Quantum Instrumentation Control Kit -- Defect Arbitrary Waveform
Generator (QICK-DAWG): A Quantum Sensing Control Framework for Quantum
Defects
- URL: http://arxiv.org/abs/2311.18253v1
- Date: Thu, 30 Nov 2023 05:03:40 GMT
- Title: Quantum Instrumentation Control Kit -- Defect Arbitrary Waveform
Generator (QICK-DAWG): A Quantum Sensing Control Framework for Quantum
Defects
- Authors: Emmeline G. Riendeau, Luca Basso, Jasmine J. Mah, Rong Cong, MA Sadi,
Jacob Henshaw, KM Azizur-Rahman, Aulden Jones, Gajadhar Joshi, Michael P.
Lilly, Andrew A. Mounce
- Abstract summary: We present a software and firmware extension to the Quantum Instrumentation Control Kit - Defect Arbitrary Waveform Generator (QICK-DAWG)
QICK-DAWG supports full quantum control and measurement of nitrogen-vacancy defects in diamond and other quantum defects using RFSoC FPGAs.
We demonstrate that QICK-DAWG is a powerful new paradigm of open source quantum hardware that significantly lowers the entry barrier and cost for quantum sensing.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Quantum information communication, sensing, and computation often require
complex and expensive instrumentation resulting in a large entry barrier. The
Quantum Instrumentation Control Kit (QICK) overcomes this barrier for
superconducting qubits with a collection of software and firmware for
state-of-the-art radio frequency system on chip (RFSoC's) field programmable
gate architecture (FPGA) chips. Here we present a software and firmware
extension to QICK, the Quantum Instrumentation Control Kit - Defect Arbitrary
Waveform Generator (QICK-DAWG), which is an open-source software and firmware
package that supports full quantum control and measurement of nitrogen-vacancy
defects in diamond and other quantum defects using RFSoC FPGAs. QICKDAWG
extends QICK to the characterization of nitrogen-vacancy defects and other
diamond quantum defects by implementing DC-1 GHz readout, AOM or gated laser
control, and analog or photon counting readout options. QICK-DAWG also adds
pulse sequence programs and data analysis scripts to collect and characterize
photoluminescence (PL) intensity, optically detected magnetic resonance (ODMR)
spectra, PL readout windows, Rabi oscillations, Ramsay interference spectra,
Hahn echo spin-spin relaxation times T$_2$, and spin-lattice relaxation times
T$_1$. We demonstrate that QICK-DAWG is a powerful new paradigm of open source
quantum hardware that significantly lowers the entry barrier and cost for
quantum sensing using quantum defects.
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