Your search keyword '"Sastrawan, J."' showing total 8 results

1. Analytically exploiting noise correlations inside the feedback loop to improve locked-oscillator performance

Author

Sastrawan, J., Jones, C., Akhalwaya, I., Uys, H., and Biercuk, M. J.

Subjects

Quantum Physics, Physics - Atomic Physics, Physics - Instrumentation and Detectors

Abstract

We introduce concepts from optimal estimation to the stabilization of precision frequency standards limited by noisy local oscillators. We develop a theoretical framework casting various measures for frequency standard variance in terms of frequency-domain transfer functions, capturing the effects of feedback stabilization via a time-series of Ramsey measurements. Using this framework we introduce a novel optimized hybrid predictive feedforward measurement protocol which employs results from multiple past measurements and transfer-function-based calculations of measurement covariance to improve the accuracy of corrections within the feedback loop. In the presence of common non-Markovian noise processes these measurements will be correlated in a calculable manner, providing a means to capture the stochastic evolution of the LO frequency during the measurement cycle. We present analytic calculations and numerical simulations of oscillator performance under competing feedback schemes and demonstrate benefits in both correction accuracy and long-term oscillator stability using hybrid feedforward. Simulations verify that in the presence of uncompensated dead time and noise with significant spectral weight near the inverse cycle time predictive feedforward outperforms traditional feedback, providing a path towards developing a new class of stabilization "software" routines for frequency standards limited by noisy local oscillators., Comment: Related papers at http://www.physics.usyd.edu.au/~mbiercuk/Publications.html

Published

2014

2. Experimental noise filtering by quantum control

Author

Soare, A., Ball, H., Hayes, D., Sastrawan, J., Jarratt, M. C., McLoughlin, J. J., Zhen, X., Green, T. J., and Biercuk, M. J.

Subjects

Quantum Physics

Abstract

Instabilities due to extrinsic interference are routinely faced in systems engineering, and a common solution is to rely on a broad class of $\textit{filtering}$ techniques in order to afford stability to intrinsically unstable systems. For instance, electronic systems are frequently designed to incorporate electrical filters composed of, $\textit{e.g.}$ RLC components, in order to suppress the effects of out-of-band fluctuations that interfere with desired performance. Quantum coherent systems are now moving to a level of complexity where challenges associated with realistic time-dependent noise are coming to the fore. Unfortunately, standard control solutions involving feedback are generally impossible due to the strictures of quantum mechanics, and existing error-suppressing gate constructions generally rely on unphysical bang-bang controls or quasi-static error models that do not reflect realistic laboratory environments. In this work we use the theory of quantum control engineering and experiments with trapped $^{171}$Yb$^{+}$ ions to demonstrate the construction of novel $\textit{noise filters}$ which are specifically designed to mitigate the effect of realistic time-dependent fluctuations on qubits \emph{during useful operations}. Starting with desired filter characteristics and the Walsh basis functions, we use a combination of analytic design rules and numeric search to construct time-domain noise filters tailored to a desired state transformation. Our results validate the generalized filter-transfer function framework for arbitrary quantum control operations, and demonstrate that it can be leveraged as an effective and efficient tool for developing novel robust control protocols., Comment: Related work available from http://www.physics.usyd.edu.au/~mbiercuk/Publications.html

Published

2014

3. Experimental bath engineering for quantitative studies of quantum control

Author

Soare, A., Ball, H., Hayes, D., Zhen, X., Jarratt, M. C., Sastrawan, J., Uys, H., and Biercuk, M. J.

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We develop and demonstrate a technique to engineer universal unitary baths in quantum systems. Using the correspondence between unitary decoherence due to ambient environmental noise and errors in a control system for quantum bits, we show how a wide variety of relevant classical error models may be realized through In-Phase/Quadrature modulation on a vector signal generator producing a resonant carrier signal. We demonstrate our approach through high-bandwidth modulation of the 12.6 GHz carrier appropriate for trapped $^{171}$Yb$^{+}$ ions. Experiments demonstrate the reduction of coherent lifetime in the system in the presence of an engineered bath, with the observed $T_{2}$ scaling as predicted by a quantitative model described herein. These techniques form the basis of a toolkit for quantitative tests of quantum control protocols, helping experimentalists characterize the performance of their quantum coherent systems., Comment: Related manuscripts at http://www.physics.usyd.edu.au/~mbiercuk/Publications.html

Published

2014

4. Analytically exploiting noise correlations inside the feedback loop to improve locked-oscillator performance

Author

Sastrawan, J., primary, Jones, C., additional, Akhalwaya, I., additional, Uys, H., additional, and Biercuk, M. J., additional

Published

2016

5. Experimental noise filtering by quantum control

Author

Soare, A., primary, Ball, H., additional, Hayes, D., additional, Sastrawan, J., additional, Jarratt, M. C., additional, McLoughlin, J. J., additional, Zhen, X., additional, Green, T. J., additional, and Biercuk, M. J., additional

Published

2014

6. Experimental bath engineering for quantitative studies of quantum control

Author

Soare, A., primary, Ball, H., additional, Hayes, D., additional, Zhen, X., additional, Jarratt, M. C., additional, Sastrawan, J., additional, Uys, H., additional, and Biercuk, M. J., additional

Published

2014

7. Prediction and real-time compensation of qubit decoherence via machine learning.

Author

Mavadia S, Frey V, Sastrawan J, Dona S, and Biercuk MJ

Abstract

The wide-ranging adoption of quantum technologies requires practical, high-performance advances in our ability to maintain quantum coherence while facing the challenge of state collapse under measurement. Here we use techniques from control theory and machine learning to predict the future evolution of a qubit's state; we deploy this information to suppress stochastic, semiclassical decoherence, even when access to measurements is limited. First, we implement a time-division multiplexed approach, interleaving measurement periods with periods of unsupervised but stabilised operation during which qubits are available, for example, in quantum information experiments. Second, we employ predictive feedback during sequential but time delayed measurements to reduce the Dick effect as encountered in passive frequency standards. Both experiments demonstrate significant improvements in qubit-phase stability over 'traditional' measurement-based feedback approaches by exploiting time domain correlations in the noise processes. This technique requires no additional hardware and is applicable to all two-level quantum systems where projective measurements are possible.

Published

2017

8. Designing a practical high-fidelity long-time quantum memory.

Author

Khodjasteh K, Sastrawan J, Hayes D, Green TJ, Biercuk MJ, and Viola L

Abstract

Quantum memory is a central component for quantum information processing devices, and will be required to provide high-fidelity storage of arbitrary states, long storage times and small access latencies. Despite growing interest in applying physical-layer error-suppression strategies to boost fidelities, it has not previously been possible to meet such competing demands with a single approach. Here we use an experimentally validated theoretical framework to identify periodic repetition of a high-order dynamical decoupling sequence as a systematic strategy to meet these challenges. We provide analytic bounds-validated by numerical calculations-on the characteristics of the relevant control sequences and show that a 'stroboscopic saturation' of coherence, or coherence plateau, can be engineered, even in the presence of experimental imperfection. This permits high-fidelity storage for times that can be exceptionally long, meaning that our device-independent results should prove instrumental in producing practically useful quantum technologies.

Published

2013