What is she best known for?
The fields of study she is best known for:
- Electrical engineering
- Mechanical engineering
- Control theory
Elena A. Lomonova mainly investigates Actuator, Magnet, Control theory, Finite element method and Electromagnetic coil.
Her Actuator study combines topics from a wide range of disciplines, such as Electromagnetic suspension and Magnetic levitation.
Her Magnet research includes elements of Commutation, Torque, Stator, Magnetic flux and Nuclear magnetic resonance.
Her Control theory research integrates issues from Electric vehicle, Space mapping, Traction, Voice coil and Rotor.
The concepts of her Finite element method study are interwoven with issues in Equivalent circuit, Classical mechanics, Maximum torque, Electronic engineering and Counter-electromotive force.
Her studies in Electromagnetic coil integrate themes in fields like Printed circuit board, Topology and Inductance.
Her most cited work include:
- General Formulation of the Electromagnetic Field Distribution in Machines and Devices Using Fourier Analysis (189 citations)
- Active Electromagnetic Suspension System for Improved Vehicle Dynamics (177 citations)
- Modeling of Magnetically Levitated Planar Actuators With Moving Magnets (136 citations)
What are the main themes of her work throughout her whole career to date?
Her primary areas of study are Magnet, Finite element method, Actuator, Control theory and Electromagnetic coil.
Her work deals with themes such as Torque, Stator and Nuclear magnetic resonance, which intersect with Magnet.
Her research in Finite element method intersects with topics in Mathematical analysis, Equivalent circuit, Magnetic flux, Mechanics and Electronic engineering.
Elena A. Lomonova has researched Actuator in several fields, including Automotive engineering, Electromagnetic suspension, Magnetic bearing and Electropermanent magnet.
Her studies deal with areas such as Magnetic reluctance, Commutation, Topology and Rotor as well as Control theory.
In her study, Synchronous motor is inextricably linked to Linear motor, which falls within the broad field of Electromagnetic coil.
She most often published in these fields:
- Magnet (32.72%)
- Finite element method (27.97%)
- Actuator (27.24%)
What were the highlights of her more recent work (between 2016-2021)?
- Finite element method (27.97%)
- Electromagnetic coil (17.00%)
- Control theory (25.96%)
In recent papers she was focusing on the following fields of study:
Elena A. Lomonova spends much of her time researching Finite element method, Electromagnetic coil, Control theory, Mathematical analysis and Magnet.
Her work carried out in the field of Finite element method brings together such families of science as Transformer, Computation, Eddy current and Harmonic.
Her Electromagnetic coil study combines topics from a wide range of disciplines, such as Superconductivity, Condensed matter physics and Linear motor.
Her Control theory study combines topics in areas such as Torque ripple, Direct torque control and Magnetic reluctance.
The study incorporates disciplines such as Actuator and Nonlinear system in addition to Magnetic reluctance.
Her study with Magnet involves better knowledge in Mechanical engineering.
Between 2016 and 2021, her most popular works were:
- Comparative analysis of various methods for modelling surface permanent magnet machines (17 citations)
- AC losses in HTS coils for high-frequency and non-sinusoidal currents (13 citations)
- Quad active-bridge single-stage bidirectional three-phase AC-DC converter with isolation: introduction and optimized modulation (13 citations)
In her most recent research, the most cited papers focused on:
- Electrical engineering
- Mechanical engineering
- Control theory
Elena A. Lomonova focuses on Finite element method, Control theory, Magnet, Magnetostatics and Inverter.
She has researched Finite element method in several fields, including Mechanics and Fourier series, Boundary value problem, Mathematical analysis.
Her work deals with themes such as Magnetic reluctance, Inertia, Stator, Electromagnetic coil and Rotor, which intersect with Control theory.
Her Magnet study is associated with Mechanical engineering.
Her research in Magnetostatics intersects with topics in Computational physics and Magnetic potential.
Her Inverter study incorporates themes from Electric machine, Power electronics and Torque, Drivetrain.
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