Related papers: A Scalable Microarchitecture for Efficient Instruction-Driven Signal Synthesis and Coherent Qubit Control

A Scalable Microarchitecture for Efficient Instruction-Driven Signal Synthesis and Coherent Qubit Control

URL: http://arxiv.org/abs/2205.06851v1
Date: Fri, 13 May 2022 18:52:38 GMT
Title: A Scalable Microarchitecture for Efficient Instruction-Driven Signal Synthesis and Coherent Qubit Control
Authors: Nader Khammassi, Randy W. Morris, Shavindra Premaratne, Florian Luthi, Felix Borjans, Satoshi Suzuki, Robert Flory, Linda Patricia Osuna Ibarra, Lester Lampert, Anne Y. Matsuura
Abstract summary: Execution of quantum algorithms requires a quantum computer architecture with a dedicated quantum instruction set. We present a scalable qubit control system that enables efficient qubit control using a flexible ISA.
Score: 0.9175368456179858
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Execution of quantum algorithms requires a quantum computer architecture with a dedicated quantum instruction set that is capable of supporting translation of workloads into actual quantum operations acting on the qubits. State-of-the-art qubit control setups typically utilize general purpose test instruments such as arbitrary waveform generators (AWGs) to generate a limited set of waveforms or pulses. These waveforms are precomputed and stored prior to execution, and then used to produce control pulses during execution. Besides their prohibitive cost and limited scalability, such instruments suffer from poor programmability due to the absence of an instruction set architecture (ISA). Limited memory for pulse storage ultimately determines the total number of supported quantum operations. In this work, we present a scalable qubit control system that enables efficient qubit control using a flexible ISA to drive a direct digital synthesis (DDS) pipeline producing nanosecond-accurate qubit control signals dynamically. The designed qubit controller provides a higher density of control channels, a scalable design, better programmability, and lower cost compared to state-of-the-art systems. In this work, we discuss the new qubit controller's capabilities, its architecture and instruction set, and present experimental results for coherent qubit control.

Related papers

Number-operator-based inverse engineering technique in a two level system [0.0]
This paper experimentally realize a new method for shortcuts to adiabaticity, number operator based inverse engineering method (NOBIE), using quantum computers built with transmon qubits. Results show the robustness of the NOBIE method, even though it is tested for an effective Hamiltonian of a qubit irrespective of the interaction with other qubits and noise associated with the control pulses.
arXiv Detail & Related papers (2024-08-20T08:30:08Z)
Distributed Architecture for FPGA-based Superconducting Qubit Control [7.804530685405802]
Quantum circuits utilizing real time feedback techniques are a powerful tool for NISQ-era quantum computing. We have developed a custom FPGA-based processor architecture for QubiC, an open source platform for superconducting qubit control. We will detail the design of both the processor and compiler stack, and demonstrate its capabilities with a quantum state teleportation experiment.
arXiv Detail & Related papers (2024-04-23T17:47:31Z)
Pulse-controlled qubit in semiconductor double quantum dots [57.916342809977785]
We present a numerically-optimized multipulse framework for the quantum control of a single-electron charge qubit. A novel control scheme manipulates the qubit adiabatically, while also retaining high speed and ability to perform a general single-qubit rotation.
arXiv Detail & Related papers (2023-03-08T19:00:02Z)
Two qubits in one transmon -- QEC without ancilla hardware [68.8204255655161]
We show that it is theoretically possible to use higher energy levels for storing and controlling two qubits within a superconducting transmon. The additional qubits could be used in algorithms which need many short-living qubits in error correction or by embedding effecitve higher connectivity in qubit networks.
arXiv Detail & Related papers (2023-02-28T16:18:00Z)
Graph test of controllability in qubit arrays: A systematic way to determine the minimum number of external controls [62.997667081978825]
We show how to leverage an alternative approach, based on a graph representation of the Hamiltonian, to determine controllability of arrays of coupled qubits. We find that the number of controls can be reduced from five to one for complex qubit-qubit couplings.
arXiv Detail & Related papers (2022-12-09T12:59:44Z)
Baseband control of superconducting qubits with shared microwave drives [11.673889645599697]
We explore theoretically the possibility of baseband flux control of superconducting qubits with only shared and always-on microwave drives. In our strategy, qubits are tuned on resonance with the drive and single-qubit gates can be realized. We expect that baseband control with shared microwave drives can help build large-scale superconducting quantum processors.
arXiv Detail & Related papers (2022-11-13T06:42:15Z)
SQ-CARS: A Scalable Quantum Control and Readout System [1.304268238836389]
SQ-CARS is a system based on the ZCU111 evaluation kit to control and measure superconducting qubits. The system offers an interactive Python framework, making it user-friendly. It also features on-board data processing like tunable low pass filters and rotation blocks, enabling lock-in detection and low-latency active feedback for quantum experiments.
arXiv Detail & Related papers (2022-03-03T05:33:11Z)
Pulse-level noisy quantum circuits with QuTiP [53.356579534933765]
We introduce new tools in qutip-qip, QuTiP's quantum information processing package. These tools simulate quantum circuits at the pulse level, leveraging QuTiP's quantum dynamics solvers and control optimization features. We show how quantum circuits can be compiled on simulated processors, with control pulses acting on a target Hamiltonian.
arXiv Detail & Related papers (2021-05-20T17:06:52Z)
QubiC: An open source FPGA-based control and measurement system for superconducting quantum information processors [5.310385728746101]
We design a modular FPGA based system called QubiC to control and measure a superconducting quantum processing unit. A prototype hardware module is assembled from several commercial off-the-shelf evaluation boards and in-house developed circuit boards. System functionality and performance are demonstrated by performing qubit chip characterization, gate optimization, and randomized benchmarking sequences.
arXiv Detail & Related papers (2020-12-31T21:06:28Z)
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.