01174nam0 22002891i 450 UON0028489120231205103856.3431124--889020061205d2006 |0itac50 baitaIT|||| |||||Teoria e prassi dei sistemi onimici popolarila comunità orbasca (Appennino Ligure centrale) e i suoi nomi propriGiorgio MarrapodiRomaSocietà Editrice Romana2006532 p.23 cmDono Prof. ValeriIT-UONSI GLOTTA 5III/094OnomasticaItaliaUONC029256FIITRomaUONL000004929.97Onomastica21MARRAPODIGiorgioUONV164501475510Società Editrice RomanaUONV260261650ITSOL20250613RICASIBA - SISTEMA BIBLIOTECARIO DI ATENEOUONSIUON00284891SIBA - SISTEMA BIBLIOTECARIO DI ATENEOSI GLOTT A 5 III 094 SI MC 30640 5 094 Dono Prof. ValeriTeoria e prassi dei sistemi onimici popolari248349UNIOR05256nam 22006614a 450 991101947090332120251116151450.097866102385079781280238505128023850X9780470091999047009199197804700919820470091983(CKB)1000000000356552(EBL)239464(SSID)ssj0000145868(PQKBManifestationID)11158354(PQKBTitleCode)TC0000145868(PQKBWorkID)10182243(PQKB)10456381(MiAaPQ)EBC239464(OCoLC)85820500(Perlego)2758587(EXLCZ)99100000000035655220041209d2005 uy 0engur|n|---|||||txtccrEmerging actuator technologies a micromechatronic approach /Jose L. PonsChichester, England ;Hoboken, NJ Wileyc20051 online resource (306 p.)Description based upon print version of record.9780470091975 0470091975 Includes bibliographical references (p. [271]-274) and index.Emerging Actuator Technologies; Contents; Foreword; Preface; List of Figures; List of Tables; 1 Actuators in motion control systems: mechatronics; 1.1 What is an actuator?; 1.2 Transducing materials as a basis for actuator design; 1.2.1 Energy domains and transduction phenomena; 1.2.2 Transducer basics; 1.3 The role of the actuator in a control system: sensing, processing and acting; 1.3.1 Sensing; 1.3.2 Processing; 1.3.3 Actuation; 1.3.4 Impedance matching; 1.4 What is mechatronics? Principles and biomimesis; 1.4.1 Principles; 1.4.2 Mechatronics and biomimesis1.5 Concomitant actuation and sensing: smart structures1.6 Figures of merit of actuator technologies; 1.6.1 Dynamic performance; 1.6.2 Actuator behavior upon scaling; 1.6.3 Suitability for the application; 1.6.4 Static performance; 1.6.5 Impact of environmental parameters; 1.7 A classification of actuator technologies; 1.7.1 Semiactive versus active actuators; 1.7.2 Translational versus rotational actuators; 1.7.3 Input energy domain; 1.7.4 Soft versus hard actuators; 1.8 Emerging versus traditional actuator technologies; 1.9 Scope of the book: emerging actuators1.10 Other actuator technologies1.10.1 Electrostatic actuators; 1.10.2 Thermal actuators; 1.10.3 Magnetic shape memory actuators; 2 Piezoelectric actuators; 2.1 Piezoelectricity and piezoelectric materials; 2.2 Constitutive equations of piezoelectric materials; 2.3 Resonant piezoelectric actuators; 2.3.1 Basics of resonant operation of piezoelectric loads; 2.3.2 Rotational ultrasonic motors; 2.3.3 Linear ultrasonic motors; 2.4 Nonresonant piezoelectric actuators; 2.4.1 Bimorph actuators; 2.4.2 Stack piezoelectric actuators; 2.4.3 Inchworm actuators; 2.5 Control aspects of piezoelectric motors2.5.1 Control circuits and resonant drivers2.5.2 Control of nonresonant actuators; 2.6 Figures of merit of piezoelectric actuators; 2.6.1 Operational characteristics; 2.6.2 Scaling of piezoelectric actuators; 2.7 Applications; 2.7.1 Applications of resonant piezoelectric actuators; 2.7.2 Applications of nonresonant piezoelectric actuators; 3 Shape Memory Actuators (SMAs); 3.1 Shape memory alloys; 3.1.1 The shape memory effect; 3.1.2 Pseudoelasticity in SMAs; 3.2 Design of shape memory actuators; 3.2.1 Design concepts for actuation with SMAs; 3.2.2 Material considerations3.2.3 Thermal considerations3.3 Control of SMAs; 3.3.1 Electrical heating; 3.3.2 Concomitant sensing and actuation with SMAs; 3.3.3 Integration in control loops; 3.4 Figures of merit of shape memory actuators; 3.4.1 Operational ranges; 3.4.2 Scaling laws for SMA actuators; 3.5 Applications; 4 Electroactive polymer actuators (EAPs); 4.1 Principles; 4.1.1 Wet EAP actuators; 4.1.2 Dry EAP actuators; 4.2 Design issues; 4.3 Control of EAPs; 4.4 Figures of merit of EAPs; 4.4.1 Operational characteristics; 4.4.2 Scaling laws for EAPs; 4.5 Applications; 5 Magnetostrictive actuators (MSs)5.1 Principles of magnetostrictionActuators are devices that convert electrical energy into mechanical work, traditionally used in electrical, pneumatic and hydraulic systems. As the demand for actuator technologies grows in biomedical, prosthetic and orthotic applications, there is an increasing need for complex and sophisticated products that perform efficiently also when scaled to micro and nano domains.Providing a comprehensive overview of actuators for novel applications, this excellent book:* Presents a mechatronic approach to the design, control and integration of a range of technologies covering piezoelectrMechatronicsActuatorsMechatronics.Actuators.621Pons José L858489MiAaPQMiAaPQMiAaPQBOOK9911019470903321Emerging actuator technologies4420558UNINA