Question about ForceBeamColumn

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oushii
Posts: 2
Joined: Sun Dec 22, 2019 7:06 pm

Question about ForceBeamColumn

Post by oushii »

I, Gid+Opensees user, built a simple 1 story reinforced concrete frame, 2 intervals setted, cyclic loads loaded in joint node, this is my .tcl file and log, can any one help solve this problem. 3Q very much!

TCL file
#
# ____ _ ____ ___ ____ ___ _ __
# / ___(_) _ \ _ / _ \ _ __ ___ _ __ / ___| ___ ___ ___ |_ _|_ __ | |_ ___ _ __ / _| __ _ ___ ___
# | | _| | | | |_| |_| | | | '_ \ / _ \ '_ \\___ \ / _ \/ _ \/ __| | || '_ \| __/ _ \ '__| |_ / _` |/ __/ _ \
# | |_| | | |_| |_ _| |_| | |_) | __/ | | |___) | __/ __/\__ \ | || | | | || __/ | | _| (_| | (_| __/
# \____|_|____/ |_| \___/| .__/ \___|_| |_|____/ \___|\___||___/ |___|_| |_|\__\___|_| |_| \__,_|\___\___|
# |_|
#
# GiD + OpenSees Interface - An Integrated FEA Platform
# Copyright (C) 2016-2018
#
# Lab of R/C and Masonry Structures
# School of Civil Engineering, AUTh
#
# Development team
#
# T. Kartalis-Kaounis, Civil Engineer AUTh
# V. Protopapadakis, Civil Engineer AUTh
# T. Papadopoulos, Civil Engineer AUTh
#
# Project coordinator
#
# V.K. Papanikolaou, Assistant Professor AUTh
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.
#

# --------------------------------------------------------------------------------------------------------------
# U N I T S
# --------------------------------------------------------------------------------------------------------------

# Length : m
# Force : kN
# Moment : kNm
# Stress : kPa
# Mass : ton

# --------------------------------------------------------------------------------------------------------------
# E L E M E N T S U S E D
# --------------------------------------------------------------------------------------------------------------

# C500X500 (6)
# B250X500 (6)

# --------------------------------------------------------------------------------------------------------------
#
# M O D E L D O M A I N 1 (6DOF)
#
# --------------------------------------------------------------------------------------------------------------

model BasicBuilder -ndm 3 -ndf 6

# --------------------------------------------------------------------------------------------------------------
# N O D E S
# --------------------------------------------------------------------------------------------------------------

# node $NodeTag $XCoord $Ycoord $Zcoord

node 1 6 0 0
node 2 6 0 1.1
node 3 6 0 2.2
node 4 6 0 3.3
node 5 5 0 3.3
node 6 4 0 3.3
node 7 3 0 3.3
node 8 2 0 3.3
node 9 1 0 3.3
node 10 0 0 0
node 11 0 0 1.1
node 12 0 0 2.2
node 13 0 0 3.3

# --------------------------------------------------------------------------------------------------------------
# R E S T R A I N T S
# --------------------------------------------------------------------------------------------------------------

# fix $NodeTag x-transl y-transl z-transl x-rot y-rot z-rot

fix 1 1 1 1 1 1 1
fix 10 1 1 1 1 1 1

# --------------------------------------------------------------------------------------------------------------
# F O R C E - B A S E D B E A M - C O L U M N E L E M E N T S
# --------------------------------------------------------------------------------------------------------------

# Geometric Transformation

geomTransf Linear 1 -1 0 0
geomTransf PDelta 3 -1 0 0
geomTransf Corotational 5 -1 0 0
geomTransf Linear 2 0 0 1
geomTransf PDelta 4 0 0 1
geomTransf Corotational 6 0 0 1

# Sections Definition used by forceBeamColumn Elements
# (飊ly if they have not already been defined on this model domain)

uniaxialMaterial Concrete06 154 -40000 -0.0023 1 1 -0.00235 3500 0.0001006 1 0.0007042
uniaxialMaterial Concrete06 155 -35000 -0.00225 1 1 -0.002375 3200 0.0001029 1 0.0007203
uniaxialMaterial Steel01 156 400000 2e+08 0.15 0 1 0 1


section Fiber 157 {

# Create the Core fibers

# patch rect $matTag $numSubdivY $numSubdivZ $yI $zI $yJ $zJ
patch rect 154 11 11 -0.200000 -0.200000 0.200000 0.200000

# Create the Cover fibers

# patch rect $matTag $numSubdivY $numSubdivZ $yI $zI $yJ $zJ
patch rect 155 2 15 0.200000 -0.250000 0.250000 0.250000
patch rect 155 2 15 -0.250000 -0.250000 -0.200000 0.250000
patch rect 155 11 2 -0.200000 0.200000 0.200000 0.250000
patch rect 155 11 2 -0.200000 -0.250000 0.200000 -0.200000

