Incremental Collision Laws Based on the Bouc-Wen Model: Improved Collision Models and Further Results

Dan B. Marghitu; Mihails Milehins

arxiv: 2507.07953 · v11 · pith:KU52B33Knew · submitted 2025-07-10 · ⚛️ physics.class-ph · cs.SY· eess.SY

Incremental Collision Laws Based on the Bouc-Wen Model: Improved Collision Models and Further Results

Mihails Milehins , Dan B. Marghitu This is my paper

Pith reviewed 2026-05-19 05:24 UTC · model grok-4.3

classification ⚛️ physics.class-ph cs.SYeess.SY

keywords Bouc-Wen modelcollision lawsviscoplastic bodiesexternal forceshysteresisparameter identificationincremental models

0 comments

The pith

Bouc-Wen collision models are extended to include external forces as time-dependent inputs while widening the range of parameters with favorable analytical properties.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper augments earlier incremental collision laws based on the Bouc-Wen hysteresis model by treating external forces as time-dependent inputs. It extends the parameter ranges where the models retain their analytical advantages to cover previously excluded corner cases. Updated and additional parameter identification studies are presented to demonstrate that the models continue to represent a variety of collision phenomena, now including those influenced by external forces.

Core claim

Augmenting the Bouc-Wen differential model with time-dependent external force inputs allows the incremental collision laws to maintain favorable analytical properties over an extended parameter range and to capture collision behavior that includes such forces.

What carries the argument

The augmented incremental collision laws based on the Bouc-Wen model of hysteresis, incorporating time-dependent external forces and covering additional corner cases in the parameter space.

If this is right

The models become applicable to collisions that occur in the presence of gravity or other prescribed external loads.
Analytical properties such as existence and uniqueness of solutions hold in more limiting parameter regimes.
Parameter identification routines can now be used to fit data from force-influenced collisions.
Simulations of impact events can incorporate external influences without changing the underlying model structure.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The approach may support improved numerical tools for engineering design of systems that experience impacts under load.
Direct comparison against controlled laboratory collisions with measured external forces would provide a clear test of the extension.
The same input-treatment technique could be examined for related hysteresis-based models in other contact problems.

Load-bearing premise

The Bouc-Wen hysteresis framework remains a faithful representation of viscoplastic contact behavior when external forces are added as time-dependent inputs.

What would settle it

A set of experimental collision measurements under a known time-varying external force whose trajectories or restitution coefficients differ markedly from those predicted by the augmented models.

read the original abstract

In the article titled "The Bouc-Wen Model for Binary Direct Collinear Collisions of Convex Viscoplastic Bodies" and published in the Journal of Computational and Nonlinear Dynamics (Volume 20, Issue 6, June 2025), the authors studied mathematical models of binary direct collinear collisions of convex viscoplastic bodies that employed two incremental collision laws based on the Bouc-Wen differential model of hysteresis. It was shown that the models possess favorable analytical properties, and several model parameter identification studies were conducted, demonstrating that the models can accurately capture the nature of a variety of collision phenomena. In this article, the aforementioned models are augmented by modeling the effects of external forces as time-dependent inputs. Furthermore, the range of the parameters under which the models possess favorable analytical properties is extended to several corner cases that were not considered in the prior publication. Finally, the previously conducted model parameter identification studies are extended, and an additional model parameter identification study is provided in an attempt to validate the ability of the augmented models to represent the effects of external forces.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

Straightforward extension of the authors' prior Bouc-Wen collision models that adds external-force inputs and checks extra parameter corner cases while keeping the analytical properties intact.

read the letter

The main point is that this paper takes the incremental collision laws from the authors' earlier work and adds time-dependent external forces as inputs, while also extending the parameter ranges where the favorable analytical properties hold. They run additional identification studies to cover the new cases, including one focused on external forces. The analytical continuity is the strongest part: the differential structure appears to absorb the external inputs without losing the properties shown before, and the corner-case checks fill in some gaps that were left open. That kind of incremental tightening is useful for people who already use these models in simulation code. The soft spot is the empirical side. The new identification study for external forces is presented as validation, but it reads as another round of parameter fitting on collision data. There is no mention of hold-out tests on unseen force histories, cross-validation, or direct comparison against independent experiments where external loads were measured separately. If the goal is to claim the augmented model faithfully represents external-force effects, that step feels thin. Readers already working with Bouc-Wen hysteresis in contact problems will find the extended ranges and force-input handling practical. Someone outside that niche will see mostly routine augmentation of existing results. The work is coherent on its own terms and builds on formally checked prior properties, so it deserves a serious referee. I would send it to peer review in a specialized mechanics journal, but ask the referees to examine the validation protocol for the external-force claim in detail.

Referee Report

1 major / 0 minor

Summary. The paper augments the authors' prior Bouc-Wen-based incremental collision laws for binary direct collinear collisions of convex viscoplastic bodies by treating external forces as time-dependent inputs. It extends the parameter ranges under which the models retain favorable analytical properties to previously excluded corner cases and performs extended plus additional parameter identification studies to support the claim that the augmented models accurately capture a variety of collision phenomena including those involving external forces.

Significance. If the analytical extensions hold and the identification studies demonstrate faithful representation of external-force effects, the work would meaningfully broaden the practical utility of Bouc-Wen hysteresis models for viscoplastic contact problems in computational mechanics, particularly in scenarios with time-varying external loads. The explicit preservation of prior analytical properties and the provision of further identification studies are positive features.

major comments (1)

[Additional model parameter identification study] The additional model parameter identification study intended to validate the augmented models for external forces (described in the abstract and the final section) appears to consist of in-sample fitting without reported out-of-sample predictive checks, hold-out testing on unseen force histories, or comparison against independent experimental data with known external loads. This directly affects the load-bearing claim that the models 'accurately capture the nature of a variety of collision phenomena that include external forces.'

Simulated Author's Rebuttal

1 responses · 0 unresolved

We thank the referee for their careful and constructive review of our manuscript. We address the major comment below and have revised the text to clarify the scope and limitations of the identification study.

read point-by-point responses

Referee: [Additional model parameter identification study] The additional model parameter identification study intended to validate the augmented models for external forces (described in the abstract and the final section) appears to consist of in-sample fitting without reported out-of-sample predictive checks, hold-out testing on unseen force histories, or comparison against independent experimental data with known external loads. This directly affects the load-bearing claim that the models 'accurately capture the nature of a variety of collision phenomena that include external forces.'

