This book focuses on the computational analysis of nonlinear vibrations of structural members (beams, plates, panels, shells), where the studied dynamical problems can be reduced to the consideration of one spatial variable and time. The reduction is carried out based on a formal mathematical approach aimed at reducing the problems with infinite dimension to finite ones. The process also includes a transition from governing nonlinear partial differential equations to a set of finite number of ordinary differential equations.

Beginning with an overview of the recent results devoted to the analysis and control of nonlinear dynamics of structural members, placing emphasis on stability, buckling, bifurcation and deterministic chaos, simple chaotic systems are briefly discussed. Next, bifurcation and chaotic dynamics of the Euler–Bernoulli and Timoshenko beams including the geometric and physical nonlinearity as well as the elastic–plastic deformations are illustrated. Despite the employed classical numerical analysis of nonlinear phenomena, the various wavelet transforms and the four Lyapunov exponents are used to detect, monitor and possibly control chaos, hyper-chaos, hyper-hyper-chaos and deep chaos exhibited by rectangular plate-strips and cylindrical panels.

The book is intended for post-graduate and doctoral students, applied mathematicians, physicists, teachers and lecturers of universities and companies dealing with a nonlinear dynamical system, as well as theoretically inclined engineers of mechanical and civil engineering.

Contents:

• Bifurcational and Chaotic Dynamics of Simple Structural Members:
  • Beams
  • Plates
  • Panels
  • Shells
• Introduction to Fractal Dynamics:
  • Cantor Set and Cantor Dust
  • Koch Snowflake
  • 1D Maps
  • Sharkovsky's Theorem
  • Julia Set
  • Mandelbrot's Set
• Introduction to Chaos and Wavelets:
  • Routes to Chaos
  • Quantifying Chaotic Dynamics
• Simple Chaotic Models:
  • Introduction
  • Autonomous Systems
  • Non-Autonomous Systems
• Discrete and Continuous Dissipative Systems:
  • Introduction
  • Linear Friction
  • Nonlinear Friction
  • Hysteretic Friction
  • Impact Damping
  • Damping in Continuous 1D Systems
• Euler-Bernoulli Beams:
  • Introduction
  • Planar Beams
  • Linear Planar Beams and Stationary Temperature Fields
  • Curvilinear Planar Beams and Stationary Temperature and Electrical Fields
  • Beams with Elasto-Plastic Deformations
  • Multi-Layer Beams
• Timoshenko and Sheremetev-Pelekh Beams:
  • The Timoshenko Beams
  • The Sheremetev-Pelekh Beams
  • Concluding Remarks
• Panels:
  • Infinite Length Panels
  • Cylindrical Panels of Infinite Length
• Plates and Shells:
  • Plates with Initial Imperfections
  • Flexible Axially-Symmetric Shells

Readership: Post-graduate and doctoral students, applied mathematicians, physicists, mechanical and civil engineers.
Bifurcation;Chaos;Structural Members;PDEs and ODEs;Lyapunov Exponents;Wavelets Key Features:

• Includes fascinating and rich dynamics exhibited by simple structural members and by the solution properties of the governing 1D non-linear PDEs, suitable for applied mathematicians and physicists
• Covers a wide variety of the studied PDEs, their validated reduction to ODEs, classical and non-classical methods of analysis, influence of various boundary conditions and control parameters, as well as the illustrative presentation of the obtained results in the form of colour 2D and 3D figures and vibration type charts and scales
• Contains originally discovered, illustrated and discussed novel and/or modified classical scenarios of transition from regular to chaotic dynamics exhibited by 1D structural members, showing a way to control chaotic and bifurcational dynamics, with directions to study other dynamical systems modeled by chains of nonlinear oscillators