Reinventing Akaike?s Wheel: model selection for quantum tomography
Abstract not provided.
Publications
How distinguishable are two quantum processes?
Abstract not provided.
Gate Set Tomography; Robust efficient and hyperaccurate characterization of quantum logic gates
Abstract not provided.
Microwave-driven coherent operation of a semiconductor quantum dot charge qubit
Nature Nanotechnology
An intuitive realization of a qubit is an electron charge at two well-defined positions of a double quantum dot. This qubit is simple and has the potential for high-speed operation because of its strong coupling to electric fields. However, charge noise also couples strongly to this qubit, resulting in rapid dephasing at all but one special operating point called the 'sweet spot'. In previous studies d.c. voltage pulses have been used to manipulate semiconductor charge qubits but did not achieve high-fidelity control, because d.c. gating requires excursions away from the sweet spot. Here, by using resonant a.c. microwave driving we achieve fast (greater than gigahertz) and universal single qubit rotations of a semiconductor charge qubit. The Z-axis rotations of the qubit are well protected at the sweet spot, and we demonstrate the same protection for rotations about arbitrary axes in the X-Y plane of the qubit Bloch sphere. We characterize the qubit operation using two tomographic approaches: standard process tomography and gate set tomography. Both methods consistently yield process fidelities greater than 86% with respect to a universal set of unitary single-qubit operations.
Gate Set Tomography on a Trapped Ion Qubit
Abstract not provided.
Fault Tolerance in Adiabatic Quantum Computing
Abstract not provided.
Robust quantum simulation for near-term realizable quantum hardware
Abstract not provided.
Hyper-Accurate Gate Set Tomography
Abstract not provided.
Quantum information processing in Sandia surface traps
Abstract not provided.
Quantum Information Processing in surface ion traps
Abstract not provided.
Lost in (Hilbert) Space - Model Selection for Quantum Tomography
Abstract not provided.
Controlling qubit drift by recycling error correction syndromes
Abstract not provided.
Hyper-accuracy and Error-Scaling in Gate Set Tomography
Abstract not provided.
Turbocharging Quantum Tomography
Quantum tomography is used to characterize quantum operations implemented in quantum information processing (QIP) hardware. Traditionally, state tomography has been used to characterize the quantum state prepared in an initialization procedure, while quantum process tomography is used to characterize dynamical operations on a QIP system. As such, tomography is critical to the development of QIP hardware (since it is necessary both for debugging and validating as-built devices, and its results are used to influence the next generation of devices). But tomography suffers from several critical drawbacks. In this report, we present new research that resolves several of these flaws. We describe a new form of tomography called gate set tomography (GST), which unifies state and process tomography, avoids prior methods critical reliance on precalibrated operations that are not generally available, and can achieve unprecedented accuracies. We report on theory and experimental development of adaptive tomography protocols that achieve far higher fidelity in state reconstruction than non-adaptive methods. Finally, we present a new theoretical and experimental analysis of process tomography on multispin systems, and demonstrate how to more effectively detect and characterize quantum noise using carefully tailored ensembles of input states.
Silicon Qubits By Design
Abstract not provided.
Hyperaccuracy and Error Scaling in Gate Set Tomography
Abstract not provided.
Gate Set Tomography
Abstract not provided.
Compressed optimization of device architectures
Recent advances in nanotechnology have enabled researchers to control individual quantum mechanical objects with unprecedented accuracy, opening the door for both quantum and extreme- scale conventional computation applications. As these devices become more complex, designing for facility of control becomes a daunting and computationally infeasible task. Here, motivated by ideas from compressed sensing, we introduce a protocol for the Compressed Optimization of Device Architectures (CODA). It leads naturally to a metric for benchmarking and optimizing device designs, as well as an automatic device control protocol that reduces the operational complexity required to achieve a particular output. Because this protocol is both experimentally and computationally efficient, it is readily extensible to large systems. For this paper, we demonstrate both the bench- marking and device control protocol components of CODA through examples of realistic simulations of electrostatic quantum dot devices, which are currently being developed experimentally for quantum computation.
Gate-set tomography: calibration-free full characterization of quantum devices using error-amplifying circuits
Abstract not provided.
Quantum Model Selection: How big is your system's Hilbert space?
Abstract not provided.
Gate Set Tomography (GST): Robust accurate full characterization of quantum logic gates
Abstract not provided.
Science and Engineering of Quantum Information Systems: Robust Devices and Operations
Abstract not provided.
Si/SiGe spin, charge, and hybrid qubits
Abstract not provided.
Quantum Graph Analysis and Gate Set Tomography
Abstract not provided.
"Implications of Analog Simulation for Computation and Complexity"
Abstract not provided.
Results 101–125 of 147