An important problem that spans across many types of systems (e.g., mechanical and biological) is how to model the dynamics of joints or interfaces in built-up structures in such a way that the complex dynamic and energy-dissipative behavior that depends on microscale phenomena at the joint/interface is accurately captured, yet in a framework that is amenable to efficient computational analyses of the larger macroscale system of which the joint or interface is a (spatially) small part. Simulating joint behavior in finite element analysis by meshing the joint regions finely enough to capture relevant micromechanics is impractical for large-scale structural systems. A more practical approach is to devise constitutive models for the overall behavior of individual joints that accurately capture their nonlinear and energy-dissipative behavior and to locally incorporate the constitutive response into the otherwise often-linear structural model. Recent studies have successfully captured and simulated mechanical joint dynamics using computationally simple phenomenological models of combined elasticity and slip with associated friction and energy dissipation, known as Iwan models. In the present article, the author reviews the relationship, and in some cases equivalence, of one type of Iwan model to several other models of hysteretic behavior that have been used to simulate a wide range of physical phenomena. Specifically, it is shown that the “parallel-series” Iwan model has been referred to in other fields by different names, including “Maxwell resistive capacitor,” “Ishlinskii,” and “ordinary stop hysteron.” Given this, the author establishes the relationship of this Iwan model to several other hysteresis models, most significantly the classical Preisach model. Having established these relationships, it is then possible to extend analytical tools developed for a specific hysteresis model to all of the models with which it is related. Such analytical tools include experimental identification, inversion, and analysis of vibratory energy flow and dissipation. Numerical case studies of simple systems that include an Iwan-modeled joint illustrate these points.

1.
Iwan
,
W. D.
, 1966, “
A Distributed-Element Model for Hysteresis and Its Steady-State Dynamic Response
,”
ASME J. Appl. Mech.
0021-8936,
33
, pp.
893
900
.
2.
Iwan
,
W. D.
, 1967, “
On a Class of Models for the Yielding Behavior of Continuous and Composite Systems
,”
ASME J. Appl. Mech.
0021-8936,
33
, pp.
893
900
.
3.
Segalman
,
D. J.
, 2005, “
A Four-Parameter Iwan Model for Lap-Type Joints
,”
ASME J. Appl. Mech.
0021-8936,
72
, pp.
752
760
.
4.
Song
,
Y.
,
McFarland
,
D. M.
,
Bergman
,
L. A.
, and
Vakakis
,
A. F.
, 2005, “
Effect of Pressure Distribution on Energy Dissipation in a Mechanical Lap Joint
,”
AIAA J.
0001-1452,
43
, pp.
420
425
.
5.
Segalman
,
D. J.
, and
Starr
,
M. J.
, 2004, “
Relationships Among Certain Joints Constitutive Models
,”
Sandia National Laboratories
, Report No. SAND2004-4321.
6.
Lee
,
S.-H.
,
Royston
,
T. J.
, and
Friedman
,
G.
, 2000, “
Modeling and Compensation of Hysteresis in Piezoceramic Transducers for Vibration Control
,”
J. Intell. Mater. Syst. Struct.
1045-389X,
11
, pp.
781
790
.
7.
Ozer
,
M. B.
, and
Royston
,
T. J.
, 2001, “
Modeling the Effect of Piezoceramic Hysteresis in Structural Vibration Control
,”
Proceedings of SPIE Eighth Annual International Symposium on Smart Structures and Materials
, Newport Beach, CA, Mar. 4–8, Paper No. 10, SPIE Vol.
4326
.
8.
Ozer
,
M. B.
, and
Royston
,
T. J.
, 2002, “
Optimal Passive and Hybrid Control of Vibration and Sound Radiation From Linear and Nonlinear PZT-Based Smart Structures
,”
Proceedings of SPIE Ninth Annual International Symposium on Smart Structures and Materials
, San Diego, CA, Mar. 17–21, Paper No. 8, SPIE Vol.
4693
.
9.
Lee
,
S.-H.
,
Ozer
,
M. B.
, and
Royston
,
T. J.
, 2002, “
Piezoceramic Hysteresis in the Adaptive Structural Vibration Control Problem
,”
J. Intell. Mater. Syst. Struct.
1045-389X,
13
, pp.
117
124
.
10.
Ozer
,
M. B.
, and
Royston
,
T. J.
, 2003, “
Passively Minimizing Structural Sound Radiation Using Shunted Piezoelectric Materials
,”
J. Acoust. Soc. Am.
0001-4966,
114
, pp.
1934
1946
.
11.
Macki
,
J. W.
,
Nistri
,
P.
, and
Zecca
,
P.
, 1993, “
Mathematical Models for Hysteresis
,”
SIAM Rev.
0036-1445,
35
, pp.
94
123
.
12.
Visintin
,
A.
