Modeling and Simulations in Time Domain of a Stimulation Set-up for Cortical Applications
Electrical stimulation is used for example to treat neuronal disorders and depression with deep brain stimulation or transcranial electrical stimulation. Depending on the application, different electrodes are used and thus different electrical characteristics exist, which have to be handled by the s...
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2016-06-01
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Series: | European Journal of Translational Myology |
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Online Access: | http://www.pagepressjournals.org/index.php/bam/article/view/6017 |
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doaj-9f4ff9a1276e434fb7eaebaf3127ad8a2020-11-24T23:06:25ZengPAGEPress PublicationsEuropean Journal of Translational Myology2037-74522037-74602016-06-0126210.4081/ejtm.2016.60174749Modeling and Simulations in Time Domain of a Stimulation Set-up for Cortical ApplicationsMichael Schweigmann0Frank Kirchhoff1Klaus P. Koch2Department of Electrical Engineering, Trier University of applied Sciences, Trier; Department of Molecular Physiology, School of Medicine, University of Saarland, HomburgDepartment of Molecular Physiology, School of Medicine, University of Saarland, HomburgDepartment of Electrical Engineering, Trier University of applied Sciences, Trier;Electrical stimulation is used for example to treat neuronal disorders and depression with deep brain stimulation or transcranial electrical stimulation. Depending on the application, different electrodes are used and thus different electrical characteristics exist, which have to be handled by the stimulator. Without a measuring device the user would have to rely on the stimulator being able to deliver the needed stimulation signal. Therefore, the objective of this paper is to present a method to increase the level of confidence with characterization and modelling of the electrical behavior by using the example of one channel of our stimulation device for experimental use. In several simulation studies with an electrode model with values in a typical range for cortical applications the influence of the load onto the stimulator and the possibility to pre-estimate measuring signals in complex networks are shown.http://www.pagepressjournals.org/index.php/bam/article/view/6017Cortical electrical stimulationStimulator characterizationStimulator modelElectrode modelOutput impedance |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Michael Schweigmann Frank Kirchhoff Klaus P. Koch |
spellingShingle |
Michael Schweigmann Frank Kirchhoff Klaus P. Koch Modeling and Simulations in Time Domain of a Stimulation Set-up for Cortical Applications European Journal of Translational Myology Cortical electrical stimulation Stimulator characterization Stimulator model Electrode model Output impedance |
author_facet |
Michael Schweigmann Frank Kirchhoff Klaus P. Koch |
author_sort |
Michael Schweigmann |
title |
Modeling and Simulations in Time Domain of a Stimulation Set-up for Cortical Applications |
title_short |
Modeling and Simulations in Time Domain of a Stimulation Set-up for Cortical Applications |
title_full |
Modeling and Simulations in Time Domain of a Stimulation Set-up for Cortical Applications |
title_fullStr |
Modeling and Simulations in Time Domain of a Stimulation Set-up for Cortical Applications |
title_full_unstemmed |
Modeling and Simulations in Time Domain of a Stimulation Set-up for Cortical Applications |
title_sort |
modeling and simulations in time domain of a stimulation set-up for cortical applications |
publisher |
PAGEPress Publications |
series |
European Journal of Translational Myology |
issn |
2037-7452 2037-7460 |
publishDate |
2016-06-01 |
description |
Electrical stimulation is used for example to treat neuronal disorders and depression with deep brain stimulation or transcranial electrical stimulation. Depending on the application, different electrodes are used and thus different electrical characteristics exist, which have to be handled by the stimulator. Without a measuring device the user would have to rely on the stimulator being able to deliver the needed stimulation signal. Therefore, the objective of this paper is to present a method to increase the level of confidence with characterization and modelling of the electrical behavior by using the example of one channel of our stimulation device for experimental use. In several simulation studies with an electrode model with values in a typical range for cortical applications the influence of the load onto the stimulator and the possibility to pre-estimate measuring signals in complex networks are shown. |
topic |
Cortical electrical stimulation Stimulator characterization Stimulator model Electrode model Output impedance |
url |
http://www.pagepressjournals.org/index.php/bam/article/view/6017 |
work_keys_str_mv |
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1725623086076657664 |