Hysteresis description and/or efficient control of smart electrorheological/magnetorheological materials and structures are essential for applications of these smart materials in vibration/shock mitigation, torque transmission, active gripping and switching, and haptic feedback. Nonlinear characterization, especially the rate-independent hysteresis modeling of the electrorheological/magnetorheological materials-based actuators and sensors is of paramount importance for specific structural design, optimization, and control. A variety of constitutive models, including parametric and non-parametric models, have been proposed to depict the quasi-static and dynamic mechanical behaviors of the smart materials and structures. In addition, the inverse problems are worth investigating for effective feedback control with the obtained relationship of the excitations, commands and outputs.
In this Research Topic, review and original research papers on the hysteresis properties, description, and effective applications of electrorheological/magnetorheological materials are to be published. Specifically, the fundamentals of constitutive relations of the materials, in forms of phenomenological and parametric approaches, are expected for the topic. Hysteretic properties-based mechanical design and optimization of the electrorheological/magnetorheological materials-based actuators and sensors for controllable damping, torque transmission, robotic end effectors, active valves, and haptic feedback or smart skin will also be included. Nonlinear control problems of the hysteresis systems (related to full range of velocity, temperature, and frequency conditions), including hysteresis modeling and inverse modeling, are expected to be solved. Specific applications of vehicular/seat suspensions with vibration control and induced shock mitigation, engine mount, brake and torque transmission systems, anti-earthquake structures for civil buildings, medical rehabilitation actuators, robotic end effectors, active vales/actuators with electrorheological/magnetorheological materials, are also particularly emphasized in this Research Topic.
The proposed topics for this Research Topic include (but are not limited to):
- Hysteresis characterization of electrorheological/magnetorheological materials
- Design/optimization of electrorheological/magnetorheological actuators and sensors
- Potential applications of electrorheological/magnetorheological materials
- Hysteresis models and inverse models of electrorheological/magnetorheological structures
- Nonlinear control of electrorheological/magnetorheological systems
Hysteresis description and/or efficient control of smart electrorheological/magnetorheological materials and structures are essential for applications of these smart materials in vibration/shock mitigation, torque transmission, active gripping and switching, and haptic feedback. Nonlinear characterization, especially the rate-independent hysteresis modeling of the electrorheological/magnetorheological materials-based actuators and sensors is of paramount importance for specific structural design, optimization, and control. A variety of constitutive models, including parametric and non-parametric models, have been proposed to depict the quasi-static and dynamic mechanical behaviors of the smart materials and structures. In addition, the inverse problems are worth investigating for effective feedback control with the obtained relationship of the excitations, commands and outputs.
In this Research Topic, review and original research papers on the hysteresis properties, description, and effective applications of electrorheological/magnetorheological materials are to be published. Specifically, the fundamentals of constitutive relations of the materials, in forms of phenomenological and parametric approaches, are expected for the topic. Hysteretic properties-based mechanical design and optimization of the electrorheological/magnetorheological materials-based actuators and sensors for controllable damping, torque transmission, robotic end effectors, active valves, and haptic feedback or smart skin will also be included. Nonlinear control problems of the hysteresis systems (related to full range of velocity, temperature, and frequency conditions), including hysteresis modeling and inverse modeling, are expected to be solved. Specific applications of vehicular/seat suspensions with vibration control and induced shock mitigation, engine mount, brake and torque transmission systems, anti-earthquake structures for civil buildings, medical rehabilitation actuators, robotic end effectors, active vales/actuators with electrorheological/magnetorheological materials, are also particularly emphasized in this Research Topic.
The proposed topics for this Research Topic include (but are not limited to):
- Hysteresis characterization of electrorheological/magnetorheological materials
- Design/optimization of electrorheological/magnetorheological actuators and sensors
- Potential applications of electrorheological/magnetorheological materials
- Hysteresis models and inverse models of electrorheological/magnetorheological structures
- Nonlinear control of electrorheological/magnetorheological systems