# Create the corner bars

# layer straight $matTag $numFiber $areaFiber $yStart $zStart $yEnd $zEnd
layer straight 156 2 0.00049090 0.200000 0.200000 0.200000 -0.200000
layer straight 156 2 0.00049090 -0.200000 0.200000 -0.200000 -0.200000

# Create the middle Reinforcing Bars along local z axis

# layer straight $matTag $numFiber $areaFiber $yStart $zStart $yEnd $zEnd
layer straight 156 3 0.00038010 0.200000 0.100000 0.200000 -0.100000
layer straight 156 3 0.00038010 -0.200000 0.100000 -0.200000 -0.100000

# Create the middle Reinforcing Bars along local y axis

# layer straight $matTag $numFiber $areaFiber $yStart $zStart $yEnd $zEnd
layer straight 156 3 0.00038010 0.100000 0.200000 -0.100000 0.200000
layer straight 156 3 0.00038010 0.100000 -0.200000 -0.100000 -0.200000
}


section Fiber 158 {

# Create the Core fibers

# patch rect $matTag $numSubdivY $numSubdivZ $yI $zI $yJ $zJ
patch rect 154 11 9 -0.200000 -0.075000 0.200000 0.075000

# Create the Cover fibers

# patch rect $matTag $numSubdivY $numSubdivZ $yI $zI $yJ $zJ
patch rect 155 2 15 0.200000 -0.125000 0.250000 0.125000
patch rect 155 2 15 -0.250000 -0.125000 -0.200000 0.125000
patch rect 155 11 3 -0.200000 0.075000 0.200000 0.125000
patch rect 155 11 3 -0.200000 -0.125000 0.200000 -0.075000


# Create the Top bars (face on local z positive dir)

# layer straight $matTag $numFiber $areaFiber $yStart $zStart $yEnd $zEnd
layer straight 156 6 0.00031420 -0.200000 0.075000 0.200000 0.075000

# Create the Bottom bars (face on local z negative dir)

layer straight 156 6 0.00031420 -0.200000 -0.075000 0.200000 -0.075000
}

# Force-Based Beam Column Element Definition

# element forceBeamColumn $eleTag $iNode $jNode $numIntgrPts $secTag $transfTag

element forceBeamColumn 1 1 2 3 157 3 -iter 10 1.00e-06 -mass 0.625
element forceBeamColumn 2 2 3 3 157 3 -iter 10 1.00e-06 -mass 0.625
element forceBeamColumn 3 3 4 3 157 3 -iter 10 1.00e-06 -mass 0.625
element forceBeamColumn 4 4 5 3 158 2 -iter 10 1.00e-06 -mass 0.3125
element forceBeamColumn 5 5 6 3 158 2 -iter 10 1.00e-06 -mass 0.3125
element forceBeamColumn 6 6 7 3 158 2 -iter 10 1.00e-06 -mass 0.3125
element forceBeamColumn 7 7 8 3 158 2 -iter 10 1.00e-06 -mass 0.3125
element forceBeamColumn 8 8 9 3 158 2 -iter 10 1.00e-06 -mass 0.3125
element forceBeamColumn 9 9 13 3 158 2 -iter 10 1.00e-06 -mass 0.3125
element forceBeamColumn 10 13 12 3 157 3 -iter 10 1.00e-06 -mass 0.625
element forceBeamColumn 11 12 11 3 157 3 -iter 10 1.00e-06 -mass 0.625
element forceBeamColumn 12 11 10 3 157 3 -iter 10 1.00e-06 -mass 0.625

# --------------------------------------------------------------------------------------------------------------
#
# D O M A I N C O M M O N S
#
# --------------------------------------------------------------------------------------------------------------