, 1994,
Differential Models of Hysteresis
,
Springer
,
New York
.
13.
Miano
,
G.
,
Serpico
,
C.
, and
Visone
,
C.
, 1996, “
A New Model of Magnetic Hysteresis, Based on Stop Hysterons: An Application to the Magnetic Field Diffusion
,”
IEEE Trans. Magn.
0018-9464,
32
, pp.
1132
1135
.
14.
Bobbio
,
S.
,
Miano
,
G.
,
Serpico
,
C.
, and
Visone
,
C.
, 1997, “
Models of Magnetic Hysteresis Based on Play and Stop Hysterons
,”
IEEE Trans. Magn.
0018-9464,
33
, pp.
4417
4426
.
15.
Webb
,
G.
,
Lagoudas
,
D.
, and
Kurdila
,
A.
, 1998, “
Hysteresis Modeling of SMA Actuators for Control Applications
,”
J. Intell. Mater. Syst. Struct.
1045-389X,
9
, pp.
432
447
.
16.
Webb
,
G.
,
Kurdila
,
A.
, and
Lagoudas
,
D.
, 2000, “
Adaptive Hysteresis Model for Model Reference Control With Actuator Hysteresis
,”
J. Guid. Control Dyn.
0731-5090,
23
, pp.
459
465
.
17.
Krasnosel’skii
,
M. A.
, and
Pokrovskii
,
A. V.
, 1989,
Systems With Hysteresis
,
Springer-Verlag
,
Heidelberg
.
18.
Royston
,
T. J.
,
Lee
,
S.-H.
, and
Friedman
,
G.
, 1999, “
Comparison of Two Rate-Independent Hysteresis Models With Application to Piezoceramic Transducers
,”
Proceedings of 1999 ASME Design Engineering Technical Conference Symposium on Nonlinear Response of Hysteretic Oscillators
, Las Vegas, NV, VIB-8082.
19.
Lee
,
S.-H.
, and
Royston
,
T. J.
, 2000, “
Modeling Piezoceramic Transducer Hysteresis in the Structural Vibration Control Problem
,”
J. Acoust. Soc. Am.
0001-4966,
108
, pp.
2843
2855
.
20.
Lubarda
,
V. A.
,
Sumarac
,
D.
, and
Krajcinovic
,
D.
, 1993, “
Preisach Model and Hysteretic Behavior of Ductile Materials
,”
Eur. J. Mech. A/Solids
0997-7538,
12
, pp.
445
470
.
21.
Mayergoyz
,
I. D.
, 2003,
Mathematical Models of Hysteresis and Their Applications
,
Elsevier-Academic
,
New York
.
22.
Lazan
,
B. J.
, 1968,
Damping of Materials and Members in Structural Mechanics
,
Pergamon
,
London
.
23.
Goldfarb
,
M.
, and
Celanovic
,
N.
, 1997, “
A Lumped Parameter Electromechanical Model for Describing the Nonlinear Behavior of Piezoelectric Actuators
,”
ASME J. Dyn. Syst., Meas., Control
0022-0434,
119
, pp.
478
485
.
24.
Royston
,
T. J.
, and
Houston
,
B. H.
, 1998, “
Modeling and Measurement of Nonlinear Dynamic Behavior in Piezoelectric Ceramics With Application to 1–3 Composites
,”
J. Acoust. Soc. Am.
0001-4966,
104
, pp.
2814
2827
.
25.
Ge
,
P.
, and
Jouaneh
,
M.
, 1996, “
Tracking Control of a Piezoceramic Actuator
,”
IEEE Trans. Control Syst. Technol.
1063-6536,
4
, pp.
209
216
.
26.
Ge
,
P.
, and
Jouaneh
,
M.
, 1997, “
Generalized Preisach Model for Hysteresis Nonlinearity of Piezoceramic Actuators
,”
Precis. Eng.
0141-6359,
20
, pp.
99
111
.
27.
Hughes
,
D.
, and
Wen
,
J. T.
, 1997, “
Preisach Modeling of Piezoceramic and Shape Memory Alloy Hysteresis
,”
Smart Mater. Struct.
0964-1726,
6
, pp.
287
300
.
28.
Quinn
,
D. D.
, and
Segalman
,
D. J.
, 2005, “
Using Series-Series Iwan-Type Models for Understanding Joint Dynamics
,”
ASME J. Appl. Mech.
0021-8936,
72
, pp.
666
673
.
29.
Mayergoyz
,
I. D.
, 1991,
Mathematical Models of Hysteresis
,
Springer-Verlag
,
New York
.
30.
Royston
,
T. J.
, and
Singh
,
R.
, 1997, “
Vibratory Power Flow Through a Nonlinear Path Into a Resonant Receiver
,”
J. Acoust. Soc. Am.
0001-4966,
101
, pp.
2059
2069
.
You do not currently have access to this content.