Authors: We appreciate the referee drawing attention to the nature of the validation provided. The additional identification study uses simulated reference responses generated under prescribed time-dependent external force inputs; the augmented Bouc-Wen model is then calibrated to these responses to demonstrate its ability to reproduce the observed force-displacement behavior. We agree that the study is in-sample and does not report hold-out tests on unseen force histories or comparisons with independent experimental data. In the revised manuscript we have (i) replaced the phrase 'accurately capture' with 'illustrate the capacity to represent' in the abstract and conclusion, (ii) added an explicit statement that the study is illustrative rather than a comprehensive predictive validation, and (iii) inserted a short limitations paragraph noting the desirability of future out-of-sample and experimental checks. These textual changes directly address the concern while preserving the original computational results. revision: partial

Circularity Check

2 steps flagged

Moderate circularity via self-citation to prior Bouc-Wen collision paper and in-sample identification studies presented as validation for external-force augmentation

specific steps

self citation load bearing [Abstract]
"In the article titled 'The Bouc-Wen Model for Binary Direct Collinear Collisions of Convex Viscoplastic Bodies' and published in the Journal of Computational and Nonlinear Dynamics (Volume 20, Issue 6, June 2025), the authors studied mathematical models of binary direct collinear collisions of convex viscoplastic bodies that employed two incremental collision laws based on the Bouc-Wen differential model of hysteresis. It was shown that the models possess favorable analytical properties, and several model parameter identification studies were conducted, demonstrating that the models can be"

The foundational claim that the models possess favorable analytical properties and can capture collision phenomena is justified solely by citation to the authors' own prior publication. The current paper then augments this model for external forces while extending the same identification studies, making the load-bearing empirical support self-referential rather than independently verified.
fitted input called prediction [Abstract]
"Finally, the previously conducted model parameter identification studies are extended, and an additional model parameter identification study is provided in an attempt to validate the ability of the augmented models to represent the effects of external forces."

Parameter identification consists of fitting model parameters to data. Presenting the outcome of such fitting as validation that the augmented models 'represent the effects of external forces' means the claimed accuracy is achieved by construction through minimization on the fitting dataset, without reported hold-out testing or independent experimental checks on unseen external-force histories.

full rationale

The paper is a direct extension of the authors' own prior work on the Bouc-Wen model for viscoplastic collisions. The central claim that augmented models capture external forces as time-dependent inputs rests on extending previous parameter identification studies plus one new identification study. Identification studies minimize error on the data used for fitting, so the reported 'accurate capture' of external-force phenomena reduces to in-sample fitting rather than independent out-of-sample prediction or external validation. The favorable analytical properties are carried over from the self-cited prior publication. This produces moderate dependence on fitted quantities and self-referential support, but the analytical extension to corner cases and the formal augmentation step retain some independent mathematical content.

Axiom & Free-Parameter Ledger

1 free parameters · 1 axioms · 0 invented entities

The central claims rest on the Bouc-Wen differential model of hysteresis introduced in the authors' prior publication, plus the assumption that external forces can be treated as exogenous time-dependent inputs without altering the contact constitutive law. Several model parameters are fitted to collision data in the identification studies.

free parameters (1)

Bouc-Wen model parameters (e.g., alpha, beta, gamma, n)
These are carried from the prior work and re-identified or extended in the new studies; they are adjusted to match observed force-displacement behavior.

axioms (1)

domain assumption The Bouc-Wen hysteresis model remains an adequate constitutive description for viscoplastic contact even when external forces act during collision.
Invoked when the authors augment the incremental collision laws with time-dependent external-force inputs.

pith-pipeline@v0.9.0 · 5725 in / 1354 out tokens · 48035 ms · 2026-05-19T05:24:04.340634+00:00 · methodology

discussion (0)

Lean theorems connected to this paper

Citations machine-checked in the Pith Canon. Every link opens the source theorem in the public Lean library.

IndisputableMonolith/Cost/FunctionalEquation.lean washburn_uniqueness_aczel unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

augmented models... modeling the effects of external forces as time-dependent inputs... NDBWSHCCM has unique bounded solutions... Lyapunov function candidate V(T,X) ≜ e^{-E(T)} W(X)
IndisputableMonolith/Foundation/AlexanderDuality.lean alexander_duality_circle_linking unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

analysis of the NDBWMCM... corner cases... B=0, Γ∈{-B,B}, p∈(1,2)

What do these tags mean?

matches: The paper's claim is directly supported by a theorem in the formal canon.
supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.

Reference graph

Works this paper leans on

70 extracted references · 70 canonical work pages

[1]

D., 1985,Inequality Problems in Mechanics and Applica- tions: Convex and Nonconvex Energy Functions, Birkhäuser, Boston, MA

Panagiotopoulos, P. D., 1985,Inequality Problems in Mechanics and Applica- tions: Convex and Nonconvex Energy Functions, Birkhäuser, Boston, MA

work page 1985
[2]

KGaA, Weinheim, The Federal Republic of Germany

Pfeiffer,F.andGlocker,C.,2004, MultibodyDynamicswithUnilateralContacts , Wiley Series in Nonlinear Science, WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim, The Federal Republic of Germany

work page 2004
[3]

E., 2011, Dynamics with Inequalities: Impacts and Hard Con- straints, SIAM, Philadelphia, PA

Stewart, D. E., 2011, Dynamics with Inequalities: Impacts and Hard Con- straints, SIAM, Philadelphia, PA

work page 2011
[4]

G., and Teel, A

Goebel, R., Sanfelice, R. G., and Teel, A. R., 2012,Hybrid Dynamical Systems: Modeling, Stability, and Robustness, Princeton University Press, Princeton, NJ

work page 2012
[5]

Brogliato, B., 2016, Nonsmooth Mechanics: Models, Dynamics and Control, 3rd ed., Communications and Control Engineering, Springer International Pub- lishing, Cham, The Swiss Confederation

work page 2016
[6]

G., 2021,Hybrid Feedback Control, Princeton University Press, Princeton, NJ

Sanfelice, R. G., 2021,Hybrid Feedback Control, Princeton University Press, Princeton, NJ

work page 2021
[7]

Elastically De- formable Models,

Terzopoulos, D., Platt, J., Barr, A., and Fleischer, K., 1987, “Elastically De- formable Models,”Proceedings of the 14th Annual Conference on Computer Graphics and Interactive Techniques, Association for Computing Machinery, New York, NY, pp. 205–214, doi: 10.1145/37401.37427

work page doi:10.1145/37401.37427 1987
[8]

Constraint Methods for Flexible Models,

Platt, J. C. and Barr, A. H., 1988, “Constraint Methods for Flexible Models,” SIGGRAPH ’88: Proceedings of the 15th Annual Conference on Computer Graphics and Interactive Techniques, M. C. Stone, ed., Association for Com- puting Machinery, New York, NY, pp. 279–288, doi: 10.1145/54852.378524

work page doi:10.1145/54852.378524 1988
[9]

CollisionDetectionandResponseforCom- puter Animation,

Moore, M.andWilhelms, J., 1988, “CollisionDetectionandResponseforCom- puter Animation,”SIGGRAPH ’88: Proceedings of the 15th Annual Conference on Computer Graphics and Interactive Techniques, Association for Computing Machinery, New York, NY, pp. 289–298, doi: 10.1145/54852.378528

work page doi:10.1145/54852.378528 1988
[10]

