Improved numerical dissipation for time integration algorithms in structural dynamics

TLDR: In this article, a new family of unconditionally stable one-step methods for the direct integration of the equations of structural dynamics is introduced and is shown to possess improved algorithmic damping properties which can be continuously controlled.

Abstract: A new family of unconditionally stable one-step methods for the direct integration of the equations of structural dynamics is introduced and is shown to possess improved algorithmic damping properties which can be continuously controlled. The new methods are compared with members of the Newmark family, and the Houbolt and Wilson methods.

Figures

Fig. 4. Damping ~atios versus 6t/T for new method and Newmark schemes

Fig. 5. Damping ratios versus 6t/T for new methods and Houbolt and Wilson schemes

Fig. 3. Spectral radii versus /J.t/T for new methods and Houbolt and Wilson schemes

Fig. 2. Spectral radii versus /J.t/T·fo~ new method and Newmark schemes

Full text

Lawrence Berkeley National Laboratory
Recent Work
Title
IMPROVED NUMERICAL DISSIPATION FOR TIME INTEGRATION ALGORITHMS IN STRUCTURAL
DYNAMICS
Permalink
https://escholarship.org/uc/item/18z548gt
Author
Hilber, Hans M.
Publication Date
1976-04-01
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University of California

-.
u u
Submitted
to
Earthquake
Engineering
and
Structural
Dynamics
LBL-4486
Preprint
C.
IMPROVED
NUMERICAL
DISSIPATION
FOR
TIME
INTEGRATION
ALGORITHMS
IN
STRUCTURAL
DYNAMICS
Hans
M.
Hilber,
Thomas
J.
R.
Hughes,
and
Robert
L.
Taylor
April
1976
Prepared
for
the
U.
S.
Energy
Research
and
Development
Administration
under
Contract
W
-7405-ENG
-48
For
Reference
Not
to
be taken from this
.room

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of
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by
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California, nor any
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of
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(
*
0 0
0
IMPROVED
NUMERICAL
DISSIPATION
FOR
TIME
INTEGRATION
. *
ALGORITHMS
IN
STRUCTURAL
DYNAMICS
Hans
M.
Hilber
Thomas
J.
R.
Hughes
Robert
L.
Taylor
Division
of
Structural
Engineering
and
Structural
Mechanics
Department
of
Civil
Engineering
and
Lawrence
Berkeley
Laboratory
University
of
California
Berkeley,
California
94720
April
1976
This
work
was
supported
in
part
by
the
U.
S.
Energy
Research
and
Development
Administration

•
o
o·
u o
~
4 o
ABSTRACT
A new
family
of
unconditionally
stable
one-step
methods
for
the
direct
integration
of
the
equations
of
structural
dynamics
is
introduced
and
is
shown
to
possess
improved
algorithmic
damping
properties
which
can
be
continuously
controlled.
The new
methods
are
compared
with
members
of
the
Newmark
family,
and
the
Houbolt.
and
Wilson
methods.
i.