# --------------------------------------------------------------------------------------------------------------
# R E C O R D E R S
# --------------------------------------------------------------------------------------------------------------

recorder Node -file Node_displacements.out -time -nodeRange 1 13 -dof 1 2 3 disp
recorder Node -file Node_rotations.out -time -nodeRange 1 13 -dof 4 5 6 disp
recorder Node -file Node_forceReactions.out -time -nodeRange 1 13 -dof 1 2 3 reaction
recorder Node -file Node_momentReactions.out -time -nodeRange 1 13 -dof 4 5 6 reaction
recorder Element -file ForceBeamColumn_localForce.out -time -ele 1 2 3 4 5 6 7 8 9 10 11 12 localForce
recorder Element -file ForceBeamColumn_basicDeformation.out -time -ele 1 2 3 4 5 6 7 8 9 10 11 12 basicDeformation
recorder Element -file ForceBeamColumn_plasticDeformation.out -time -ele 1 2 3 4 5 6 7 8 9 10 11 12 plasticDeformation

logFile "ypkj.log"

puts ""
puts " __ __ __ __ _ "
puts "/ _ .| \\ _|_ / \\ _ _ _ (_ _ _ _ | _ |_ _ _(_ _ _ _"
puts "\\__)||__/ | \\__/|_)(-| )__)(-(-_) || )|_(-| | (_|(_(-"
puts " | "
puts " v2.6.0"
puts "Analysis summary"
puts ""
puts "Interval 1 : Static - [expr int(1+5)] steps"
puts "Interval 2 : Static - [expr int(1+ 400)] steps"
puts ""
puts "----------------"
puts ""
set time_start [clock seconds]
puts "Starting analysis at [clock format $time_start -format %H:%M:%S]\n"

# --------------------------------------------------------------------------------------------------------------
#
# I N T E R V A L 1
#
# --------------------------------------------------------------------------------------------------------------

puts "Running interval 1\n"

# Loads - Plain Pattern

pattern Plain 100 Linear {
load 4 0 0 -2005 0 0 0
load 13 0 0 -2005 0 0 0
eleLoad -ele 4 -type -beamUniform 0 -10 0
eleLoad -ele 5 -type -beamUniform 0 -10 0
eleLoad -ele 6 -type -beamUniform 0 -10 0
eleLoad -ele 7 -type -beamUniform 0 -10 0
eleLoad -ele 8 -type -beamUniform 0 -10 0
eleLoad -ele 9 -type -beamUniform 0 -10 0
# Dead Loads
eleLoad -ele 1 -type -beamUniform 0 0 -6.25
eleLoad -ele 2 -type -beamUniform 0 0 -6.25
eleLoad -ele 3 -type -beamUniform 0 0 -6.25
eleLoad -ele 4 -type -beamUniform 0 -3.125 -0
eleLoad -ele 5 -type -beamUniform 0 -3.125 -0
eleLoad -ele 6 -type -beamUniform 0 -3.125 -0
eleLoad -ele 7 -type -beamUniform 0 -3.125 -0
eleLoad -ele 8 -type -beamUniform 0 -3.125 -0
eleLoad -ele 9 -type -beamUniform 0 -3.125 -0
eleLoad -ele 10 -type -beamUniform 0 0 6.25
eleLoad -ele 11 -type -beamUniform 0 0 6.25
eleLoad -ele 12 -type -beamUniform 0 0 6.25
}

# recording the initial status

record

# Perform eigenvalue analysis

puts "Running eigenvalue analysis\n"

set numModes 9

# Record eigenvectors

for { set k 1 } { $k <= $numModes } { incr k } {
recorder Node -file [format "Mode_%i.out" $k] -nodeRange 1 13 -dof 1 2 3 "eigen $k"
}

set lambda [eigen -fullGenLapack $numModes]

# Calculate periods

set T {}
foreach lam $lambda {
lappend T [expr 6.283185/sqrt($lam)]
}

# Write periods file

set period "Periods.out"
set Periods [open $period "w"]
foreach t $T {
puts $Periods "$t"
}
close $Periods

