Your search keyword '"Sinanan-Singh, Jasmine"' showing total 13 results

1. Toward Mixed Analog-Digital Quantum Signal Processing: Quantum AD/DA Conversion and the Fourier Transform

Author

Liu, Yuan, Martyn, John M., Sinanan-Singh, Jasmine, Smith, Kevin C., Girvin, Steven M., and Chuang, Isaac L.

Subjects

Electrical Engineering and Systems Science - Signal Processing, Quantum Physics

Abstract

Signal processing stands as a pillar of classical computation and modern information technology, applicable to both analog and digital signals. Recently, advancements in quantum information science have suggested that quantum signal processing (QSP) can enable more powerful signal processing capabilities. However, the developments in QSP have primarily leveraged \emph{digital} quantum resources, such as discrete-variable (DV) systems like qubits, rather than \emph{analog} quantum resources, such as continuous-variable (CV) systems like quantum oscillators. Consequently, there remains a gap in understanding how signal processing can be performed on hybrid CV-DV quantum computers. Here we address this gap by developing a new paradigm of mixed analog-digital QSP. We demonstrate the utility of this paradigm by showcasing how it naturally enables analog-digital conversion of quantum signals -- specifically, the transfer of states between DV and CV quantum systems. We then show that such quantum analog-digital conversion enables new implementations of quantum algorithms on CV-DV hardware. This is exemplified by realizing the quantum Fourier transform of a state encoded on qubits via the free-evolution of a quantum oscillator, albeit with a runtime exponential in the number of qubits due to information theoretic arguments. Collectively, this work marks a significant step forward in hybrid CV-DV quantum computation, providing a foundation for scalable analog-digital signal processing on quantum processors., Comment: arXiv admin note: text overlap with arXiv:2407.10381

Published

2024

2. Long-lived metastable-qubit memory

Author

Shi, Xiaoyang, Sinanan-Singh, Jasmine, DeBry, Kyle, Todaro, Susanna L., Chuang, Isaac L., and Chiaverini, John

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Coherent storage of quantum information is crucial to many quantum technologies. Long coherence times have been demonstrated in trapped-ion qubits, typically using the hyperfine levels within the ground state of a single ion. However, recent research suggests qubits encoded in metastable states could provide architectural benefits for quantum information processing, such as the possibility of effective dual-species operation in a single-species system and erasure-error conversion for fault-tolerant quantum computing. Here we demonstrate long-lived encoding of a quantum state in the metastable states of a trapped ion. By sympathetically cooling with another ion of the same species and constantly monitoring for erasure errors, we demonstrate a coherence time of 136(42) seconds with a qubit encoded in the metastable $5D_{5/2}$ state of a single $^{137}$Ba$^+$ ion. In agreement with a model based on empirical results from dynamical-decoupling-based noise spectroscopy, we find that dephasing of the metastable levels is the dominant source of error once erasure errors are removed.

Published

2024

3. Hybrid Oscillator-Qubit Quantum Processors: Instruction Set Architectures, Abstract Machine Models, and Applications

Author

Liu, Yuan, Singh, Shraddha, Smith, Kevin C., Crane, Eleanor, Martyn, John M., Eickbusch, Alec, Schuckert, Alexander, Li, Richard D., Sinanan-Singh, Jasmine, Soley, Micheline B., Tsunoda, Takahiro, Chuang, Isaac L., Wiebe, Nathan, and Girvin, Steven M.

Subjects

Quantum Physics

Abstract

Quantum computing with discrete variable (DV, qubit) hardware is approaching the large scales necessary for computations beyond the reach of classical computers. However, important use cases such as quantum simulations of physical models containing bosonic modes, and quantum error correction are challenging for DV-only systems. Separately, hardware containing native continuous-variable (CV, oscillator) systems has received attention as an alternative approach, yet the universal control of such systems is non-trivial. In this work, we show that hybrid CV-DV hardware offers a great advantage in meeting these challenges, offering a powerful computational paradigm that inherits the strengths of both DV and CV processors. We provide a pedagogical introduction to CV-DV systems and the multiple abstraction layers needed to produce a full software stack connecting applications to hardware. We present a variety of new hybrid CV-DV compilation techniques, algorithms, and applications, including the extension of quantum signal processing concepts to CV-DV systems and strategies to simulate systems of interacting spins, fermions, and bosons. To facilitate the development of hybrid CV-DV processor systems, we introduce formal Abstract Machine Models and Instruction Set Architectures -- essential abstractions that enable developers to formulate applications, compile algorithms, and explore the potential of current and future hardware for realizing fault-tolerant circuits, modules, and processors. Hybrid CV-DV quantum computations are beginning to be performed in superconducting, trapped ion, and neutral atom platforms, and large-scale experiments are set to be demonstrated in the near future. We present a timely and comprehensive guide to this relatively unexplored yet promising approach to quantum computation and providing an architectural backbone to guide future development., Comment: Added a reader's guide, new reference and various minor edits throughout. 155 pages, 51 figures, 652 references