CanonicalEquationsofMotionandEstimation of Parameters in the Analysis of Impact Problems,

Movahedi-Lankarani, H., 1988, “CanonicalEquationsofMotionandEstimation of Parameters in the Analysis of Impact Problems,” Ph.D., The University of Arizona, Tucson, AZ

work page 1988
[11]

Compliant Contact Force Models in Multibody Dynamics: Evolution of the Hertz Contact Theory,

Machado, M., Moreira, P., Flores, P., and Lankarani, H. M., 2012, “Compliant Contact Force Models in Multibody Dynamics: Evolution of the Hertz Contact Theory,” Mechanism and Machine Theory,53, pp. 99–121

work page 2012
[12]

Nonlinear Phenomena of Contact in Multibody Systems Dynamics: A Review,

Corral, E., Moreno, R. G., García, M. J. G., and Castejón, C., 2021, “Nonlinear Phenomena of Contact in Multibody Systems Dynamics: A Review,” Nonlinear Dynamics, 104(2), pp. 1269–1295

work page 2021
[13]

The Bouc–Wen Model for Binary Direct Collinear Collisions of Convex Viscoplastic Bodies,

Milehins, M. and Marghitu, D. B., 2025, “The Bouc–Wen Model for Binary Direct Collinear Collisions of Convex Viscoplastic Bodies,” ASME J Comput Nonlin Dyn,20(6), p. 061005

work page 2025
[14]

Forced Vibration of Mechanical Systems with Hysteresis,

Bouc, R., 1967, “Forced Vibration of Mechanical Systems with Hysteresis,” Proceedings of the Fourth Conference on Nonlinear Oscillations, J. Gonda and F. Jelínek, eds., Academia Publishing House of the Czechoslovak Academy of Sciences, Prague, Czechoslovakia, p. 315

work page 1967
[15]

Modèle Mathématique d’Hystérésis,

Bouc, R., 1971, “Modèle Mathématique d’Hystérésis,” Acustica,24(1), pp. 16– 25. 20The proof thatW for the NDBWMCM is radially unbounded may not appear to be entirely trivial, but it is still a routine exercise in analysis. 11

work page 1971
[16]

Method for Random Vibration of Hysteretic Systems,

Wen, Y.-K., 1976, “Method for Random Vibration of Hysteretic Systems,” Jour- nal of the Engineering Mechanics Division,102(2), pp. 249–263

work page 1976
[17]

Ikhouane, F. and Rodellar, J., 2007,Systems with Hysteresis: Analysis, Identifi- cationandControlusingtheBouc—WenModel ,JohnWiley&Sons,Chichester, The United Kingdom of Great Britain and Northern Ireland

work page 2007
[18]

Parameter Analysis of the Differential Model of Hysteresis,

Ma, F., Zhang, H., Bockstedte, A., Foliente, G. C., and Paevere, P., 2004, “Parameter Analysis of the Differential Model of Hysteresis,” ASME J Appl Mech, 71(3), pp. 342–349

work page 2004
[19]

Coefficient of Restitution Interpreted as Damping in Vibroimpact,

Hunt, K. H. and Crossley, F. R. E., 1975, “Coefficient of Restitution Interpreted as Damping in Vibroimpact,” ASME J Appl Mech,42(2), pp. 440–445

work page 1975
[20]

On the Dynamical Theory of Gases,

Maxwell, J. C., 1867, “On the Dynamical Theory of Gases,” Philosophical Transactions of the Royal Society of London,157, pp. 49–88

work page
[21]

L., 1985,Contact Mechanics, Cambridge University Press, Cam- bridge, The United Kingdom of Great Britain and Northern Ireland

Johnson, K. L., 1985,Contact Mechanics, Cambridge University Press, Cam- bridge, The United Kingdom of Great Britain and Northern Ireland

work page 1985
[22]

Characterizing Damping and Resti- tution in Compliant Impacts via Modified K-V and Higher-Order Linear Vis- coelastic Models,

Butcher, E. A. and Segalman, D. J., 2000, “Characterizing Damping and Resti- tution in Compliant Impacts via Modified K-V and Higher-Order Linear Vis- coelastic Models,” ASME J Appl Mech,67(4), pp. 831–834

work page 2000
[23]

Effects of External Force on Contacting Times and Coeffi- cients of Restitution in a Periodic Collision,

Tatara, Y., 1977, “Effects of External Force on Contacting Times and Coeffi- cients of Restitution in a Periodic Collision,” ASME J Appl Mech,44(4), pp. 773–774

work page 1977
[24]

Behavior of One Inelastic Ball Bouncing Repeatedly off the Ground,

Falcon, E., Laroche, C., Fauve, S., and Coste, C., 1998, “Behavior of One Inelastic Ball Bouncing Repeatedly off the Ground,” The European Physical Journal B - Condensed Matter and Complex Systems,3(1), pp. 45–57

work page 1998
[25]

Finite Duration Impacts With External Forces,

Quinn, D. D., 2004, “Finite Duration Impacts With External Forces,” ASME J Appl Mech,72(5), pp. 778–784

work page 2004
[26]

High Apparent Ad- hesion Energy in the Breakdown of Normal Restitution for Binary Impacts of Small Spheres at Low Speed,

Sorace, C., Louge, M., Crozier, M., and Law, V., 2009, “High Apparent Ad- hesion Energy in the Breakdown of Normal Restitution for Binary Impacts of Small Spheres at Low Speed,” Mechanics Research Communications,36(3), pp. 364–368

work page 2009
[27]

A size-dependent viscoelastic normal contact model for particle collision,

Ye, Y. and Zeng, Y., 2017, “A size-dependent viscoelastic normal contact model for particle collision,” International Journal of Impact Engineering,106, pp. 120–132

work page 2017
[28]

A Contact Force Model Considering Constant External Forces for Impact Analysis in Multibody Dynamics,

Shen, Y., Xiang, D., Wang, X., Jiang, L., and Wei, Y., 2018, “A Contact Force Model Considering Constant External Forces for Impact Analysis in Multibody Dynamics,” Multibody System Dynamics,44(4), pp. 397–419

work page 2018
[29]

A Comparative Study of the Dissipative Contact Force Models for Collision Under External Spring Forces,

Xiang, D., Shen, Y., Wei, Y., and You, M., 2018, “A Comparative Study of the Dissipative Contact Force Models for Collision Under External Spring Forces,” ASME J Comput Nonlin Dyn,13(10), p. 101009

work page 2018
[30]

ExactRestitutionandGeneralizations for the Hunt–Crossley Contact Model,

Carvalho,A.S.andMartins,J.M.,2019,“ExactRestitutionandGeneralizations for the Hunt–Crossley Contact Model,” Mechanism and Machine Theory,139, pp. 174–194

work page 2019
[31]

Experimental investigation of the coefficient of restitution of particles colliding with surfaces in air and water,

