LEADER 09929nam  2202797z- 450 
001 9910674057703321
005 20231214133501.0
035   $a(CKB)5400000000042652
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/69002
035   $a(EXLCZ)995400000000042652
100   $a20202105d2020      |y             0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aAdvances in Rotating Electric Machines
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 electronic resource (486 p.)
311   $a3-03936-780-3 
311   $a3-03936-781-1 
330   $aIt is difficult to imagine a modern society without rotating electric machines. Their use has been increasing not only in the traditional fields of application but also in more contemporary fields, including renewable energy conversion systems, electric aircraft, aerospace, electric vehicles, unmanned propulsion systems, robotics, etc. This has contributed to advances in the materials, design methodologies, modeling tools, and manufacturing processes of current electric machines, which are characterized by high compactness, low weight, high power density, high torque density, and high reliability. On the other hand, the growing use of electric machines and drives in more critical applications has pushed forward the research in the area of condition monitoring and fault tolerance, leading to the development of more reliable diagnostic techniques and more fault-tolerant machines. This book presents and disseminates the most recent advances related to the theory, design, modeling, application, control, and condition monitoring of all types of rotating electric machines.
606   $aHistory of engineering & technology$2bicssc
610   $acore saturation
610   $across-coupling inductance
610   $awound synchronous machines (WSM)
610   $asignal injection
610   $aposition sensorless
610   $ahigh-frequency model
610   $ahybrid permanent magnet
610   $ainterior permanent magnet (IPM) machine
610   $amagnet-axis-shifted
610   $areluctance torque
610   $aSensorless
610   $ainduction motors
610   $aH_infinity
610   $adrives
610   $avector control
610   $aexperimental implementation
610   $adirect torque control
610   $aduty cycle control
610   $aharmonic currents
610   $asix-phase induction motor
610   $atorque ripple
610   $ainterior permanent magnet synchronous motor (IPMSM)
610   $asensorless control
610   $aadaptive algorithm
610   $asuper-twisting sliding mode observer (STO)
610   $aphase-locked loop (PLL)
610   $apermanent-magnet vernier machine
610   $ain-wheel direct-drive
610   $aouter rotor
610   $aoverhang
610   $asoft magnetic composite
610   $areaction sphere
610   $aspherical motor
610   $astructural design
610   $atorque density optimization
610   $asupport vector machines
610   $afinite element method
610   $ainduction motor
610   $asmart-sensor
610   $astray flux
610   $atime-frequency transforms
610   $awavelet entropy
610   $aharmonic modeling method
610   $amagnetic-geared machine
610   $ahybrid electric vehicle
610   $amagnetic field
610   $aelectromagnetic performance
610   $aanalytical modeling
610   $abrushless DC motor
610   $acommutation torque ripple
610   $aback electromotive force
610   $amultiphase machines
610   $afault-tolerance
610   $adual-channel
610   $abrushless direct current motor with permanent magnet (BLDCM)
610   $aswitched reluctance motor (SRM)
610   $aactive flux
610   $astator flux observation
610   $asuper-twisting sliding-mode stator flux observer (STSMFO)
610   $adeep-bar effect
610   $amathematical model
610   $aestimation
610   $amotor drives
610   $adirect torque control (DTC)
610   $apermanent magnet synchronous motor (PMSM)
610   $amaximum torque per ampere (MTPA) operation
610   $aDTC with space-vector modulation (DTC-SVM)
610   $aAFPMSM
610   $aanalytical algorithm
610   $avibration noise
610   $atemperature field analysis
610   $aSynRM
610   $airreversible demagnetization
610   $aPMa-SynRM
610   $aflux intensifying
610   $adeadbeat current control
610   $aPMSM servo motor drives
610   $aauto tuning
610   $aparameter identification
