Transduction of the Motion

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Related lectures (28)

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Capacitors and Dielectrics

Explores the behavior of capacitors, electrostatic potential energy, and forces on dielectric materials.

Transduction: Actuation

Explores transduction through actuation mechanisms, covering force-based and deformation-based methods, shape memory polymers, electrostatic and magnetic actuation principles, and examples like Texas Instruments DLP & DMD.

Distance Sensors: Implementation

Explains the implementation of a distance sensor using microcontrollers and discusses indirect measurement techniques.

Dielectrics and Capacitors

Explores dielectrics, capacitors, electric energy, force, and resistivity in materials.

Electrostatic Devices: Modeling & Simulation

Covers modeling and simulation of electrostatic devices in micro and nanosystems.

Transduction: Detection

Explores various methods of transduction for detecting motion and deformation in microscale applications.

Electric Fields and Currents

Explores electric fields, energy storage, charge displacement, DC currents, and historical aspects of electricity.

Electrostatic MEMS: Scaling Laws & Simulations

Explores scaling laws, simulations, and challenges in electrostatic MEMS, focusing on energy density, capacitance, actuators, and practical applications in haptic gloves.

Electrostatic Transduction: Capacitors and Transducers

Covers the physical phenomena of electrostatic transduction, including charge accumulation, capacitance, and electrostatic force, with practical examples of sensors and actuators.

Mechanisms of Actuators and Artificial Muscles

Explores the mechanisms of actuators, artificial muscles, and electroactive materials, focusing on dielectric elastomers and high-speed actuators.