Design and Optimal Control of a Multistable, Cooperative Microactuator

The performance of micromirrors in terms of their maximum deflection is often limited due to mechanical constraints in the design. To increase the range of achievable deflection angles, we present a novel concept in which a free-lying sphere with a flat side as reflector can be rotated. Due to the large forces needed to move the sphere, multiple electrostatic actuators are used to cooperatively rotate the sphere in iterative steps by impacts and friction. A parameterized system-level model of the configuration is derived, which considers arbitrary multi-contact scenarios and can be used for simulation, analysis, and control design purposes. Due to the complex, indirect relation between the actuator voltages and the sphere motion, model-based numerical optimization is applied to obtain suitable system inputs. This results in rotation sequences, which can be understood as a sequence of motion primitives, thus transforming the continuous time model into an abstract discrete time model. Based on this, we propose a feedback control strategy for trajectory following, considering model uncertainties by a learning scheme. High precision is achieved by an extension controlling the angular change of each rotation step. The suitability of the overall approach is demonstrated in simulation for maximum angles of 40°, achieving angular velocities of approximately 10°/s.

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“…Here, we use a slight adaptation of the definition in [19]. According to [27] the activation function is then given by…”

Section: Beam-ground Contactmentioning

confidence: 99%

Modeling and Control Design of a Contact-Based, Electrostatically Actuated Rotating Sphere

et al. 2022

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“…The resulting actuator had a stroke of 680 µm and 185 mN blocking force. A combination of electromagnetic and piezoelectric principles for multistable digital actuation was presented in [17]. The actuator consists of permanent magnetic rings, defining multiple stable positions: a lower one in contact with a piezoelectric stack actuator, and upper ones located at predefined heights, where the magnetic object is stably levitated.…”

Section: From Analog To Digital Actuationmentioning

confidence: 99%

Trajectory and Conveyance Validation of a Micro Conveyor Based on a Digital Electromagnetic Actuators Array for the Micro-Factory

et al. 2021

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Micro-factories are characterized by high modularity, reconfigurability and mobility. To achieve this, the micro-factory needs a conveyor which is able to transport objects in as many degrees of freedom (DoF) as possible, executes optimal trajectories of these objects in terms of energy and precision and is robust to withstand possible malfunctions. In this article, we present the planar conveyance of objects on a digital actuation array following trajectories generated by an adapted A* algorithm. The A* algorithm exploits the predictions of a developed dynamic model of the system to find the optimal paths (in terms of energy) on the conveyor surface. The dynamic model predictions were compared to experimental measurements, obtaining low root-mean-square-errors for all conditions. Uni-dimensional conveyance tests characterized the influence of the control parameters. Then, bi-dimensional motions characterized the conveyor’s performance. From the bi-dimensional test, a position root-mean-square-error of 20 μm was measured for a 1109 μm open-loop controlled trajectory. The modular nature of the array allows easy scaling and avoiding possible malfunctioning zones, increasing the robustness of the micro-conveyor. The experimental tests demonstrate that the proposed device is an interesting alternative for the micro-factory.

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“…Such solenoids require a continuous power supply to hold any position except for the stable one given by the spring force (maximum air gap 𝑥 a,max ). Bistable solenoids [3][4][5] or solutions with more than two, but a limited number of stable switching positions [6,7], are an efficient alternative to neutral mono-stable switching solenoids. Therefore, different design principles are known [2,3].…”

Section: Introductionmentioning

confidence: 99%

Automation of Pneumatic Throttle Check Valves by Using Novel Multi-Stable Solenoids

Kramer,

Weber

2024

14th International Fluid Power Conference

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Multi-stable solenoids are novel energy-efficient actuator structures, which can hold any armature position powerless. Power is only required to change the armature position. They combine the continuous adjustability of proportional solenoids with the energy efficiency of polarised magnetic circuits. Thus, they are well suited for automating pneumatic throttle check valves, in order to set the throttle cross section and thus the cylinder piston velocity to a specific value and hold it for a certain time. This is useful in industry 4.0 context to produce on demand with various required piston velocities or for gradual compensation for increasing frictional forces during cylinder lifetime. The focus of this paper is the application of novel multi-stable solenoids for replacing the todays widely used manual adjustment of throttle check valves. Therefore, two different throttle valves are designed: a spool valve and a poppet valve. They are based on the transfer characteristic of a conventional throttle check valve. The flow behaviour of both valves is investigated to show the principal transfer behaviour and disturbances. The valves are equipped with a multi-stable solenoid for demonstrating the adjustability of the throttle's volume flow rate and on that basis the adjustability of the piston velocity in a pneumatic cylinder drive.

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Design and Optimal Control of a Multistable, Cooperative Microactuator

Cited by 3 publications

References 31 publications

Modeling and Control Design of a Contact-Based, Electrostatically Actuated Rotating Sphere

Modeling and Control Design of a Contact-Based, Electrostatically Actuated Rotating Sphere

Trajectory and Conveyance Validation of a Micro Conveyor Based on a Digital Electromagnetic Actuators Array for the Micro-Factory

Automation of Pneumatic Throttle Check Valves by Using Novel Multi-Stable Solenoids

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