# Analysis options

system BandGeneral
numberer RCM
constraints Transformation
integrator LoadControl 0.2
test NormDispIncr 1e-06 100 0
algorithm Newton
analysis Static

set Lincr 0.200000
set Nsteps 5
set committedSteps 1
set LoadCounter 0

variable strIni {}
variable testTypeStatic NormDispIncr
variable TolStatic 1e-06
variable maxNumIterStatic 100
variable algorithmTypeStatic Newton

for {set i 1} { $i <= $Nsteps } {incr i 1} {
set t [format "%7.5f" [expr [getTime] + $Lincr]]
set AnalOk [analyze 1]
if {$AnalOk !=0} {
break
} else {
set LoadCounter [expr $LoadCounter+1.0]
set committedSteps [expr $committedSteps+1]
}
}

if {$AnalOk != 0} {; # if analysis fails, alternative algorithms and substepping is applied
set firstFail 1
set AnalOk 0
set Nk 1
set returnToInitStepFlag 0
while {$LoadCounter < $Nsteps && $AnalOk == 0} {
if {($Nk==2 && $AnalOk==0) || ($Nk==1 && $AnalOk==0)} {
set Nk 1
if {$returnToInitStepFlag} {
puts "\nBack to initial step\n"
set returnToInitStepFlag 0
}
if {$firstFail == 0} { # for the first time only, do not repeat previous failed step
integrator LoadControl $Lincr; # reset to original increment
set t [format "%7.5f" [expr [getTime] + $Lincr]]
set AnalOk [analyze 1]; # zero for convergence
} else {
set AnalOk 1
set firstFail 0
}
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [format "%7.5f" [expr [getTime] + $Lincr]]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set LoadCounter [expr $LoadCounter+1.0/$Nk]
set committedSteps [expr $committedSteps+1]
}
}; # end if Nk=1
# substepping /2
if {($AnalOk !=0 && $Nk==1) || ($AnalOk==0 && $Nk==4)} {
set Nk 2; # reduce step size
set continueFlag 1
puts "\nInitial step is divided by 2\n"
set LincrReduced [expr $Lincr/$Nk]
integrator LoadControl $LincrReduced
for {set ik 1} {$ik <=$Nk} {incr ik 1} {
if {$continueFlag==0} {
break
}
set t [format "%7.5f" [expr [getTime] + $LincrReduced]]
set AnalOk [analyze 1]; # zero for convergence
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [format "%7.5f" [expr [getTime] + $LincrReduced]]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set LoadCounter [expr $LoadCounter+1.0/$Nk]
set committedSteps [expr $committedSteps+1]
} else {
set continueFlag 0
}
}
if {$AnalOk == 0} {
set returnToInitStepFlag 1
}
}; # end if Nk=2
# substepping /4
if {($AnalOk !=0 && $Nk==2) || ($AnalOk==0 && $Nk==8)} {
set Nk 4; # reduce step size
set continueFlag 1
puts "\nInitial step is divided by 4\n"
set LincrReduced [expr $Lincr/$Nk]
integrator LoadControl $LincrReduced
for {set ik 1} {$ik <=$Nk} {incr ik 1} {
if {$continueFlag==0} {
break
}
set t [format "%7.5f" [expr [getTime] + $LincrReduced]]
set AnalOk [analyze 1]; # zero for convergence
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [format "%7.5f" [expr [getTime] + $LincrReduced]]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set LoadCounter [expr $LoadCounter+1.0/$Nk]
set committedSteps [expr $committedSteps+1]
} else {
set continueFlag 0
}
}
if {$AnalOk == 0} {
set returnToInitStepFlag 1
}
}; # end if Nk=4
# substepping /8
if {$AnalOk !=0 && $Nk==4 || ($Nk == 16 && $AnalOk == 0)} {
set Nk 8; # reduce step size
set continueFlag 1
puts "\nInitial step is divided by 8\n"
set LincrReduced [expr $Lincr/$Nk]
integrator LoadControl $LincrReduced
for {set ik 1} {$ik <=$Nk} {incr ik 1} {
if {$continueFlag==0} {
break
}
set t [format "%7.5f" [expr [getTime] + $LincrReduced]]
set AnalOk [analyze 1]; # zero for convergence
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [format "%7.5f" [expr [getTime] + $LincrReduced]]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set LoadCounter [expr $LoadCounter+1.0/$Nk]
set committedSteps [expr $committedSteps+1]
} else {
set continueFlag 0
}
}
if {$AnalOk == 0} {
set returnToInitStepFlag 1
}
}; # end if Nk=8
# substepping /16
if {($Nk == 8 && $AnalOk!=0)} {
set Nk 16; # reduce step size
set continueFlag 1
puts "\nInitial step is divided by 16\n"
set LincrReduced [expr $Lincr/$Nk]
integrator LoadControl $LincrReduced
for {set ik 1} {$ik <=$Nk} {incr ik 1} {
if {$continueFlag==0} {
break
}
set t [format "%7.5f" [expr [getTime] + $LincrReduced]]
set AnalOk [analyze 1]; # zero for convergence
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [format "%7.5f" [expr [getTime] + $LincrReduced]]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set LoadCounter [expr $LoadCounter+1.0/$Nk]
set committedSteps [expr $committedSteps+1]
} else {
set continueFlag 0
}
}
if {$AnalOk == 0} {
set returnToInitStepFlag 1
}
}; # end if Nk=16
}; # end while loop
}; # end if AnalOk

