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Inverse control of systems with hysteresis and creep

Inverse control of systems with hysteresis and creep

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Since the beginning of the 1990s, hysteresis operators have been employed on a larger scale for the linearisation of hysteretic transducers. One reason for this is the increasing number of mechatronic applications that use solid-state actuators based on magnetostrictive or piezo-electric material or shape memory alloys. All of these actuator types show strong hysteretic effects. In addition to hysteresis, piezo-electric actuators show strong creep effects. Thus, the objective of the paper is to enlarge the operator-based methodology of hysteresis operators by elements that allow the description of systems with hysteresis and creep. To reach this objective, following the procedure used for hysteretic systems, creep operators are introduced to form, together with the hysteresis operators, a system operator for the simultaneous consideration of both phenomena. With regard to applications in control and measurement technology, the existence, uniqueness, Lipschitz continuity and thus input–output stability of its inverse operator are theoretically supported by functional analytical methods. Subsequently, the efficiency of this new concept is demonstrated, in practice, by a real-time inverse feedforward controller for piezo-electric actuators. Using this control concept, the tracking errors caused by hysteretic and creep effects are reduced by approximately one order of magnitude.

Inspec keywords: discrete time systems; piezoelectric actuators; feedforward; hysteresis; input-output stability; functional analysis; creep

Other keywords: existence; Lipschitz continuity; creep operators; inverse operator; hysteresis operators; functional analytical methods; real-time inverse feedforward controller; tracking errors; inverse control; uniqueness; creep effects; solid-state actuators

Subjects: Mathematical analysis; Discrete control systems; Stability in control theory; Piezoelectric devices; Mathematical analysis; Nonlinear control systems; Electric actuators and final control equipment

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