Published

2024

4. Single-shot Quantum Signal Processing Interferometry

Author

Sinanan-Singh, Jasmine, Mintzer, Gabriel L., Chuang, Isaac L., and Liu, Yuan

Subjects

Quantum Physics, Electrical Engineering and Systems Science - Signal Processing

Abstract

Quantum systems of infinite dimension, such as bosonic oscillators, provide vast resources for quantum sensing. Yet, a general theory on how to manipulate such bosonic modes for sensing beyond parameter estimation is unknown. We present a general algorithmic framework, quantum signal processing interferometry (QSPI), for quantum sensing at the fundamental limits of quantum mechanics by generalizing Ramsey-type interferometry. Our QSPI sensing protocol relies on performing nonlinear polynomial transformations on the oscillator's quadrature operators by generalizing quantum signal processing (QSP) from qubits to hybrid qubit-oscillator systems. We use our QSPI sensing framework to make efficient binary decisions on a displacement channel in the single-shot limit. Theoretical analysis suggests the sensing accuracy, given a single-shot qubit measurement, scales inversely with the sensing time or circuit depth of the algorithm. We further concatenate a series of such binary decisions to perform parameter estimation in a bit-by-bit fashion. Numerical simulations are performed to support these statements. Our QSPI protocol offers a unified framework for quantum sensing using continuous-variable bosonic systems beyond parameter estimation and establishes a promising avenue toward efficient and scalable quantum control and quantum sensing schemes beyond the NISQ era., Comment: 26 pages, 8 figures, 1 table

Published

2023

5. Experimental quantum channel discrimination using metastable states of a trapped ion

Author

DeBry, Kyle, Sinanan-Singh, Jasmine, Bruzewicz, Colin D., Reens, David, Kim, May E., Roychowdhury, Matthew P., McConnell, Robert, Chuang, Isaac L., and Chiaverini, John

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We present experimental demonstrations of accurate and unambiguous single-shot discrimination between three quantum channels using a single trapped $^{40}\text{Ca}^{+}$ ion. The three channels cannot be distinguished unambiguously using repeated single channel queries, the natural classical analogue. We develop techniques for using the 6-dimensional $\text{D}_{5/2}$ state space for quantum information processing, and we implement protocols to discriminate quantum channel analogues of phase shift keying and amplitude shift keying data encodings used in classical radio communication. The demonstrations achieve discrimination accuracy exceeding $99\%$ in each case, limited entirely by known experimental imperfections., Comment: Main text: 6 pages, 4 figures. Supplementary Material: 7 pages, 5 figures, 2 tables Fixed a reference and updated publication information

Published

2023

6. Constructing Qudits from Infinite Dimensional Oscillators by Coupling to Qubits

Author

Liu, Yuan, Sinanan-Singh, Jasmine, Kearney, Matthew T., Mintzer, Gabriel, and Chuang, Isaac L.

Subjects

Quantum Physics, Physics - Atomic Physics, Physics - Chemical Physics

Abstract

An infinite dimensional system such as a quantum harmonic oscillator offers a potentially unbounded Hilbert space for computation, but accessing and manipulating the entire state space requires a physically unrealistic amount of energy. When such a quantum harmonic oscillator is coupled to a qubit, for example via a Jaynes-Cummings interaction, it is well known that the total Hilbert space can be separated into independently accessible subspaces of constant energy, but the number of subspaces is still infinite. Nevertheless, a closed four-dimensional Hilbert space can be analytically constructed from the lowest energy states of the qubit-oscillator system. We extend this idea and show how a $d$-dimensional Hilbert space can be analytically constructed, which is closed under a finite set of unitary operations resulting solely from manipulating standard Jaynes-Cummings Hamiltonian terms. Moreover, we prove that the first-order sideband pulses and carrier pulses comprise a universal set for quantum operations on the qubit-oscillator qudit. This work suggests that the combination of a qubit and a bosonic system may serve as hardware-efficient quantum resources for quantum information processing., Comment: 15 pages, 5 figures

