Optimal control gradient precision trade-offs: application to fast generation of DeepControl libraries for MRI
Optimal control gradient precision trade-offs: application to fast generation of DeepControl libraries for MRI
We have recently demonstrated supervised deep learning methods for rapid generation of radiofrequency pulses in magnetic resonance imaging (https://doi.org/10.1002/mrm.27740, https://doi.org/10.1002/mrm.28667). Unlike the previous iterative optimization approaches, deep learning methods generate a pulse using a fixed number of floating-point operations - this is important in MRI, where patient-specific pulses preferably must be produced in real time. However, deep learning requires vast training libraries, which must be generated using the traditional methods, e.g., iterative quantum optimal control methods. Those methods are usually variations of gradient descent, and the calculation of the gradient of the performance metric with respect to the pulse waveform can be the most numerically intensive step. In this communication, we explore various ways in which the calculation of gradients in quantum optimal control theory may be accelerated. Four optimization avenues are explored: truncated commutator series expansions at zeroth and first order, a novel midpoint truncation scheme at first order, and the exact complex-step method. For the spin systems relevant to MRI, the first-order midpoint truncation is found to be sufficiently accurate, but also significantly faster than the machine precision gradient. This makes the generation of training databases for the machine learning methods considerably more realistic.
2D RF, DeepControl, MRI, Optimal Control, Optimization Gradients
Vinding, Mads Sloth
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Goodwin, David L
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Kuprov, Ilya
bb07f28a-5038-4524-8146-e3fc8344c065
Lund, Torben Ellegaard
1d9f84b9-72ed-4287-8a3d-c09963dd252f
December 2021
Vinding, Mads Sloth
711f3812-64ce-41c7-8f1e-5f358c2b8d05
Goodwin, David L
6cf3021d-a025-457b-9061-a4f6d2fee8de
Kuprov, Ilya
bb07f28a-5038-4524-8146-e3fc8344c065
Lund, Torben Ellegaard
1d9f84b9-72ed-4287-8a3d-c09963dd252f
Vinding, Mads Sloth, Goodwin, David L, Kuprov, Ilya and Lund, Torben Ellegaard
(2021)
Optimal control gradient precision trade-offs: application to fast generation of DeepControl libraries for MRI.
Journal of Magnetic Resonance, 333, [107094].
(doi:10.1016/j.jmr.2021.107094).
Abstract
We have recently demonstrated supervised deep learning methods for rapid generation of radiofrequency pulses in magnetic resonance imaging (https://doi.org/10.1002/mrm.27740, https://doi.org/10.1002/mrm.28667). Unlike the previous iterative optimization approaches, deep learning methods generate a pulse using a fixed number of floating-point operations - this is important in MRI, where patient-specific pulses preferably must be produced in real time. However, deep learning requires vast training libraries, which must be generated using the traditional methods, e.g., iterative quantum optimal control methods. Those methods are usually variations of gradient descent, and the calculation of the gradient of the performance metric with respect to the pulse waveform can be the most numerically intensive step. In this communication, we explore various ways in which the calculation of gradients in quantum optimal control theory may be accelerated. Four optimization avenues are explored: truncated commutator series expansions at zeroth and first order, a novel midpoint truncation scheme at first order, and the exact complex-step method. For the spin systems relevant to MRI, the first-order midpoint truncation is found to be sufficiently accurate, but also significantly faster than the machine precision gradient. This makes the generation of training databases for the machine learning methods considerably more realistic.
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More information
Accepted/In Press date: 19 October 2021
e-pub ahead of print date: 27 October 2021
Published date: December 2021
Additional Information:
Funding Information:
MSV thanks Villum Fonden, Eva og Henry Fraenkels Mindefond, Harboefonden, and Kong Christian Den Tiendes Fond. DLG thanks Burkhard Luy for his generous support and advice.
Publisher Copyright:
© 2021 The Authors
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
Keywords:
2D RF, DeepControl, MRI, Optimal Control, Optimization Gradients
Identifiers
Local EPrints ID: 453946
URI: http://eprints.soton.ac.uk/id/eprint/453946
ISSN: 1090-7807
PURE UUID: 4582a694-d777-4d7b-b9aa-5ce77440072e
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Date deposited: 26 Jan 2022 17:46
Last modified: 17 Mar 2024 03:28
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Author:
Mads Sloth Vinding
Author:
David L Goodwin
Author:
Torben Ellegaard Lund
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