610   $aperiodic controller
610   $asurface permanent magnet synchronous motor
610   $afault-tolerant system
610   $amulti-channel
610   $aquad-channel operation (QCO)
610   $atriple-channel operation (TCO)
610   $adual-channel operation (DCO)
610   $asingle-channel operation (SCO)
610   $apermanent magnet brushless direct current motor
610   $aBLDCM
610   $adouble Fourier analysis
610   $acurrent spectrum decomposition
610   $aeddy current loss
610   $apermanent magnet machine design
610   $acogging torque
610   $apermanent magnet machine
610   $auneven magnets
610   $aIPMSM
610   $auncertainty and disturbance estimator
610   $aflux-weakening control
610   $adouble-cage induction motor
610   $aimprovement of motor reliability
610   $acage winding constructions
610   $adirect start-up
610   $acoupled electromagnetic-thermal model
610   $aouter rotor inductor
610   $aelectric vehicle
610   $ahigh-efficiency
610   $aeco-friendly
610   $aautomation
610   $afinite element analysis
610   $aPMSM
610   $aDOE
610   $aoptimization
610   $ametamodeling
610   $aadaptive robust control
610   $aenergy feedback
610   $aparticle swarm optimization
610   $atorque optimal distribution method
610   $amultiphase electric drives
610   $asix-phase machines
610   $afinite control set model predictive control
610   $apredictive current control
610   $apredictive torque control
610   $ahigh frequency square-wave voltage
610   $ainterior permanent-magnet synchronous motor (IPMSM)
610   $amagnetic polarity detection
610   $arotor position estimation
610   $acharacteristics analysis
610   $afault detection
610   $astator fault
610   $arotor fault
610   $atorque estimation
610   $afinite control set mode predictive control
610   $aduty cycle
610   $amaximum torque per ampere
610   $apermanent magnet synchronous motor
610   $aacoustics
610   $aboundary element method
610   $aelectric machines
610   $amagneto-mechanics
610   $amodeling
610   $anoise
610   $avibro-acoustics
610   $aefficiency
610   $aline-start synchronous reluctance motor
610   $apermanent magnet
610   $apower factor
610   $amultiphase
610   $ainduction
610   $amotor
610   $aspace harmonics
610   $atime harmonics
610   $ainjection
610   $ahigh-speed permanent synchronous motor
610   $amagnetic field characteristic
610   $airon loss
610   $astator structure
610   $aonline parameters estimation
610   $apermanent magnet synchronous machines
610   $asynchronous reluctance machines
610   $ahigh frequency signal injection
610   $aCMV
610   $amodulation techniques
610   $aPWM
610   $arailway traction drives
610   $ainduction motor drives
610   $ahigh-speed drives
610   $aovermodulation and six-step operation
610   $aelectrical motors
610   $asot filling factor
610   $aoptimization algorithm
610   $awindings
610   $amagnetic wire
610   $afilling factor optimization
610   $aelectric drive
610   $atransmission shaft
610   $aelectric transmission line
610   $aelectrical and mechanical similarities
610   $akinematic structure
610   $aequivalent circuit
610   $amathematical modelling
610   $afailure
610   $adetection
610   $adiagnosis
610   $aBLDC
610   $abrushless
610   $asystematic review
610   $arotor position
610   $aBLDC motor
610   $asensor misalignment
610   $asizing methodology
610   $aelectrical machines
610   $athermal model
610   $aelectromagnetic model
610   $aswitched reluctance motor
610   $atorque sharing functions
610   $afiring angle modulation
610   $aautonomous systems
610   $abrushless synchronous generator
610   $aelectric power generation
610   $ahigh speed generator
610   $ahigh resistance connection
610   $afault-detection
610   $afault-tolerant control
610   $asix-phase permanent magnet synchronous machines
610   $afield-oriented control
615  7$aHistory of engineering & technology
700   $aCruz$b Sérgio$4edt$01308055
702   $aCruz$b Sérgio$4oth
906   $aBOOK
912   $a9910674057703321
996   $aAdvances in Rotating Electric Machines$93029081
997   $aUNINA