Hysteretic Material: Difference between revisions

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| style="background:yellow; color:black; width:800px" | '''uniaxialMaterial Hysteretic $matTag $s1p $e1p $s2p $e2p <$s3p $e3p> $s1n $e1n $s2n $e2n <$s3n $e3n> $pinchX $pinchY $damage1 $damage2 <$beta>'''
| style="background:lime; color:black; width:800px" | '''uniaxialMaterial Hysteretic $matTag $s1p $e1p $s2p $e2p <$s3p $e3p> $s1n $e1n $s2n $e2n <$s3n $e3n> $pinchX $pinchY $damage1 $damage2 <$beta>'''
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Hysteretic Material


[[Image:Hysteretic.gif]]
[[Image:Hysteretic.gif]]


[[Image:Hysteretic2.png]]


NOTE:
#In cases $s3p > $s2p and abs($s3n) > abs($s2n), the envelope of the hysteretic material after $e3p or $e3n follows the slope defined by 2nd and 3rd point of the envelope.
#In cases $s3p <= $s2p and abs($s3n) <= abs($s2n) the envelope of the hysteretic material after $e3p or $e3n is a flat line with a constant stress (or force) equal to $s3p or $s3n.
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Examples:
Effects of Hysteretic-Material Parameters [http://opensees.berkeley.edu/OpenSees/manuals/usermanual/4052.htm]
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Code Developed by: <span style="color:blue"> Micheal Scott & Filip Filippou, UC Berkeley </span>
Code Developed by: <span style="color:blue"> Michael Scott (Oregon State University) & Filip Filippou (UC Berkeley) </span>


Images Developed by: <span style="color:blue"> Silvia Mazzoni </span>
Images Developed by: <span style="color:blue"> Silvia Mazzoni </span>

Latest revision as of 22:00, 9 December 2016




This command is used to construct a uniaxial bilinear hysteretic material object with pinching of force and deformation, damage due to ductility and energy, and degraded unloading stiffness based on ductility.

uniaxialMaterial Hysteretic $matTag $s1p $e1p $s2p $e2p <$s3p $e3p> $s1n $e1n $s2n $e2n <$s3n $e3n> $pinchX $pinchY $damage1 $damage2 <$beta>

$matTag integer tag identifying material
$s1p $e1p stress and strain (or force & deformation) at first point of the envelope in the positive direction
$s2p $e2p stress and strain (or force & deformation) at second point of the envelope in the positive direction
$s3p $e3p stress and strain (or force & deformation) at third point of the envelope in the positive direction (optional)
$s1n $e1n stress and strain (or force & deformation) at first point of the envelope in the negative direction
$s2n $e2n stress and strain (or force & deformation) at second point of the envelope in the negative direction
$s3n $e3n stress and strain (or force & deformation) at third point of the envelope in the negative direction (optional)
$pinchx pinching factor for strain (or deformation) during reloading
$pinchy pinching factor for stress (or force) during reloading
$damage1 damage due to ductility: D1(mu-1)
$damage2 damage due to energy: D2(Eii/Eult)
$beta power used to determine the degraded unloading stiffness based on ductility, mu-beta (optional, default=0.0)



NOTE:

  1. In cases $s3p > $s2p and abs($s3n) > abs($s2n), the envelope of the hysteretic material after $e3p or $e3n follows the slope defined by 2nd and 3rd point of the envelope.
  2. In cases $s3p <= $s2p and abs($s3n) <= abs($s2n) the envelope of the hysteretic material after $e3p or $e3n is a flat line with a constant stress (or force) equal to $s3p or $s3n.

Examples:

Effects of Hysteretic-Material Parameters [1]


Code Developed by: Michael Scott (Oregon State University) & Filip Filippou (UC Berkeley)

Images Developed by: Silvia Mazzoni