 1.8x for Quantum Fourier Transform (QFT)
arXiv Detail & Related papers (2025-06-10T19:35:11Z) - Modular Compilation for Quantum Chiplet Architectures [0.8169527563677724]
Complexity of chiplet-based quantum devices, coupled with their growing size, presents an imminent scalability challenge for quantum compilation.<n>We propose SEQC, a hierarchical parallelized compilation pipeline optimized for chiplet-based quantum systems.
arXiv Detail & Related papers (2025-01-14T22:41:29Z) - AdaLog: Post-Training Quantization for Vision Transformers with Adaptive Logarithm Quantizer [54.713778961605115]
Vision Transformer (ViT) has become one of the most prevailing fundamental backbone networks in the computer vision community.
We propose a novel non-uniform quantizer, dubbed the Adaptive Logarithm AdaLog (AdaLog) quantizer.
arXiv Detail & Related papers (2024-07-17T18:38:48Z) - Cloud on-demand emulation of quantum dynamics with tensor networks [48.7576911714538]
We introduce a tensor network based emulator, simulating a programmable analog quantum processing unit (QPU)
The software package is fully integrated in a cloud platform providing a common interface for executing jobs on a HPC cluster as well as dispatching them to a QPU device.
arXiv Detail & Related papers (2023-02-10T14:08:05Z) - Tensor Network Quantum Virtual Machine for Simulating Quantum Circuits
at Exascale [57.84751206630535]
We present a modernized version of the Quantum Virtual Machine (TNQVM) which serves as a quantum circuit simulation backend in the e-scale ACCelerator (XACC) framework.
The new version is based on the general purpose, scalable network processing library, ExaTN, and provides multiple quantum circuit simulators.
By combining the portable XACC quantum processors and the scalable ExaTN backend we introduce an end-to-end virtual development environment which can scale from laptops to future exascale platforms.
arXiv Detail & Related papers (2021-04-21T13:26:42Z) - Extending C++ for Heterogeneous Quantum-Classical Computing [56.782064931823015]
qcor is a language extension to C++ and compiler implementation that enables heterogeneous quantum-classical programming, compilation, and execution in a single-source context.
Our work provides a first-of-its-kind C++ compiler enabling high-level quantum kernel (function) expression in a quantum-language manner.
arXiv Detail & Related papers (2020-10-08T12:49:07Z) - Extending XACC for Quantum Optimal Control [70.19683407682642]
Quantum computing vendors are beginning to open up application programming for direct pulse-level quantum control.
We present an extension to the XACC system-level quantum-classical software framework.
This extension enables the translation of digital quantum circuit representations to equivalent pulse sequences.
arXiv Detail & Related papers (2020-06-04T13:13:55Z) - Enabling Pulse-level Programming, Compilation, and Execution in XACC [78.8942067357231]
Gate-model quantum processing units (QPUs) are currently available from vendors over the cloud.
Digital quantum programming approaches exist to run low-depth circuits on physical hardware.
Vendors are beginning to open this pulse-level control system to the public via specified interfaces.
arXiv Detail & Related papers (2020-03-26T15:08:32Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.