Publications

Muller, Richard P.; Baczewski, Andrew D.; Blume-Kohout, Robin J.; Carroll, Malcolm; Gamble, John K.; Gao, Xujiao G.; Jacobson, Noah T.; Montano, Ines M.; Nielsen, Erik N.; Rudinger, Kenneth M.; Witzel, Wayne W.

Abstract not provided.

Muller, Richard P.; Aidun, John B.; Baczewski, Andrew D.; Gao, Xujiao G.; Metodi, Tzvetan S.; Mitchell, John A.; Sterk, Jonathan D.; Gamble, John K.; Blume-Kohout, Robin J.; Jacobson, Noah T.

Abstract not provided.

Lu, Tzu-Ming L.; Cederberg, Jeffrey G.; Lilly, Michael L.; Carroll, Malcolm; Bishop, Nathaniel B.; Tracy, Lisa A.; Blume-Kohout, Robin J.; Pluym, Tammy P.; Wendt, J.R.; Dominguez, Jason J.; Means, Joel L.; Kotula, Paul G.

Abstract not provided.

Lu, Tzu-Ming L.; Cederberg, Jeffrey G.; Lilly, Michael L.; Carroll, Malcolm; Bishop, Nathaniel B.; Tracy, Lisa A.; Blume-Kohout, Robin J.; Pluym, Tammy P.; Wendt, J.R.; Dominguez, Jason J.; Means, Joel L.; Kotula, Paul G.

Abstract not provided.

Lu, Tzu-Ming L.; Cederberg, Jeffrey G.; Lilly, Michael L.; Carroll, Malcolm; Bishop, Nathaniel B.; Tracy, Lisa A.; Blume-Kohout, Robin J.; Pluym, Tammy P.; Wendt, J.R.; Dominguez, Jason J.; Means, Joel L.; Kotula, Paul G.

Abstract not provided.

Rudinger, Kenneth M.; Hogle, Craig W.; Naik, Ravi N.; Hashim, Akel H.; Lobser, Daniel L.; Santiago, David S.; Grace, Matthew G.; Nielsen, Erik N.; Proctor, Timothy J.; Seritan, Stefan K.; Clark, Susan M.; Blume-Kohout, Robin J.; Siddiqi, Irfan S.; Young, Kevin C.

Abstract not provided.

Blume-Kohout, Robin J.

Abstract not provided.

Young, Kevin C.; Lobser, Daniel L.; Magann, Alicia B.; Blume-Kohout, Robin J.; Proctor, Timothy J.; Rudinger, Kenneth M.

Abstract not provided.

Blume-Kohout, Robin J.

Abstract not provided.

ACS Nano

Muller, Richard P.; Blume-Kohout, Robin J.

Quantum simulations promise to be one of the primary applications of quantum computers, should one be constructed. This article briefly summarizes the history of quantum simulation in light of the recent result of Wang and co-workers, demonstrating calculation of the ground and excited states for a HeH+ molecule, and concludes with a discussion of why this and other recent progress in the field suggest that quantum simulations of quantum chemistry have a bright future. (Figure Presented).

Blume-Kohout, Robin J.

Abstract not provided.

Frees, Adam F.; Gamble, John K.; Ward, Daniel R.; Blume-Kohout, Robin J.; Eriksson, M.A.E.; Friesen, Mark F.; Coppersmith, S.N.C.

Abstract not provided.

Blume-Kohout, Robin J.; Young, Kevin C.; Baczewski, Andrew D.

Abstract not provided.

Blume-Kohout, Robin J.; Gamble, John K.; Nielsen, Erik N.; Maunz, Peter L.; Scholten, Travis L.; Rudinger, Kenneth M.

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.

Blume-Kohout, Robin J.; Young, Kevin C.

Abstract not provided.

Nielsen, Erik N.; Proctor, Timothy J.; Rudinger, Kenneth M.; Young, Kevin C.; Blume-Kohout, Robin J.

Abstract not provided.

Proctor, Timothy J.; Rudinger, Kenneth M.; Young, Kevin C.; Sarovar, Mohan S.; Blume-Kohout, Robin J.

Abstract not provided.

Physical Review Letters

Proctor, Timothy J.; Rudinger, Kenneth M.; Young, Kevin; Sarovar, Mohan S.; Blume-Kohout, Robin J.

Randomized benchmarking (RB) is widely used to measure an error rate of a set of quantum gates, by performing random circuits that would do nothing if the gates were perfect. In the limit of no finite-sampling error, the exponential decay rate of the observable survival probabilities, versus circuit length, yields a single error metric r. For Clifford gates with arbitrary small errors described by process matrices, r was believed to reliably correspond to the mean, over all Clifford gates, of the average gate infidelity between the imperfect gates and their ideal counterparts. We show that this quantity is not a well-defined property of a physical gate set. It depends on the representations used for the imperfect and ideal gates, and the variant typically computed in the literature can differ from r by orders of magnitude. We present new theories of the RB decay that are accurate for all small errors describable by process matrices, and show that the RB decay curve is a simple exponential for all such errors. These theories allow explicit computation of the error rate that RB measures (r), but as far as we can tell it does not correspond to the infidelity of a physically allowed (completely positive) representation of the imperfect gates.

Proctor, Timothy J.; Rudinger, Kenneth M.; Young, Kevin C.; Sarovar, Mohan S.; Blume-Kohout, Robin J.

Abstract not provided.

Proposed for publication in New Journal of Physics.

Blume-Kohout, Robin J.

Abstract not provided.

Blume-Kohout, Robin J.

Abstract not provided.

Blume-Kohout, Robin J.

Abstract not provided.