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Your search keyword '"Durso-Sabina, Elijah"' showing total 6 results
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6 results on '"Durso-Sabina, Elijah"'

1. Genons, Double Covers and Fault-tolerant Clifford Gates

Author

Burton, Simon, Durso-Sabina, Elijah, and Brown, Natalie C.

Subjects
Quantum Physics
Abstract

A great deal of work has been done developing quantum codes with varying overhead and connectivity constraints. However, given the such an abundance of codes, there is a surprising shortage of fault-tolerant logical gates supported therein. We define a construction, such that given an input $[[n,k,d]]$ code, yields a $[[2n,2k,\ge d]]$ symplectic double code with naturally occurring fault-tolerant logical Clifford gates. As applied to 2-dimensional $D(\mathbb{Z}_2)$-topological codes with genons (twists) and domain walls, we find the symplectic double is genon free, and of possibly higher genus. Braiding of genons on the original code becomes Dehn twists on the symplectic double. Such topological operations are particularly suited for architectures with all-to-all connectivity, and we demonstrate this experimentally on Quantinuum's H1-1 trapped-ion quantum computer.

Published
2024

2. Entangling four logical qubits beyond break-even in a nonlocal code

Author

Hong, Yifan, Durso-Sabina, Elijah, Hayes, David, and Lucas, Andrew

Subjects
Quantum Physics
Abstract

Quantum error correction protects logical quantum information against environmental decoherence by encoding logical qubits into entangled states of physical qubits. One of the most important near-term challenges in building a scalable quantum computer is to reach the break-even point, where logical quantum circuits on error-corrected qubits achieve higher fidelity than equivalent circuits on uncorrected physical qubits. Using Quantinuum's H2 trapped-ion quantum processor, we encode the GHZ state in four logical qubits with fidelity $ 99.5 \pm 0.15 \% \le F \le 99.7 \pm 0.1\% $ (after postselecting on over 98% of outcomes). Using the same quantum processor, we can prepare an uncorrected GHZ state on four physical qubits with fidelity $97.8 \pm 0.2 \% \le F\le 98.7\pm 0.2\%$. The logical qubits are encoded in a $[\![ 25,4,3 ]\!]$ Tanner-transformed long-range-enhanced surface code. Logical entangling gates are implemented using simple swap operations. Our results are a first step towards realizing fault-tolerant quantum computation with logical qubits encoded in geometrically nonlocal quantum low-density parity check codes., Comment: 13 pages, 9 figures, 1 table. v2 changes: added classical simulation data and appendices

Published
2024

3. Benchmarking logical three-qubit quantum Fourier transform encoded in the Steane code on a trapped-ion quantum computer

Author

Mayer, Karl, Ryan-Anderson, Ciarán, Brown, Natalie, Durso-Sabina, Elijah, Baldwin, Charles H., Hayes, David, Dreiling, Joan M., Foltz, Cameron, Gaebler, John P., Gatterman, Thomas M., Gerber, Justin A., Gilmore, Kevin, Gresh, Dan, Hewitt, Nathan, Horst, Chandler V., Johansen, Jacob, Mengle, Tanner, Mills, Michael, Moses, Steven A., Siegfried, Peter E., Neyenhuis, Brian, Pino, Juan, and Stutz, Russell

Subjects
Quantum Physics
Abstract

We implement logically encoded three-qubit circuits for the quantum Fourier transform (QFT), using the [[7,1,3]] Steane code, and benchmark the circuits on the Quantinuum H2-1 trapped-ion quantum computer. The circuits require multiple logical two-qubit gates, which are implemented transversally, as well as logical non-Clifford single-qubit rotations, which are performed by non-fault-tolerant state preparation followed by a teleportation gadget. First, we benchmark individual logical components using randomized benchmarking for the logical two-qubit gate, and a Ramsey-type experiment for the logical $T$ gate. We then implement the full QFT circuit, using two different methods for performing a logical control-$T$, and benchmark the circuits by applying it to each basis state in a set of bases that is sufficient to lower bound the process fidelity. We compare the logical QFT benchmark results to predictions based on the logical component benchmarks.

Published
2024

4. Programming the full stack of an open-access quantum computer

Author

Frey, Virginia, Rademacher, Richard, Durso-Sabina, Elijah, Greenberg, Noah, Videnov, Nikolay, Day, Matthew L., Islam, Rajibul, and Senko, Crystal

Subjects
Quantum Physics
Abstract

We present a new quantum programming language called "Quala" that enables true full-stack programming of quantum hardware. Quala allows seamless integration of abstraction layers such as the digital circuit layer and the analog control pulse waveform layer. Additionally, the language supports user-issued low-level hardware instructions like FPGA actions. Mid-circuit measurements and branching decision logic support real-time, adaptive programs. This flexibility allows users to write code for everything from quantum error correction to analog quantum simulation. The combination of a user-facing calibration database and a powerful symbolic algebra framework provides users with an unprecedented level of expressiveness and transparency. We display the salient characteristics of the language structure and describe how the accompanying compiler can translate programs written in any abstraction layer into precisely timed hardware commands. We intend for this language to bridge the gap between circuit-level programming and physical operations on real hardware while maintaining full transparency in each level of the stack. This eliminates the need for "behind-the-scenes" compilation and provides users with insights into the day-to-day calibration routines., Comment: 12 pages, 3 figures. Comments welcome

Published
2021

5. Validation of Numerical Simulation Approach for Lightning Transient Analysis of a Transport Category Aircraft

Author

Weber, Cody, De Souza Mariano, José Antônio, Freire, Rodrigo Cabaleiro Cortizo, and Durso-Sabina, Elijah

Abstract

Lightning strikes to aircraft can cause physical damage to structures and components, but the lightning currents can also couple to electronics cables potentially upsetting or damaging critical electronics systems. Because the coupling of lightning currents to system electronics cables and boxes does not usually cause direct physical damage, it is known as indirect effects of lightning (IEL). The certification requirements of 14 CFR 25.1316, for electrical and electronic system lightning protection, ensure transport category aircraft electronic systems can function appropriately, depending on criticality, through the expected lightning environments for that system. One of the critical steps in the certification process is determining the lightning transient environment that will appear at equipment interface circuits for all identified systems requiring lightning assessment. The certification guidance material in AC 20-136B [1] identifies EM simulation as a possible means to establish the aircraft lightning transient environment. Complex analyses using computational electromagnetics (CEM) simulation software can determine aircraft actual transient levels (ATLs) in a manner that is similar to traditional full vehicle lightning transient analysis (LTA) tests. This paper reviews certification guidelines and presents a computer simulation approach to determine ATLs for a transport category airplane. The simulation ATL results were compared to the measured results from a traditional full vehicle LTA test to validate the simulation results. A proposed method for margin development is presented as well as an argument to evaluate the overall uncertainty in the verification process based on a combination of aircraft test and analysis.

Published
2022
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