From the reviews of the first edition:

"This is a very useful book for the analysis of vibro-impact systems. It is written in the great Russian tradition of mechanics entwined with mathematics, but the fundamental introductions of the chapters always lead to explicit calculational schemes. ... As a whole this book is a good introduction to a very important part of engineering mathematics." (Ferdinand Verhulst, SIAM Reviews, Vol. 45 (2), 2003)

"This book deals with periodic vibrations of strongly nonlinear dynamical systems, with special attention to mechanical systems with impacts, which are investigated for their own relevance and as approximations of other strongly nonlinear systems. ... The book is well organized and the arguments are illustrated in a sequential and logical order." (Meccanica, Vol. 39, 2004)

"In this book, first published in Russian, analytic approaches are presented for the description of strongly nonlinear mechanical systems with the solution of non-linear second order differential equations arising in leading to time-periodicity of the coefficients in the different equations. ... The text is fluent and well illustrated." (European Journal of Mechanical and Environmental Engineering, Vol. 47 (4), 2002/2003)

"This book investigates vibrations of nonlinear mechanical systems characterized by the presence of threshold nonlinear positional forces. ... In the reviewer opinion, the book presents many original solutions of dynamical problems for strongly nonlinear systems, and thus may be considered as a first systematical description of the theory of vibrations of strongly nonlinear systems with lumped parameters." (Yuri N. Sankin, Zentralblatt MATH, Vol. 997 (22), 2002)