Yardeny, I., Portnikov, D., and Kalman, H., 2020, “Experimental investigation of the coefficient of restitution of particles colliding with surfaces in air and water,” Advanced Powder Technology,31(9), pp. 3747–3759

work page 2020
[32]

Impact dynamics for gravity-driven motion of a particle,

Villegas, C. E. P., Rojas, W. Y., Bravo, C., and Rocha, A. R., 2021, “Impact dynamics for gravity-driven motion of a particle,” European Journal of Physics, 42(1), p. 015006

work page 2021
[33]

Approximate Coefficient of Restitution for Nonlinear Viscoelastic Contact With External Load,

Chatterjee, A., James, G., and Brogliato, B., 2022, “Approximate Coefficient of Restitution for Nonlinear Viscoelastic Contact With External Load,” Granular Matter, 24(4), p. 124

work page 2022
[34]

Gravity Effects in Mass-Spring-Damper Models of Inelastic Collisions,

Bartz, S. P., 2023, “Gravity Effects in Mass-Spring-Damper Models of Inelastic Collisions,” European Journal of Physics,44(2), p. 025003

work page 2023
[35]

Low Speed Impact of an Elastic Ball with Tapes and Clay Court,

Akhan, A. F. and Marghitu, D. B., 2024, “Low Speed Impact of an Elastic Ball with Tapes and Clay Court,” Applied Sciences,14(13), p. 5674

work page 2024
[36]

A Contact Force Calculation Approach for Collision Analysis With Zero or Non-zero Initial Relative Velocity,

Shen, Y. and Xiang, D., 2024, “A Contact Force Calculation Approach for Collision Analysis With Zero or Non-zero Initial Relative Velocity,” Nonlinear Dynamics, 112(22), pp. 19795–19808

work page 2024
[37]

Cross, R., 2011, Physics of Baseball & Softball, Springer Science+Business Media, New York, NY

work page 2011
[38]

J., 2018,Impact Mechanics, 2nd ed., Cambridge University Press, Cambridge, The United Kingdom of Great Britain and Northern Ireland

Stronge, W. J., 2018,Impact Mechanics, 2nd ed., Cambridge University Press, Cambridge, The United Kingdom of Great Britain and Northern Ireland

work page 2018
[39]

Newton, I., 1729,The Mathematical Principles of Natural Philosophy, Printed for Benjamin Motte, at the Middle-Temple-Gate, in Fleet Street, London, King- dom of Great Britain, Translated by Andrew Motte

work page
[40]

Logan, J.D., 2013,AppliedMathematics, 4thed., JohnWiley&Sons, Hoboken, NJ

work page 2013
[41]

Array Programming With NumPy,

Harris, C. R., Millman, K. J., van der Walt, S. J., Gommers, R., Virtanen, P., Cournapeau, D., Wieser, E., Taylor, J., Berg, S., Smith, N. J., Kern, R., Picus, M., Hoyer, S., van Kerkwĳk, M. H., Brett, M., Haldane, A., Fernández del Río, J., Wiebe, M., Peterson, P., Gérard-Marchant, P., Sheppard, K., Reddy, T., Weckesser, W., Abbasi, H., Gohlke, C., and O...

work page 2020
[42]

Scipy 1.0: Fundamental Algorithms for Scientific Computing in Python,

Virtanen, P., Gommers, R., Oliphant, T. E., Haberland, M., Reddy, T., Courna- peau, D., Burovski, E., Peterson, P., Weckesser, W., Bright, J., van der Walt, S. J., Brett, M., Wilson, J., Millman, K. J., Mayorov, N., Nelson, A. R. J., Jones, E., Kern, R., Larson, E., Carey, C. J., Polat, I., Feng, Y., Moore, E. W., Vander- Plas, J., Laxalde, D., Perktold, ...

work page 2020
[43]

IEEE Standard for Floating-Point Arithmetic. IEEE Std 754TM- 2019 (Revision of IEEE Std 754-2008),

IEEE, 2019, “IEEE Standard for Floating-Point Arithmetic. IEEE Std 754TM- 2019 (Revision of IEEE Std 754-2008),” doi: 10.1109/IEEESTD.2019.8766229

work page doi:10.1109/ieeestd.2019.8766229 2019
[44]

A Family of Embedded Runge-Kutta Formulae,

Dormand, J. R. and Prince, P. J., 1980, “A Family of Embedded Runge-Kutta Formulae,” Journal of Computational and Applied Mathematics,6(1), pp. 19– 26

work page 1980
[45]

High Order Embedded Runge-Kutta Formulae,

Prince, P. J. and Dormand, J. R., 1981, “High Order Embedded Runge-Kutta Formulae,” Journal of Computational and Applied Mathematics,7(1), pp. 67– 75

work page 1981
[46]

P., and Wanner, G., 1993,Solving Ordinary Differential Equations I: Nonstiff Problems, 2nd ed., No

Hairer, E., Nørsett, S. P., and Wanner, G., 1993,Solving Ordinary Differential Equations I: Nonstiff Problems, 2nd ed., No. 8 in Springer Series in Computa- tional Mathematics, Springer, Berlin, The Federal Republic of Germany

work page 1993
[47]

A Study of the Restitution Coefficient in Elastic-Plastic Impact,

Kharaz, A. and Gorham, D., 2000, “A Study of the Restitution Coefficient in Elastic-Plastic Impact,” Philosophical Magazine Letters,80(8), pp. 549–559

work page 2000
[48]

WebPlotDigitizer,

Rohatgi, A., “WebPlotDigitizer,” https://automeris.io

work page
[49]

Model-Based Derivative-Free Optimization Methods andSoftware,

Ragonneau, T. M., 2023, “Model-Based Derivative-Free Optimization Methods andSoftware,”doi:10.48550/arXiv.2210.12018,arXiv:2210.12018[math],http: //arxiv.org/abs/2210.12018

work page doi:10.48550/arxiv.2210.12018 2023
[50]

An Optimal Interpolation Set for Model-Based Derivative-Free Optimization Methods,

Ragonneau, T. M. and Zhang, Z., 2024, “An Optimal Interpolation Set for Model-Based Derivative-Free Optimization Methods,” Optimization Methods and Software,39(4), pp. 898–910

work page 2024
[51]

PDFO: A Cross-Platform Package forPowell’sDerivative-FreeOptimizationSolvers,

Ragonneau, T. M. and Zhang, Z., 2024, “PDFO: A Cross-Platform Package forPowell’sDerivative-FreeOptimizationSolvers,” MathematicalProgramming Computation, 16(4), pp. 535–559

work page 2024
[52]

A Reduced-Order Model From High- Dimensional Frictional Hysteresis,

Biswas, S. and Chatterjee, A., 2014, “A Reduced-Order Model From High- Dimensional Frictional Hysteresis,” Proceedings of the Royal Society A: Math- ematical, Physical and Engineering Sciences,470(2166), p. 20130817

work page 2014
[53]

