Stealth RF energy harvesting in MRI using selective shielding

Purpose To utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or safety. Methods Power harvesting is performed by RF induction in a resonant coil. Resulting RF field distortion in the subject is canceled by a...

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Published inMagnetic resonance in medicine Vol. 92; no. 1; pp. 406 - 415
Main Authors Bjorkqvist, Oskar, Pruessmann, Klaas P.
Format Journal Article
LanguageEnglish
Published United States Wiley Subscription Services, Inc 01.07.2024
Subjects
Electromagnetic induction
Energy harvesting
Equipment Design
Equipment Failure Analysis
Humans
Image quality
Magnetic resonance imaging
Magnetic Resonance Imaging - instrumentation
Phantoms, Imaging
Power management
Power sources
Radiation Protection - instrumentation
Radio frequency
Radio Waves
RF harvesting
Shielding
wireless power
shielding
wireless power
RF harvesting
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Abstract Purpose To utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or safety. Methods Power harvesting is performed by RF induction in a resonant coil. Resulting RF field distortion in the subject is canceled by a selective shield that couples to the harvester while being transparent to the RF transmitter. Such shielding is designed with the help of electromagnetic simulation. A shielded harvester of 3 cm diameter is implemented, assessed on the bench, and tested in a 3T MRI system, recording power yield during typical scans. Results The concept of selective shielding is confirmed by simulation. Bench tests show effective power harvesting in the presence of the shield. In the MRI system, it is confirmed that selective shielding virtually eliminates RF perturbation. In scans with the harvester immediately adjacent to a phantom, up to 100 mW of average power are harvested without affecting image quality. Conclusion Selective shielding enables stealthy RF harvesting which can be used to supply wireless power to on‐body devices during MRI.
AbstractList Purpose To utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or safety. Methods Power harvesting is performed by RF induction in a resonant coil. Resulting RF field distortion in the subject is canceled by a selective shield that couples to the harvester while being transparent to the RF transmitter. Such shielding is designed with the help of electromagnetic simulation. A shielded harvester of 3 cm diameter is implemented, assessed on the bench, and tested in a 3T MRI system, recording power yield during typical scans. Results The concept of selective shielding is confirmed by simulation. Bench tests show effective power harvesting in the presence of the shield. In the MRI system, it is confirmed that selective shielding virtually eliminates RF perturbation. In scans with the harvester immediately adjacent to a phantom, up to 100 mW of average power are harvested without affecting image quality. Conclusion Selective shielding enables stealthy RF harvesting which can be used to supply wireless power to on‐body devices during MRI.
To utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or safety.PURPOSETo utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or safety.Power harvesting is performed by RF induction in a resonant coil. Resulting RF field distortion in the subject is canceled by a selective shield that couples to the harvester while being transparent to the RF transmitter. Such shielding is designed with the help of electromagnetic simulation. A shielded harvester of 3 cm diameter is implemented, assessed on the bench, and tested in a 3T MRI system, recording power yield during typical scans.METHODSPower harvesting is performed by RF induction in a resonant coil. Resulting RF field distortion in the subject is canceled by a selective shield that couples to the harvester while being transparent to the RF transmitter. Such shielding is designed with the help of electromagnetic simulation. A shielded harvester of 3 cm diameter is implemented, assessed on the bench, and tested in a 3T MRI system, recording power yield during typical scans.The concept of selective shielding is confirmed by simulation. Bench tests show effective power harvesting in the presence of the shield. In the MRI system, it is confirmed that selective shielding virtually eliminates RF perturbation. In scans with the harvester immediately adjacent to a phantom, up to 100 mW of average power are harvested without affecting image quality.RESULTSThe concept of selective shielding is confirmed by simulation. Bench tests show effective power harvesting in the presence of the shield. In the MRI system, it is confirmed that selective shielding virtually eliminates RF perturbation. In scans with the harvester immediately adjacent to a phantom, up to 100 mW of average power are harvested without affecting image quality.Selective shielding enables stealthy RF harvesting which can be used to supply wireless power to on-body devices during MRI.CONCLUSIONSelective shielding enables stealthy RF harvesting which can be used to supply wireless power to on-body devices during MRI.
PurposeTo utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or safety.MethodsPower harvesting is performed by RF induction in a resonant coil. Resulting RF field distortion in the subject is canceled by a selective shield that couples to the harvester while being transparent to the RF transmitter. Such shielding is designed with the help of electromagnetic simulation. A shielded harvester of 3 cm diameter is implemented, assessed on the bench, and tested in a 3T MRI system, recording power yield during typical scans.ResultsThe concept of selective shielding is confirmed by simulation. Bench tests show effective power harvesting in the presence of the shield. In the MRI system, it is confirmed that selective shielding virtually eliminates RF perturbation. In scans with the harvester immediately adjacent to a phantom, up to 100 mW of average power are harvested without affecting image quality.ConclusionSelective shielding enables stealthy RF harvesting which can be used to supply wireless power to on‐body devices during MRI.
To utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or safety. Power harvesting is performed by RF induction in a resonant coil. Resulting RF field distortion in the subject is canceled by a selective shield that couples to the harvester while being transparent to the RF transmitter. Such shielding is designed with the help of electromagnetic simulation. A shielded harvester of 3 cm diameter is implemented, assessed on the bench, and tested in a 3T MRI system, recording power yield during typical scans. The concept of selective shielding is confirmed by simulation. Bench tests show effective power harvesting in the presence of the shield. In the MRI system, it is confirmed that selective shielding virtually eliminates RF perturbation. In scans with the harvester immediately adjacent to a phantom, up to 100 mW of average power are harvested without affecting image quality. Selective shielding enables stealthy RF harvesting which can be used to supply wireless power to on-body devices during MRI.
Author Bjorkqvist, Oskar
Pruessmann, Klaas P.
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Keywords shielding
wireless power
RF harvesting
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Snippet Purpose To utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or...
To utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or safety....
PurposeTo utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or...
To utilize the transmit radiofrequency (RF) field in MRI as a power source, near or within the field of view but without affecting image quality or...
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SubjectTerms Electromagnetic induction
Energy harvesting
Equipment Design
Equipment Failure Analysis
Humans
Image quality
Magnetic resonance imaging
Magnetic Resonance Imaging - instrumentation
Phantoms, Imaging
Power management
Power sources
Radiation Protection - instrumentation
Radio frequency
Radio Waves
RF harvesting
Shielding
wireless power
Title Stealth RF energy harvesting in MRI using selective shielding
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fmrm.30048
https://www.ncbi.nlm.nih.gov/pubmed/38411281
https://www.proquest.com/docview/3046999087
https://www.proquest.com/docview/2932438253
Volume 92
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