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A discrete-time compensation algorithm for hysteresis in piezoceramic actuators
A discrete-time Preisach model that captures hysteresis in a piezoceramic actuator is developed. The model is implemented using a numerical technique that is based on first-order reversal functions and is presented in a recursive form that is amenable for real-time implementation. The first-order re...
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| Published in: | Mechanical systems and signal processing 2004, Vol.18 (1), p.169-185 |
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| Main Authors: | , |
| Format: | Article |
| Language: | English |
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| cited_by | cdi_FETCH-LOGICAL-c338t-6848e81b7f421a33bfccdab2606f63bd946dea035a341dce23f17207f998f3973 |
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| container_end_page | 185 |
| container_issue | 1 |
| container_start_page | 169 |
| container_title | Mechanical systems and signal processing |
| container_volume | 18 |
| creator | Hu, H. Ben Mrad, R. |
| description | A discrete-time Preisach model that captures hysteresis in a piezoceramic actuator is developed. The model is implemented using a numerical technique that is based on first-order reversal functions and is presented in a recursive form that is amenable for real-time implementation. The first-order reversal functions are experimentally obtained using a piezoceramic actuator in a stacked form. The developed model shows good agreement with actual measured data. Two hysteresis compensation schemes based on the developed discrete-time Preisach model are also developed and used in order to obtain any desired linear voltage-to-displacement relationship. The ability of the first hysteresis compensator to lead to an arbitrary linear voltage-to-displacement relationship is shown through experimental tests under the condition that no-load is applied to the actuator and then a load typical of many piezoactuator applications is applied to the actuator. The second hysteresis compensation scheme is used as part of an open-loop tracking controller and is shown experimentally to lead to high tracking accuracy. |
| doi_str_mv | 10.1016/S0888-3270(03)00021-9 |
| format | article |
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The model is implemented using a numerical technique that is based on first-order reversal functions and is presented in a recursive form that is amenable for real-time implementation. The first-order reversal functions are experimentally obtained using a piezoceramic actuator in a stacked form. The developed model shows good agreement with actual measured data. Two hysteresis compensation schemes based on the developed discrete-time Preisach model are also developed and used in order to obtain any desired linear voltage-to-displacement relationship. The ability of the first hysteresis compensator to lead to an arbitrary linear voltage-to-displacement relationship is shown through experimental tests under the condition that no-load is applied to the actuator and then a load typical of many piezoactuator applications is applied to the actuator. 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The model is implemented using a numerical technique that is based on first-order reversal functions and is presented in a recursive form that is amenable for real-time implementation. The first-order reversal functions are experimentally obtained using a piezoceramic actuator in a stacked form. The developed model shows good agreement with actual measured data. Two hysteresis compensation schemes based on the developed discrete-time Preisach model are also developed and used in order to obtain any desired linear voltage-to-displacement relationship. The ability of the first hysteresis compensator to lead to an arbitrary linear voltage-to-displacement relationship is shown through experimental tests under the condition that no-load is applied to the actuator and then a load typical of many piezoactuator applications is applied to the actuator. 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The model is implemented using a numerical technique that is based on first-order reversal functions and is presented in a recursive form that is amenable for real-time implementation. The first-order reversal functions are experimentally obtained using a piezoceramic actuator in a stacked form. The developed model shows good agreement with actual measured data. Two hysteresis compensation schemes based on the developed discrete-time Preisach model are also developed and used in order to obtain any desired linear voltage-to-displacement relationship. The ability of the first hysteresis compensator to lead to an arbitrary linear voltage-to-displacement relationship is shown through experimental tests under the condition that no-load is applied to the actuator and then a load typical of many piezoactuator applications is applied to the actuator. 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| fulltext | fulltext |
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| ispartof | Mechanical systems and signal processing, 2004, Vol.18 (1), p.169-185 |
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| language | eng |
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| source | ScienceDirect Freedom Collection |
| title | A discrete-time compensation algorithm for hysteresis in piezoceramic actuators |
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