Time optimal control-based RF pulse design under gradient imperfections

Christoph S Aigner; Armin Rund; Samy Abo Seada; Anthony N Price; Joseph V Hajnal; Shaihan J Malik; Karl Kunisch; Rudolf Stollberger

doi:10.1002/mrm.27955

Time optimal control-based RF pulse design under gradient imperfections

Christoph S Aigner^*, Armin Rund, Samy Abo Seada, Anthony N Price, Joseph V Hajnal, Shaihan J Malik, Karl Kunisch, Rudolf Stollberger

^*Corresponding author for this work

Institute of Biomedical Imaging (7170)

Research output: Contribution to journal › Article › peer-review

Abstract

PURPOSE: This study incorporates a gradient system imperfection model into an optimal control framework for radio frequency (RF) pulse design.

THEORY AND METHODS: The joint design of minimum-time RF and slice selective gradient shapes is posed as an optimal control problem. Hardware limitations such as maximal amplitudes for RF and slice selective gradient or its slew rate are included as hard constraints to assure practical applicability of the optimized waveforms. In order to guarantee the performance of the optimized waveform with possible gradient system disturbances such as limited system bandwidth and eddy currents, a measured gradient impulse response function (GIRF) for a specific system is integrated into the optimization.

RESULTS: The method generates optimized RF and pre-distorted slice selective gradient shapes for refocusing that are able to fully compensate the modeled imperfections of the gradient system under investigation. The results nearly regenerate the optimal results of an idealized gradient system. The numerical Bloch simulations are validated by phantom and in-vivo experiments on 2 3T scanners.

CONCLUSIONS: The presented design approach demonstrates the successful correction of gradient system imperfections within an optimal control framework for RF pulse design.

Original language	English
Pages (from-to)	561-574
Number of pages	14
Journal	Magnetic Resonance in Medicine
Volume	83
Issue number	2
DOIs	https://doi.org/10.1002/mrm.27955
Publication status	Published - Feb 2020

Keywords

gradient imperfections
gradient impulse response function
pulse design
simultaneous multi-slice excitation
time optimal control

ASJC Scopus subject areas

Radiology Nuclear Medicine and imaging

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10.1002/mrm.27955Licence: CC BY 4.0

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title = "Time optimal control-based RF pulse design under gradient imperfections",

abstract = "PURPOSE: This study incorporates a gradient system imperfection model into an optimal control framework for radio frequency (RF) pulse design.THEORY AND METHODS: The joint design of minimum-time RF and slice selective gradient shapes is posed as an optimal control problem. Hardware limitations such as maximal amplitudes for RF and slice selective gradient or its slew rate are included as hard constraints to assure practical applicability of the optimized waveforms. In order to guarantee the performance of the optimized waveform with possible gradient system disturbances such as limited system bandwidth and eddy currents, a measured gradient impulse response function (GIRF) for a specific system is integrated into the optimization.RESULTS: The method generates optimized RF and pre-distorted slice selective gradient shapes for refocusing that are able to fully compensate the modeled imperfections of the gradient system under investigation. The results nearly regenerate the optimal results of an idealized gradient system. The numerical Bloch simulations are validated by phantom and in-vivo experiments on 2 3T scanners.CONCLUSIONS: The presented design approach demonstrates the successful correction of gradient system imperfections within an optimal control framework for RF pulse design.",

keywords = "gradient imperfections, gradient impulse response function, pulse design, simultaneous multi-slice excitation, time optimal control",

author = "Aigner, {Christoph S} and Armin Rund and {Abo Seada}, Samy and Price, {Anthony N} and Hajnal, {Joseph V} and Malik, {Shaihan J} and Karl Kunisch and Rudolf Stollberger",

note = "{\textcopyright} 2019 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals, Inc. on behalf of International Society for Magnetic Resonance in Medicine.",

year = "2020",

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doi = "10.1002/mrm.27955",

language = "English",

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T1 - Time optimal control-based RF pulse design under gradient imperfections

AU - Aigner, Christoph S

AU - Rund, Armin

AU - Abo Seada, Samy

AU - Price, Anthony N

AU - Hajnal, Joseph V

AU - Malik, Shaihan J

AU - Kunisch, Karl

AU - Stollberger, Rudolf

PY - 2020/2

Y1 - 2020/2

N2 - PURPOSE: This study incorporates a gradient system imperfection model into an optimal control framework for radio frequency (RF) pulse design.THEORY AND METHODS: The joint design of minimum-time RF and slice selective gradient shapes is posed as an optimal control problem. Hardware limitations such as maximal amplitudes for RF and slice selective gradient or its slew rate are included as hard constraints to assure practical applicability of the optimized waveforms. In order to guarantee the performance of the optimized waveform with possible gradient system disturbances such as limited system bandwidth and eddy currents, a measured gradient impulse response function (GIRF) for a specific system is integrated into the optimization.RESULTS: The method generates optimized RF and pre-distorted slice selective gradient shapes for refocusing that are able to fully compensate the modeled imperfections of the gradient system under investigation. The results nearly regenerate the optimal results of an idealized gradient system. The numerical Bloch simulations are validated by phantom and in-vivo experiments on 2 3T scanners.CONCLUSIONS: The presented design approach demonstrates the successful correction of gradient system imperfections within an optimal control framework for RF pulse design.

AB - PURPOSE: This study incorporates a gradient system imperfection model into an optimal control framework for radio frequency (RF) pulse design.THEORY AND METHODS: The joint design of minimum-time RF and slice selective gradient shapes is posed as an optimal control problem. Hardware limitations such as maximal amplitudes for RF and slice selective gradient or its slew rate are included as hard constraints to assure practical applicability of the optimized waveforms. In order to guarantee the performance of the optimized waveform with possible gradient system disturbances such as limited system bandwidth and eddy currents, a measured gradient impulse response function (GIRF) for a specific system is integrated into the optimization.RESULTS: The method generates optimized RF and pre-distorted slice selective gradient shapes for refocusing that are able to fully compensate the modeled imperfections of the gradient system under investigation. The results nearly regenerate the optimal results of an idealized gradient system. The numerical Bloch simulations are validated by phantom and in-vivo experiments on 2 3T scanners.CONCLUSIONS: The presented design approach demonstrates the successful correction of gradient system imperfections within an optimal control framework for RF pulse design.

KW - gradient imperfections

KW - gradient impulse response function

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KW - simultaneous multi-slice excitation

KW - time optimal control

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Time optimal control-based RF pulse design under gradient imperfections

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Keywords

ASJC Scopus subject areas

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