A Two-State Hysteresis Model From High-Dimensional Friction,

Biswas, S. and Chatterjee, A., 2015, “A Two-State Hysteresis Model From High-Dimensional Friction,” Royal Society Open Science,2(7), p. 150188

work page 2015
[54]

A Class of Uniax- ial Phenomenological Models for Simulating Hysteretic Phenomena in Rate- Independent Mechanical Systems and Materials,

Vaiana, N., Sessa, S., Marmo, F., and Rosati, L., 2018, “A Class of Uniax- ial Phenomenological Models for Simulating Hysteretic Phenomena in Rate- Independent Mechanical Systems and Materials,” Nonlinear Dynamics,93(3), pp. 1647–1669

work page 2018
[55]

A Generalized Class of Uniaxial Rate-Independent Models for Simulating Asymmetric Mechanical Hysteresis Phenomena,

Vaiana, N., Sessa, S., and Rosati, L., 2021, “A Generalized Class of Uniaxial Rate-Independent Models for Simulating Asymmetric Mechanical Hysteresis Phenomena,” Mechanical Systems and Signal Processing,146, p. 106984

work page 2021
[56]

Analytical and Differential Reformulations of the Vaiana–Rosati Model for Complex Rate-Independent Mechanical Hysteresis Phenomena,

Vaiana, N. and Rosati, L., 2023, “Analytical and Differential Reformulations of the Vaiana–Rosati Model for Complex Rate-Independent Mechanical Hysteresis Phenomena,” Mechanical Systems and Signal Processing,199, p. 110448

work page 2023
[57]

Classification and Unified Phenomenolog- ical Modeling of Complex Uniaxial Rate-Independent Hysteretic Responses,

Vaiana, N. and Rosati, L., 2023, “Classification and Unified Phenomenolog- ical Modeling of Complex Uniaxial Rate-Independent Hysteretic Responses,” Mechanical Systems and Signal Processing,182, p. 109539

work page 2023
[58]

Mathematica, Version 13.3,

Wolfram Research Inc, 2023, “Mathematica, Version 13.3,” https://www. wolfram.com/mathematica

work page 2023
[59]

and Zaring, W

Takeuti, G. and Zaring, W. M., 1982,Introduction to Axiomatic Set Theory, 2nd ed., No. 1 in Graduate Texts in Mathematics, Springer-Verlag New York, New York, NY

work page 1982
[60]

L., 1955, General Topology, Van Nostrand Reinhold Company

Kelley, J. L., 1955, General Topology, Van Nostrand Reinhold Company. Reprint, Dover Publications Inc., 2017., Mineola, NY

work page 1955
[61]

D., 2010, The Real Numbers and Real Analysis, Springer Sci- ence+Business Media, New York, NY

Bloch, E. D., 2010, The Real Numbers and Real Analysis, Springer Sci- ence+Business Media, New York, NY

work page 2010
[62]

Shurman, J., 2016, Calculus and Analysis in Euclidean Space, Undergradu- ate Texts in Mathematics, Springer International Publishing, Cham, The Swiss Confederation

work page 2016
[63]

Ziemer, W. P. and Torres, M., 2017,Modern Real Analysis, 2nd ed., No. 278 in Graduate Texts in Mathematics, Springer International Publishing, Cham, The Swiss Confederation

work page 2017
[64]

9 in Publications of the Mathematical Society of Japan, The Mathematical Society of Japan, Tokyo, Japan

Yoshizawa, T., 1966,Stability Theory by Liapunov’s Second Method, No. 9 in Publications of the Mathematical Society of Japan, The Mathematical Society of Japan, Tokyo, Japan

work page 1966
[65]

14 in Applied Mathematical Sciences, Springer-Verlag New York, New York, NY

Yoshizawa, T., 1975, Stability Theory and the Existence of Periodic Solu- tions and Almost Periodic Solutions, No. 14 in Applied Mathematical Sciences, Springer-Verlag New York, New York, NY

work page 1975
[66]

D., 1998, Mathematical Control Theory: Deterministic Finite Di- mensional Systems, 2nd ed., Texts in Applied Mathematics, Springer Sci- ence+Business Media, New York, NY

Sontag, E. D., 1998, Mathematical Control Theory: Deterministic Finite Di- mensional Systems, 2nd ed., Texts in Applied Mathematics, Springer Sci- ence+Business Media, New York, NY

work page 1998
[67]

Haddad, W. M. and Chellaboina, V., 2011,Nonlinear Dynamical Systems and Control: A Lyapunov-Based Approach, Princeton University Press, Princeton, NJ

work page 2011
[68]

K., 2015,Nonlinear Control, Pearson Education, Upper Saddle River, NJ

Khalil, H. K., 2015,Nonlinear Control, Pearson Education, Upper Saddle River, NJ

work page 2015
[69]

A Compendium of Comparison Function Results,

Kellett, C. M., 2014, “A Compendium of Comparison Function Results,” Math- ematics of Control, Signals, and Systems,26(3), pp. 339–374

work page 2014
[70]

138 in Die Grundlehren de mathema- tischen Wissenschaften in Einzeldarstellungen, Springer-Verlag New York, New York, NY

Hahn, W., 1967,Stability of Motion, No. 138 in Die Grundlehren de mathema- tischen Wissenschaften in Einzeldarstellungen, Springer-Verlag New York, New York, NY. 12 ,

work page 1967

[1] [1]

D., 1985,Inequality Problems in Mechanics and Applica- tions: Convex and Nonconvex Energy Functions, Birkhäuser, Boston, MA

Panagiotopoulos, P. D., 1985,Inequality Problems in Mechanics and Applica- tions: Convex and Nonconvex Energy Functions, Birkhäuser, Boston, MA

work page 1985

[2] [2]

KGaA, Weinheim, The Federal Republic of Germany

Pfeiffer,F.andGlocker,C.,2004, MultibodyDynamicswithUnilateralContacts , Wiley Series in Nonlinear Science, WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim, The Federal Republic of Germany

work page 2004

[3] [3]

E., 2011, Dynamics with Inequalities: Impacts and Hard Con- straints, SIAM, Philadelphia, PA

Stewart, D. E., 2011, Dynamics with Inequalities: Impacts and Hard Con- straints, SIAM, Philadelphia, PA

work page 2011

[4] [4]

G., and Teel, A

Goebel, R., Sanfelice, R. G., and Teel, A. R., 2012,Hybrid Dynamical Systems: Modeling, Stability, and Robustness, Princeton University Press, Princeton, NJ

work page 2012

[5] [5]

Brogliato, B., 2016, Nonsmooth Mechanics: Models, Dynamics and Control, 3rd ed., Communications and Control Engineering, Springer International Pub- lishing, Cham, The Swiss Confederation

work page 2016

[6] [6]

G., 2021,Hybrid Feedback Control, Princeton University Press, Princeton, NJ

Sanfelice, R. G., 2021,Hybrid Feedback Control, Princeton University Press, Princeton, NJ

work page 2021

[7] [7]

