DocumentCode :
1184870
Title :
Jump behavior of circuits and systems
Author :
Sastry, S. Shankar ; Desoer, Charles A.
Volume :
28
Issue :
12
fYear :
1981
fDate :
12/1/1981 12:00:00 AM
Firstpage :
1109
Lastpage :
1124
Abstract :
Some circuits exhibit jump behavior. for example, this occurs when the velocity field specified by the 
and 
of the inductor and capacitor characteristics cannot be "lifted" on to the resistive constraint manifold. The (jump) behavior is viewed as the limit as 
of the solutions of a regularized system of equations obtained by introducing suitably located 
-parasitic 
\´s and 
\´s: this leads to a consistent way of defining discontinuous solutions. In particular, the behavior near a fold and cusp is examined. The concept of physically measurable operating point is defined and is related to that of strict local dissipativeness (which generalizes that of strict local passivity). Two examples are included.
and of the inductor and capacitor characteristics cannot be "lifted" on to the resistive constraint manifold. The (jump) behavior is viewed as the limit as of the solutions of a regularized system of equations obtained by introducing suitably located -parasitic \´s and \´s: this leads to a consistent way of defining discontinuous solutions. In particular, the behavior near a fold and cusp is examined. The concept of physically measurable operating point is defined and is related to that of strict local dissipativeness (which generalizes that of strict local passivity). Two examples are included.Keywords :
General analysis and synthesis methods; Network theory; Capacitors; Circuits and systems; Constraint theory; Equations; Inductors; Laboratories; Parasitic capacitance; Transient response; Voltage;
fLanguage :
English
Journal_Title :
Circuits and Systems, IEEE Transactions on
Publisher :
ieee
ISSN :
0098-4094
Type :
jour
DOI :
10.1109/TCS.1981.1084943
Filename :
1084943
Link To Document :
