Hu Ding

What is he best known for?

The fields of study he is best known for:

• Vibration
• Nonlinear system
• Mathematical analysis

The scientist’s investigation covers issues in Vibration, Nonlinear system, Galerkin method, Axial symmetry and Mechanics. His research in Vibration tackles topics such as Classical mechanics which are related to areas like Viscoelasticity. His Nonlinear system research is multidisciplinary, incorporating elements of Acoustics and Structural engineering.

His work deals with themes such as Vibration isolation, Beam, Timoshenko beam theory and Mathematical analysis, which intersect with Galerkin method. His research integrates issues of Transverse plane, Split-step method, Finite difference and Finite difference method in his study of Axial symmetry. His Mechanics research integrates issues from Harmonic balance, Multiple-scale analysis and Simple harmonic motion.

His most cited work include:

• Galerkin methods for natural frequencies of high-speed axially moving beams (104 citations)
• Convergence of Galerkin truncation for dynamic response of finite beams on nonlinear foundations under a moving load (77 citations)
• Integration of a nonlinear energy sink and a giant magnetostrictive energy harvester (66 citations)

What are the main themes of his work throughout his whole career to date?

Hu Ding focuses on Nonlinear system, Vibration, Mechanics, Mathematical analysis and Axial symmetry. The concepts of his Nonlinear system study are interwoven with issues in Stiffness and Boundary value problem. His Vibration research is multidisciplinary, incorporating perspectives in Beam, Finite difference method and Classical mechanics.

His studies deal with areas such as Amplitude, Cantilever, Bifurcation and Inertia as well as Mechanics. The study incorporates disciplines such as Transverse plane and Timoshenko beam theory in addition to Mathematical analysis. His Axial symmetry research includes themes of Critical speed, Time derivative, Multiple-scale analysis, Parametric oscillator and Constitutive equation.

He most often published in these fields:

• Nonlinear system (67.68%)
• Vibration (59.15%)
• Mechanics (35.37%)

What were the highlights of his more recent work (between 2019-2021)?

• Nonlinear system (67.68%)
• Vibration (59.15%)
• Stiffness (15.85%)

In recent papers he was focusing on the following fields of study:

His scientific interests lie mostly in Nonlinear system, Vibration, Stiffness, Acoustics and Harmonic balance. His study of Galerkin method is a part of Nonlinear system. His research in Vibration intersects with topics in Damper, Cantilever, Beam and Applied mathematics.

His Stiffness study combines topics in areas such as Negative stiffness, Vibration isolation, Bounded function and Control theory. His Harmonic balance study incorporates themes from Frequency response, Displacement and Boundary value problem, Mathematical analysis. His Mechanics research incorporates elements of Finite difference method, Bifurcation theory and Timoshenko beam theory.

Between 2019 and 2021, his most popular works were:

• Elimination of multimode resonances of composite plate by inertial nonlinear energy sinks (26 citations)
• Nonlinear vibration isolation via a circular ring (19 citations)
• Designs, analysis, and applications of nonlinear energy sinks (18 citations)

In his most recent research, the most cited papers focused on:

• Vibration
• Nonlinear system
• Mathematical analysis

His primary scientific interests are in Vibration, Nonlinear system, Harmonic balance, Acoustics and Stiffness. His biological study spans a wide range of topics, including Amplitude, Cantilever and Damper. Hu Ding works in the field of Nonlinear system, focusing on Galerkin method in particular.

His studies in Galerkin method integrate themes in fields like Beam, Bending, Axial symmetry and Stress. His research investigates the link between Acoustics and topics such as Frequency response that cross with problems in Stewart platform. His Stiffness research incorporates themes from Displacement, Vibration isolation and Control theory.

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