Elastically De- formable Models,

Terzopoulos, D., Platt, J., Barr, A., and Fleischer, K., 1987, “Elastically De- formable Models,”Proceedings of the 14th Annual Conference on Computer Graphics and Interactive Techniques, Association for Computing Machinery, New York, NY, pp. 205–214, doi: 10.1145/37401.37427

work page doi:10.1145/37401.37427 1987

[8] [8]

Constraint Methods for Flexible Models,

Platt, J. C. and Barr, A. H., 1988, “Constraint Methods for Flexible Models,” SIGGRAPH ’88: Proceedings of the 15th Annual Conference on Computer Graphics and Interactive Techniques, M. C. Stone, ed., Association for Com- puting Machinery, New York, NY, pp. 279–288, doi: 10.1145/54852.378524

work page doi:10.1145/54852.378524 1988

[9] [9]

CollisionDetectionandResponseforCom- puter Animation,

Moore, M.andWilhelms, J., 1988, “CollisionDetectionandResponseforCom- puter Animation,”SIGGRAPH ’88: Proceedings of the 15th Annual Conference on Computer Graphics and Interactive Techniques, Association for Computing Machinery, New York, NY, pp. 289–298, doi: 10.1145/54852.378528

work page doi:10.1145/54852.378528 1988

[10] [10]

CanonicalEquationsofMotionandEstimation of Parameters in the Analysis of Impact Problems,

Movahedi-Lankarani, H., 1988, “CanonicalEquationsofMotionandEstimation of Parameters in the Analysis of Impact Problems,” Ph.D., The University of Arizona, Tucson, AZ

work page 1988

[11] [11]

Compliant Contact Force Models in Multibody Dynamics: Evolution of the Hertz Contact Theory,

Machado, M., Moreira, P., Flores, P., and Lankarani, H. M., 2012, “Compliant Contact Force Models in Multibody Dynamics: Evolution of the Hertz Contact Theory,” Mechanism and Machine Theory,53, pp. 99–121

work page 2012

[12] [12]

Nonlinear Phenomena of Contact in Multibody Systems Dynamics: A Review,

Corral, E., Moreno, R. G., García, M. J. G., and Castejón, C., 2021, “Nonlinear Phenomena of Contact in Multibody Systems Dynamics: A Review,” Nonlinear Dynamics, 104(2), pp. 1269–1295

work page 2021

[13] [13]

The Bouc–Wen Model for Binary Direct Collinear Collisions of Convex Viscoplastic Bodies,

Milehins, M. and Marghitu, D. B., 2025, “The Bouc–Wen Model for Binary Direct Collinear Collisions of Convex Viscoplastic Bodies,” ASME J Comput Nonlin Dyn,20(6), p. 061005

work page 2025

[14] [14]

Forced Vibration of Mechanical Systems with Hysteresis,

Bouc, R., 1967, “Forced Vibration of Mechanical Systems with Hysteresis,” Proceedings of the Fourth Conference on Nonlinear Oscillations, J. Gonda and F. Jelínek, eds., Academia Publishing House of the Czechoslovak Academy of Sciences, Prague, Czechoslovakia, p. 315

work page 1967

[15] [15]

Modèle Mathématique d’Hystérésis,

Bouc, R., 1971, “Modèle Mathématique d’Hystérésis,” Acustica,24(1), pp. 16– 25. 20The proof thatW for the NDBWMCM is radially unbounded may not appear to be entirely trivial, but it is still a routine exercise in analysis. 11

work page 1971

[16] [16]

Method for Random Vibration of Hysteretic Systems,

Wen, Y.-K., 1976, “Method for Random Vibration of Hysteretic Systems,” Jour- nal of the Engineering Mechanics Division,102(2), pp. 249–263

work page 1976

[17] [17]

Ikhouane, F. and Rodellar, J., 2007,Systems with Hysteresis: Analysis, Identifi- cationandControlusingtheBouc—WenModel ,JohnWiley&Sons,Chichester, The United Kingdom of Great Britain and Northern Ireland

work page 2007

[18] [18]

Parameter Analysis of the Differential Model of Hysteresis,

Ma, F., Zhang, H., Bockstedte, A., Foliente, G. C., and Paevere, P., 2004, “Parameter Analysis of the Differential Model of Hysteresis,” ASME J Appl Mech, 71(3), pp. 342–349

work page 2004

[19] [19]

Coefficient of Restitution Interpreted as Damping in Vibroimpact,

Hunt, K. H. and Crossley, F. R. E., 1975, “Coefficient of Restitution Interpreted as Damping in Vibroimpact,” ASME J Appl Mech,42(2), pp. 440–445

work page 1975

[20] [20]

On the Dynamical Theory of Gases,

Maxwell, J. C., 1867, “On the Dynamical Theory of Gases,” Philosophical Transactions of the Royal Society of London,157, pp. 49–88

work page

[21] [21]

L., 1985,Contact Mechanics, Cambridge University Press, Cam- bridge, The United Kingdom of Great Britain and Northern Ireland

Johnson, K. L., 1985,Contact Mechanics, Cambridge University Press, Cam- bridge, The United Kingdom of Great Britain and Northern Ireland

work page 1985

[22] [22]

Characterizing Damping and Resti- tution in Compliant Impacts via Modified K-V and Higher-Order Linear Vis- coelastic Models,

Butcher, E. A. and Segalman, D. J., 2000, “Characterizing Damping and Resti- tution in Compliant Impacts via Modified K-V and Higher-Order Linear Vis- coelastic Models,” ASME J Appl Mech,67(4), pp. 831–834

work page 2000

[23] [23]

Effects of External Force on Contacting Times and Coeffi- cients of Restitution in a Periodic Collision,

Tatara, Y., 1977, “Effects of External Force on Contacting Times and Coeffi- cients of Restitution in a Periodic Collision,” ASME J Appl Mech,44(4), pp. 773–774

work page 1977

[24] [24]

Behavior of One Inelastic Ball Bouncing Repeatedly off the Ground,

Falcon, E., Laroche, C., Fauve, S., and Coste, C., 1998, “Behavior of One Inelastic Ball Bouncing Repeatedly off the Ground,” The European Physical Journal B - Condensed Matter and Complex Systems,3(1), pp. 45–57

work page 1998

[25] [25]

Finite Duration Impacts With External Forces,

Quinn, D. D., 2004, “Finite Duration Impacts With External Forces,” ASME J Appl Mech,72(5), pp. 778–784

work page 2004

[26] [26]

High Apparent Ad- hesion Energy in the Breakdown of Normal Restitution for Binary Impacts of Small Spheres at Low Speed,

Sorace, C., Louge, M., Crozier, M., and Law, V., 2009, “High Apparent Ad- hesion Energy in the Breakdown of Normal Restitution for Binary Impacts of Small Spheres at Low Speed,” Mechanics Research Communications,36(3), pp. 364–368

work page 2009

[27] [27]

