Your search keyword '"Gu, Mile"' showing total 6 results

1. Fundamental limits of quantum error mitigation.

Author

Takagi, Ryuji, Endo, Suguru, Minagawa, Shintaro, and Gu, Mile

Subjects

CIRCUIT complexity, ERROR functions, SAMPLING errors, QUBITS

Abstract

The inevitable accumulation of errors in near-future quantum devices represents a key obstacle in delivering practical quantum advantages, motivating the development of various quantum error-mitigation methods. Here, we derive fundamental bounds concerning how error-mitigation algorithms can reduce the computation error as a function of their sampling overhead. Our bounds place universal performance limits on a general error-mitigation protocol class. We use them to show (1) that the sampling overhead that ensures a certain computational accuracy for mitigating local depolarizing noise in layered circuits scales exponentially with the circuit depth for general error-mitigation protocols and (2) the optimality of probabilistic error cancellation among a wide class of strategies in mitigating the local dephasing noise on an arbitrary number of qubits. Our results provide a means to identify when a given quantum error-mitigation strategy is optimal and when there is potential room for improvement. [ABSTRACT FROM AUTHOR]

Published

2022

2. Single ion qubit with estimated coherence time exceeding one hour.

Author

Wang, Pengfei, Luan, Chun-Yang, Qiao, Mu, Um, Mark, Zhang, Junhua, Wang, Ye, Yuan, Xiao, Gu, Mile, Zhang, Jingning, and Kim, Kihwan

Subjects

QUBITS, QUANTUM coherence, QUANTUM information science, DECOHERENCE (Quantum mechanics), QUANTUM theory, DECAY constants

Abstract

Realizing a long coherence time quantum memory is a major challenge of current quantum technology. Until now, the longest coherence-time of a single qubit was reported as 660 s in a single 171Yb+ ion-qubit through the technical developments of sympathetic cooling and dynamical decoupling pulses, which addressed heating-induced detection inefficiency and magnetic field fluctuations. However, it was not clear what prohibited further enhancement. Here, we identify and suppress the limiting factors, which are the remaining magnetic-field fluctuations, frequency instability and leakage of the microwave reference-oscillator. Then, we observe the coherence time of around 5500 s for the 171Yb+ ion-qubit, which is the time constant of the exponential decay fit from the measurements up to 960 s. We also systematically study the decoherence process of the quantum memory by using quantum process tomography and analyze the results by applying recently developed resource theories of quantum memory and coherence. Our experimental demonstration will accelerate practical applications of quantum memories for various quantum information processing, especially in the noisy-intermediate-scale quantum regime. Extending qubit coherence times represent one of the key challenges for quantum technologies. Here, after properly suppressing magnetic-field fluctuations, frequency instability and leakage of the microwave reference-oscillator, the authors infer coherence times of 5500 s for an Yb ion qubit. [ABSTRACT FROM AUTHOR]

Published

2021

3. COHERENT AND INCOHERENT CONTENTS OF CORRELATIONS.

Author

MODI, KAVAN and GU, MILE

Subjects

*COHERENCE (Physics), *STATISTICAL correlation, *SET theory, *QUANTUM theory, *QUANTUM entanglement, *DISTRIBUTION (Probability theory), *QUBITS

Abstract

We examine bipartite and multipartite correlations within the construct of unitary orbits. We show that the set of product states is a very small subset of set of all possible states, while all unitary orbits contain classically correlated states. Using this we give meaning to degeneration of quantum correlations due to a unitary interactions, which we call coherent correlations. The remaining classical correlations are called incoherent correlations and quantified in terms of the distance of the joint probability distributions to its marginals. Finally, we look at how entanglement looks in this picture for the two-qubit case. [ABSTRACT FROM AUTHOR]

Published

2013

4. A classical algorithm to mimic quantum decisions.

Author

Gu, Mile

Subjects

*ALGORITHMS, *QUBITS, *QUANTUM computing, *PHOTON counting, *BEAM splitters, *QUANTUM computers

Published

2019

5. Witnessing Quantum Resource Conversion within Deterministic Quantum Computation Using One Pure Superconducting Qubit.

Author

Wang, W., Han, J., Yadin, B., Ma, Y., Ma, J., Cai, W., Xu, Y., Hu, L., Wang, H., Song, Y. P., Gu, Mile, and Sun, L.

Subjects

*SUPERCONDUCTING circuits, *QUANTUM computing, *QUANTUM theory, *QUBITS

Abstract

Deterministic quantum computation with one qubit (DQC1) is iconic in highlighting that exponential quantum speedup may be achieved with negligible entanglement. Its discovery catalyzed a heated study of general quantum resources, and various conjectures regarding their role in DQC1's performance advantage. Coherence and discord are prominent candidates, respectively, characterizing nonclassicality within localized and correlated systems. Here we realize DQC1 within a superconducting system, engineered such that the dynamics of coherence and discord can be tracked throughout its execution. We experimentally confirm that DQC1 acts as a resource converter, consuming coherence to generate discord during its operation. Our results highlight superconducting circuits as a promising platform for both realizing DQC1 and related algorithms, and experimentally characterizing resource dynamics within quantum protocols. [ABSTRACT FROM AUTHOR]

Published

2019

6. Power of one qumode for quantum computation.

Author

Liu, Nana, Thompson, Jayne, Weedbrook, Christian, Lloyd, Seth, Vedral, Vlatko, Gu, Mile, and Modi, Kavan

Subjects

*QUANTUM computing, *QUBITS, *QUANTUM computers

Abstract

Although quantum computers are capable of solving problems like factoring exponentially faster than the best-known classical algorithms, determining the resources responsible for their computational power remains unclear. An important class of problems where quantum computers possess an advantage is phase estimation, which includes applications like factoring. We introduce a computational model based on a single squeezed state resource that can perform phase estimation, which we call the power of one qumode. This model is inspired by an interesting computational model known as deterministic quantum computing with one quantum bit (DQC1). Using the power of one qumode, we identify that the amount of squeezing is sufficient to quantify the resource requirements of different computational problems based on phase estimation. In particular, we can use the amount of squeezing to quantitatively relate the resource requirements of DQC1 and factoring. Furthermore, we can connect the squeezing to other known resources like precision, energy, qudit dimensionality, and qubit number. We show the circumstances under which they can likewise be considered good resources. [ABSTRACT FROM AUTHOR]

Published

2016