1 Operators of Linear Systems.- §1. Dynamic Compliance.- 1.1. Operator of Mechanical System.- 1.2 Fundamental Features of the Generalised Dirac ?-function.- 1.3. Green Functions for Systems with Lumped Parameters.- 1.4. Operator of Dynamic Compliance.- 1.5. The Eigenmode Decomposition of the Dynamic Compliance Operator.- 1.6. Linear System as a Low-pass Filter.- 1.7. Linear Single-Degree-of-Freedom System.- 1.8. Operators of Rod Systems.- 1.9. Expression of Forces Through Operator Functions.- 1.10. Some Generalisations.- §2. Periodic Green Functions.- 2.1. Periodic Generalised Functions.- 2.2. Periodic Green Functions.- 2.3. Features of Periodic Green Functions.- 2.4. Periodic Green Function on the Interval of Periodicity.- 2.5. Single-Degree-of-Freedom System.- 2.6. Eigenfunction Expansion of PGF.- 2.7. Steady-state Motion.- 2.8. Representation of PGF in the Form of Fast Convergent Fourier Series.- §3 Parametric Periodic Green Functions.- 3.1. Integral Equations of Periodic Vibration.- 3.2. Integral Fredholm Equations.- 3.3. Description of Parametric Periodic Green Functions.- 3.4. Excitation of Parametric Vibration by Impacts.- 2 Strongly Nonlinear Single-Degree-of Freedom Systems.- §4 Conservative Systems.- 4.1. Classification of Nonlinear Systems.- 4.2. Equations of Conservative Systems.- 4.3. Vibro-impact Systems.- 4.4. Singular Force of Impact.- 4.5. Motions of Vibro-impact Systems.- 4.6. Strongly Nonlinear Systems.- 4.7. Strongly Nonlinear Systems of Threshold Type.- 4.8. Singularisation.- 4.9. Improved Singularisation.- 4.10. Piecewise Linear Force of Threshold Type.- 4.11. Threshold-type Force Defined by the Power Function.- 4.12. Symmetric Threshold-type Forces.- §5 Forced Vibration.- 5.1. Problem Statement.- 5.2. Change of Variables.- 5.3. Resonant Processes.- 5.4. Averaging in Systems with Impact Interactions.- 5.5. Steady-state Vibration and Stability.- 5.6. Vibro-impact Systems Under Harmonic Excitation.- 5.7. Exact Laws of Motion of Vibro-impact Systems.- 5.8. Resonance Vibration of a System with Piecewise Restoring Force.- 5.9. Piecewise Power Restoring Force.- 5.10. Principle of Energy Balance.- 5.11. Conditions of Existence of Resonant Regimes under Harmonic Excitation.- 5.12. Bifurcation of Fundamental Resonant Regimes under Polyharmonic Excitation.- 5.13. Bifurcation of Solutions in Vibro-impact System.- 5.14. Analysis of Superperiodic and Combination Resonances.- §6 Vibration in Autonomous Systems.- 6.1. Preliminary Considerations.- 6.2. Analysis of Autonomous Systems using the Averaging Method.- 6.3. Chatter.- 6.4. Analysis of the Autoresonant System.- 6.5. Quasi-isochronous Approximation.- 6.6. Symmetric Systems.- §7 Parametric Vibration.- 7.1. Preliminary Considerations.- 7.2. Resonant Regimes Outside the Zones of Instability of a Linear System.- 7.3. Integral Equation of Parametric Vibration.- 7.4. Resonant Regimes within the Zone of Instability of Linear Systems.- 7.5. Parametric Systems with Force Excitation.- 7.6. Energy Condition of Instability.- 7.7. Mathieu Equation with Strong Nonlinearity.- 7.8. System with Symmetric Nonlinearity.- 7.9. Calculations for Systems under Combined Excitation.- 7.10. Bifurcation of Regimes in Parametric Systems.- 7.11. Explicit Solutions to a Specific Class of Model Problems.- §8 Random Vibration.- 8.1. Preliminary Considerations.- 8.2. Some Exact Solutions.- 8.3. Random Vibration in Self-sustained System with Small Clearance.- 8.4. Contact Damping.- 8.5. Deviations from Solutions of Averaged Systems.- 8.6. Quasi-resonant Regimes.- 8.7. Parametric Systems in a Quasi-isochronous Approximation.- 8.8. Perturbed Periodic Green Functions.- 8.9. Application of Perturbed Periodic Green Functions to the Analysis of a Vibro-impact system.- 8.10. Narrowband Excitation.- 3 Multiple-Degree-of-Freedom Systems.- §9 Forced Vibration in Multiple-Degree-of-Freedom Systems.- 9.1. Preliminary Considerations.- 9.2. Integro-differential Equation of Periodic Regimes in System of Two Strongly Interacting Linear Subsystems.- 9.3. Newtonian Interaction.- 9.4. Principle of Energy Balance.- 9.5. Singularisation.- 9.6. Interaction of Two Systems with Lumped Parameters.- 9.7. Interaction of Rod Systems.- 9.8. Resonant Regimes in Systems with Arbitrary Dynamic Compliance Operators.- 9.9. Quasi-resonant Regimes.- 9.10. Analysis of Multi-dimensional Systems using Markov Processes.- 9.11 Systems with Relaxation.- 9.12. Single-frequency Vibration in Systems Given by the Operator Equation.- 9.13. Analysis of Symmetric Systems.- §10 Parametric Vibration in the Multiple-Degree-of-Freedom Systems.- 10.1. Method of Analysis.- 10.2. Equation of Energy Balance.- 10.3. Auxiliary Analysis.- 10.4. The Second Approximation for Impact Impulse.- 10.5. Parametric Vibration of an Oscillator Suspended Inertially Inside a Container.- 10.6. Dynamics of Vibro-impact Mechanisms Mounted on a Vibrating Base.- Additional Bibliography.- Appendix I The Averaging Method in Systems with Impacts.- Appendix II On the Analysis of Resonant Vibration of Vibro-impact Systems Using the Averaging Technique.- Appendix III Structure-borne Vibroimpact Resonances and Periodic Green Functions.- Appendix IV Nonlinear Correction of a Vibration Protection System Containing Tuned Dynamic Absorber.

Among the wide variety of nonlinear mechanical systems, it is possible to distinguish a representative class, which may be characterised by the presence of threshold nonlinear positional forces. Such discontinuous systems demonstrate a sudden and essential change in the behaviour of elastic and dissipative forces within every cycle of vibration. This monograph addresses the systematic representation of the methods of analysis developed by the authors as applied to such systems. Particular features of dynamic processes in such systems are studied. Special attention is given to an analysis of different resonant phenomena taking unusual and diverse forms. All solutions are transformed to the final analytical expressions allowing clear mechanical interpretation. These methods are applied to the analysis of mechanical systems designed for the generation and transformation of intensive impulsive processes or structures exposed to such a nonlinear dynamic loading. These are vibro-impact processes due to intermittent unilateral contacts of the structure elements, created by backlashes in joints and kinematic pairs, during opening and closing of cracks etc. New mechanical effects are described. Some engineering problems are solved using a combination of analytical technique and modern simulation tools.