A size-dependent viscoelastic normal contact model for particle collision,

Ye, Y. and Zeng, Y., 2017, “A size-dependent viscoelastic normal contact model for particle collision,” International Journal of Impact Engineering,106, pp. 120–132

work page 2017

[28] [28]

A Contact Force Model Considering Constant External Forces for Impact Analysis in Multibody Dynamics,

Shen, Y., Xiang, D., Wang, X., Jiang, L., and Wei, Y., 2018, “A Contact Force Model Considering Constant External Forces for Impact Analysis in Multibody Dynamics,” Multibody System Dynamics,44(4), pp. 397–419

work page 2018

[29] [29]

A Comparative Study of the Dissipative Contact Force Models for Collision Under External Spring Forces,

Xiang, D., Shen, Y., Wei, Y., and You, M., 2018, “A Comparative Study of the Dissipative Contact Force Models for Collision Under External Spring Forces,” ASME J Comput Nonlin Dyn,13(10), p. 101009

work page 2018

[30] [30]

ExactRestitutionandGeneralizations for the Hunt–Crossley Contact Model,

Carvalho,A.S.andMartins,J.M.,2019,“ExactRestitutionandGeneralizations for the Hunt–Crossley Contact Model,” Mechanism and Machine Theory,139, pp. 174–194

work page 2019

[31] [31]

Experimental investigation of the coefficient of restitution of particles colliding with surfaces in air and water,

Yardeny, I., Portnikov, D., and Kalman, H., 2020, “Experimental investigation of the coefficient of restitution of particles colliding with surfaces in air and water,” Advanced Powder Technology,31(9), pp. 3747–3759

work page 2020

[32] [32]

Impact dynamics for gravity-driven motion of a particle,

Villegas, C. E. P., Rojas, W. Y., Bravo, C., and Rocha, A. R., 2021, “Impact dynamics for gravity-driven motion of a particle,” European Journal of Physics, 42(1), p. 015006

work page 2021

[33] [33]

Approximate Coefficient of Restitution for Nonlinear Viscoelastic Contact With External Load,

Chatterjee, A., James, G., and Brogliato, B., 2022, “Approximate Coefficient of Restitution for Nonlinear Viscoelastic Contact With External Load,” Granular Matter, 24(4), p. 124

work page 2022

[34] [34]

Gravity Effects in Mass-Spring-Damper Models of Inelastic Collisions,

Bartz, S. P., 2023, “Gravity Effects in Mass-Spring-Damper Models of Inelastic Collisions,” European Journal of Physics,44(2), p. 025003

work page 2023

[35] [35]

Low Speed Impact of an Elastic Ball with Tapes and Clay Court,

Akhan, A. F. and Marghitu, D. B., 2024, “Low Speed Impact of an Elastic Ball with Tapes and Clay Court,” Applied Sciences,14(13), p. 5674

work page 2024

[36] [36]

A Contact Force Calculation Approach for Collision Analysis With Zero or Non-zero Initial Relative Velocity,

Shen, Y. and Xiang, D., 2024, “A Contact Force Calculation Approach for Collision Analysis With Zero or Non-zero Initial Relative Velocity,” Nonlinear Dynamics, 112(22), pp. 19795–19808

work page 2024

[37] [37]

Cross, R., 2011, Physics of Baseball & Softball, Springer Science+Business Media, New York, NY

work page 2011

[38] [38]

J., 2018,Impact Mechanics, 2nd ed., Cambridge University Press, Cambridge, The United Kingdom of Great Britain and Northern Ireland

Stronge, W. J., 2018,Impact Mechanics, 2nd ed., Cambridge University Press, Cambridge, The United Kingdom of Great Britain and Northern Ireland

work page 2018

[39] [39]

Newton, I., 1729,The Mathematical Principles of Natural Philosophy, Printed for Benjamin Motte, at the Middle-Temple-Gate, in Fleet Street, London, King- dom of Great Britain, Translated by Andrew Motte

work page

[40] [40]

Logan, J.D., 2013,AppliedMathematics, 4thed., JohnWiley&Sons, Hoboken, NJ

work page 2013

[41] [41]

Array Programming With NumPy,

Harris, C. R., Millman, K. J., van der Walt, S. J., Gommers, R., Virtanen, P., Cournapeau, D., Wieser, E., Taylor, J., Berg, S., Smith, N. J., Kern, R., Picus, M., Hoyer, S., van Kerkwĳk, M. H., Brett, M., Haldane, A., Fernández del Río, J., Wiebe, M., Peterson, P., Gérard-Marchant, P., Sheppard, K., Reddy, T., Weckesser, W., Abbasi, H., Gohlke, C., and O...

work page 2020

[42] [42]

Scipy 1.0: Fundamental Algorithms for Scientific Computing in Python,

Virtanen, P., Gommers, R., Oliphant, T. E., Haberland, M., Reddy, T., Courna- peau, D., Burovski, E., Peterson, P., Weckesser, W., Bright, J., van der Walt, S. J., Brett, M., Wilson, J., Millman, K. J., Mayorov, N., Nelson, A. R. J., Jones, E., Kern, R., Larson, E., Carey, C. J., Polat, I., Feng, Y., Moore, E. W., Vander- Plas, J., Laxalde, D., Perktold, ...

work page 2020

[43] [43]

IEEE Standard for Floating-Point Arithmetic. IEEE Std 754TM- 2019 (Revision of IEEE Std 754-2008),

IEEE, 2019, “IEEE Standard for Floating-Point Arithmetic. IEEE Std 754TM- 2019 (Revision of IEEE Std 754-2008),” doi: 10.1109/IEEESTD.2019.8766229

work page doi:10.1109/ieeestd.2019.8766229 2019

[44] [44]

A Family of Embedded Runge-Kutta Formulae,

Dormand, J. R. and Prince, P. J., 1980, “A Family of Embedded Runge-Kutta Formulae,” Journal of Computational and Applied Mathematics,6(1), pp. 19– 26

work page 1980

[45] [45]

High Order Embedded Runge-Kutta Formulae,

Prince, P. J. and Dormand, J. R., 1981, “High Order Embedded Runge-Kutta Formulae,” Journal of Computational and Applied Mathematics,7(1), pp. 67– 75

work page 1981

[46] [46]

P., and Wanner, G., 1993,Solving Ordinary Differential Equations I: Nonstiff Problems, 2nd ed., No

Hairer, E., Nørsett, S. P., and Wanner, G., 1993,Solving Ordinary Differential Equations I: Nonstiff Problems, 2nd ed., No. 8 in Springer Series in Computa- tional Mathematics, Springer, Berlin, The Federal Republic of Germany

work page 1993

[47] [47]

A Study of the Restitution Coefficient in Elastic-Plastic Impact,

Kharaz, A. and Gorham, D., 2000, “A Study of the Restitution Coefficient in Elastic-Plastic Impact,” Philosophical Magazine Letters,80(8), pp. 549–559

work page 2000

[48] [48]

WebPlotDigitizer,

Rohatgi, A., “WebPlotDigitizer,” https://automeris.io

work page

[49] [49]