Published

2021

7. Experimental Quantum Channel Discrimination Using Metastable States of a Trapped Ion

Author

DeBry, Kyle, primary, Sinanan-Singh, Jasmine, additional, Bruzewicz, Colin D., additional, Reens, David, additional, Kim, May E., additional, Roychowdhury, Matthew P., additional, McConnell, Robert, additional, Chuang, Isaac L., additional, and Chiaverini, John, additional

Published

2023

8. Constructing qudits from infinite-dimensional oscillators by coupling to qubits

Author

Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Liu, Yuan, Sinanan-Singh, Jasmine, Kearney, Matthew T, Mintzer, Gabriel, Chuang, Isaac L, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Liu, Yuan, Sinanan-Singh, Jasmine, Kearney, Matthew T, Mintzer, Gabriel, and Chuang, Isaac L

Published

2022

9. Continuous Variable Quantum Computing with Trapped Ions

Author

Sinanan-Singh, Jasmine, primary, Mintzer, Gabriel, primary, Todaro, Susanna, primary, DeBry, Kyle, primary, Knollmann, Felix, primary, Shi, Xiaoyang, primary, Bruzewicz, Colin, primary, Chiaverini, John, primary, and L. Chuang, Isaac, primary

Published

2022

10. Barium Ions for omg-style Trapped-Ion Quantum Information

Author

Todaro, Susanna, primary, Shi, Xiaoyang, primary, Lei, Karen, primary, DeBry, Kyle, primary, Alterman, Sam, primary, Knollmann, Felix, primary, Mintzer, Gabriel, primary, McCourt, Trevor, primary, Sinanan-Singh, Jasmine, primary, Bruzewicz, Colin, primary, Chiaverini, John, primary, and L. Chuang, Isaac, primary

Published

2022

11. Constructing qudits from infinite-dimensional oscillators by coupling to qubits

Author

Liu, Yuan, primary, Sinanan-Singh, Jasmine, additional, Kearney, Matthew T., additional, Mintzer, Gabriel, additional, and Chuang, Isaac L., additional

Published

2021

12. Analysis of poration-induced changes in cells from laser-activated plasmonic substrates

Author

Saklayen, Nabiha, Kalies, Stefan, Madrid, Marinna, Nuzzo, Valeria, Huber, Marinus, Shen, Weilu, Sinanan-Singh, Jasmine, Heinemann, Dag, Heisterkamp, Alexander, Mazur, Eric, Saklayen, Nabiha, Kalies, Stefan, Madrid, Marinna, Nuzzo, Valeria, Huber, Marinus, Shen, Weilu, Sinanan-Singh, Jasmine, Heinemann, Dag, Heisterkamp, Alexander, and Mazur, Eric

Abstract

Laser-exposed plasmonic substrates permeabilize the plasma membrane of cells when in close contact to deliver cell-impermeable cargo. While studies have determined the cargo delivery efficiency and viability of laser-exposed plasmonic substrates, morphological changes in a cell have not been quantified. We porated myoblast C2C12 cells on a plasmonic pyramid array using a 532-nm laser with 850-ps pulse length and time-lapse fluorescence imaging to quantify cellular changes. We obtain a poration efficiency of 80%, viability of 90%, and a pore radius of 20 nm. We quantified area changes in the plasma membrane attached to the substrate (10% decrease), nucleus (5 - 10% decrease), and cytoplasm (5 - 10% decrease) over 1 h after laser treatment. Cytoskeleton fibers show a change of 50% in the alignment, or coherency, of fibers, which stabilizes after 10 mins. We investigate structural and morphological changes due to the poration process to enable the safe development of this technique for therapeutic applications.

Published

2017

13. Analysis of poration-induced changes in cells from laser-activated plasmonic substrates

Author

Saklayen, Nabiha, primary, Kalies, Stefan, additional, Madrid, Marinna, additional, Nuzzo, Valeria, additional, Huber, Marinus, additional, Shen, Weilu, additional, Sinanan-Singh, Jasmine, additional, Heinemann, Dag, additional, Heisterkamp, Alexander, additional, and Mazur, Eric, additional

Published

2017