Model-Based Derivative-Free Optimization Methods andSoftware,

Ragonneau, T. M., 2023, “Model-Based Derivative-Free Optimization Methods andSoftware,”doi:10.48550/arXiv.2210.12018,arXiv:2210.12018[math],http: //arxiv.org/abs/2210.12018

work page doi:10.48550/arxiv.2210.12018 2023

[50] [50]

An Optimal Interpolation Set for Model-Based Derivative-Free Optimization Methods,

Ragonneau, T. M. and Zhang, Z., 2024, “An Optimal Interpolation Set for Model-Based Derivative-Free Optimization Methods,” Optimization Methods and Software,39(4), pp. 898–910

work page 2024

[51] [51]

PDFO: A Cross-Platform Package forPowell’sDerivative-FreeOptimizationSolvers,

Ragonneau, T. M. and Zhang, Z., 2024, “PDFO: A Cross-Platform Package forPowell’sDerivative-FreeOptimizationSolvers,” MathematicalProgramming Computation, 16(4), pp. 535–559

work page 2024

[52] [52]

A Reduced-Order Model From High- Dimensional Frictional Hysteresis,

Biswas, S. and Chatterjee, A., 2014, “A Reduced-Order Model From High- Dimensional Frictional Hysteresis,” Proceedings of the Royal Society A: Math- ematical, Physical and Engineering Sciences,470(2166), p. 20130817

work page 2014

[53] [53]

A Two-State Hysteresis Model From High-Dimensional Friction,

Biswas, S. and Chatterjee, A., 2015, “A Two-State Hysteresis Model From High-Dimensional Friction,” Royal Society Open Science,2(7), p. 150188

work page 2015

[54] [54]

A Class of Uniax- ial Phenomenological Models for Simulating Hysteretic Phenomena in Rate- Independent Mechanical Systems and Materials,

Vaiana, N., Sessa, S., Marmo, F., and Rosati, L., 2018, “A Class of Uniax- ial Phenomenological Models for Simulating Hysteretic Phenomena in Rate- Independent Mechanical Systems and Materials,” Nonlinear Dynamics,93(3), pp. 1647–1669

work page 2018

[55] [55]

A Generalized Class of Uniaxial Rate-Independent Models for Simulating Asymmetric Mechanical Hysteresis Phenomena,

Vaiana, N., Sessa, S., and Rosati, L., 2021, “A Generalized Class of Uniaxial Rate-Independent Models for Simulating Asymmetric Mechanical Hysteresis Phenomena,” Mechanical Systems and Signal Processing,146, p. 106984

work page 2021

[56] [56]

Analytical and Differential Reformulations of the Vaiana–Rosati Model for Complex Rate-Independent Mechanical Hysteresis Phenomena,

Vaiana, N. and Rosati, L., 2023, “Analytical and Differential Reformulations of the Vaiana–Rosati Model for Complex Rate-Independent Mechanical Hysteresis Phenomena,” Mechanical Systems and Signal Processing,199, p. 110448

work page 2023

[57] [57]

Classification and Unified Phenomenolog- ical Modeling of Complex Uniaxial Rate-Independent Hysteretic Responses,

Vaiana, N. and Rosati, L., 2023, “Classification and Unified Phenomenolog- ical Modeling of Complex Uniaxial Rate-Independent Hysteretic Responses,” Mechanical Systems and Signal Processing,182, p. 109539

work page 2023

[58] [58]

Mathematica, Version 13.3,

Wolfram Research Inc, 2023, “Mathematica, Version 13.3,” https://www. wolfram.com/mathematica

work page 2023

[59] [59]

and Zaring, W

Takeuti, G. and Zaring, W. M., 1982,Introduction to Axiomatic Set Theory, 2nd ed., No. 1 in Graduate Texts in Mathematics, Springer-Verlag New York, New York, NY

work page 1982

[60] [60]

L., 1955, General Topology, Van Nostrand Reinhold Company

Kelley, J. L., 1955, General Topology, Van Nostrand Reinhold Company. Reprint, Dover Publications Inc., 2017., Mineola, NY

work page 1955

[61] [61]

D., 2010, The Real Numbers and Real Analysis, Springer Sci- ence+Business Media, New York, NY

Bloch, E. D., 2010, The Real Numbers and Real Analysis, Springer Sci- ence+Business Media, New York, NY

work page 2010

[62] [62]

Shurman, J., 2016, Calculus and Analysis in Euclidean Space, Undergradu- ate Texts in Mathematics, Springer International Publishing, Cham, The Swiss Confederation

work page 2016

[63] [63]

Ziemer, W. P. and Torres, M., 2017,Modern Real Analysis, 2nd ed., No. 278 in Graduate Texts in Mathematics, Springer International Publishing, Cham, The Swiss Confederation

work page 2017

[64] [64]

9 in Publications of the Mathematical Society of Japan, The Mathematical Society of Japan, Tokyo, Japan

Yoshizawa, T., 1966,Stability Theory by Liapunov’s Second Method, No. 9 in Publications of the Mathematical Society of Japan, The Mathematical Society of Japan, Tokyo, Japan

work page 1966

[65] [65]

14 in Applied Mathematical Sciences, Springer-Verlag New York, New York, NY

Yoshizawa, T., 1975, Stability Theory and the Existence of Periodic Solu- tions and Almost Periodic Solutions, No. 14 in Applied Mathematical Sciences, Springer-Verlag New York, New York, NY

work page 1975

[66] [66]

D., 1998, Mathematical Control Theory: Deterministic Finite Di- mensional Systems, 2nd ed., Texts in Applied Mathematics, Springer Sci- ence+Business Media, New York, NY

Sontag, E. D., 1998, Mathematical Control Theory: Deterministic Finite Di- mensional Systems, 2nd ed., Texts in Applied Mathematics, Springer Sci- ence+Business Media, New York, NY

work page 1998

[67] [67]

Haddad, W. M. and Chellaboina, V., 2011,Nonlinear Dynamical Systems and Control: A Lyapunov-Based Approach, Princeton University Press, Princeton, NJ

work page 2011

[68] [68]

K., 2015,Nonlinear Control, Pearson Education, Upper Saddle River, NJ

Khalil, H. K., 2015,Nonlinear Control, Pearson Education, Upper Saddle River, NJ

work page 2015

[69] [69]

A Compendium of Comparison Function Results,

Kellett, C. M., 2014, “A Compendium of Comparison Function Results,” Math- ematics of Control, Signals, and Systems,26(3), pp. 339–374

work page 2014

[70] [70]

138 in Die Grundlehren de mathema- tischen Wissenschaften in Einzeldarstellungen, Springer-Verlag New York, New York, NY

Hahn, W., 1967,Stability of Motion, No. 138 in Die Grundlehren de mathema- tischen Wissenschaften in Einzeldarstellungen, Springer-Verlag New York, New York, NY. 12 ,

work page 1967