if {$AnalOk == 0} {
puts "\nAnalysis completed SUCCESSFULLY"
puts "Committed steps : $committedSteps\n"
} else {
puts "\nAnalysis FAILED"
puts "Committed steps : $committedSteps\n"
}

# all previously defined patterns are constant for so on.

loadConst -time 0.0

# --------------------------------------------------------------------------------------------------------------
#
# I N T E R V A L 2
#
# --------------------------------------------------------------------------------------------------------------

puts "Running interval 2\n"

# Loads - Plain Pattern

pattern Plain 200 Linear {
load 13 1 0 0 0 0 0
}

# recording the initial status

record

# Analysis options

system BandGeneral
numberer RCM
constraints Transformation
integrator DisplacementControl 13 1 0.00132
test NormDispIncr 1e-08 100 0
algorithm Newton
analysis Static

set iDmax [list]
set iNSteps [list]
set Nsteps 50
set committedSteps 1
set IDctrlNode 13
set IDctrlDOF 1

lappend iDmax 0.021978
lappend iNcycles 2
lappend iNSteps $Nsteps
lappend iDmax 0.043956
lappend iNcycles 2
lappend iNSteps $Nsteps
lappend iDmax 0.066
lappend iNcycles 2
lappend iNSteps $Nsteps

variable strIni {}
variable testTypeStatic NormDispIncr
variable TolStatic 1e-08
variable maxNumIterStatic 100
variable algorithmTypeStatic Newton

foreach Dmax $iDmax Ncycles $iNcycles NumSteps $iNSteps {
set DispIncr [expr $Dmax/$NumSteps]; # the displacement increment for each step
set Dstepvector ""
set Disp 0
if {$Dmax<0} {; # avoid the divide by zero
set dx [expr -$DispIncr]
} else {
set dx $DispIncr
}
for {set i 1} {$i <= $NumSteps} {incr i 1} {; # zero to one
set Disp [expr $Disp + $dx]
lappend Dstepvector $Disp
}
for {set i 1} {$i <= $NumSteps} {incr i 1} {; # one to zero
set Disp [expr $Disp - $dx]
lappend Dstepvector $Disp
}
for {set i 1} {$i <= $NumSteps} {incr i 1} {; # zero to minus one
set Disp [expr $Disp - $dx]
lappend Dstepvector $Disp
}
for {set i 1} {$i <= $NumSteps} {incr i 1} {; # minus one to zero
set Disp [expr $Disp + $dx]
lappend Dstepvector $Disp
}
for {set i 1} {$i <= $Ncycles} {incr i 1} {
set currentPath 1
set D0 0.0
foreach Dispstep $Dstepvector {
set D1 $Dispstep
set Dincr [expr $D1 - $D0]
integrator DisplacementControl $IDctrlNode $IDctrlDOF $Dincr
set t [getTime]
set AnalOk [analyze 1]; # first analyze command
set D0 $D1; # move to next step
set tempexpr1 [expr abs($D0-$Dmax)]
set tempexpr2 [expr abs($D0+$Dmax)]
set tempexpr3 [expr abs($D0)]
if {($tempexpr1 < 0.0000001) || ($tempexpr2 < 0.0000001) || ($tempexpr3 < 0.0000001)} {
set currentPath [expr $currentPath+1]
}
if {$AnalOk != 0 } {
break
}
}
if {$AnalOk != 0} {; # if analysis fails, alternative algorithms and substepping is applied
set firstFail 1
set Dstep 0.0
set AnalOk 0
set Nk 1
set returnToInitStepFlag 0
set tempexpr [expr abs($Dstep)]
while {($AnalOk == 0 && $currentPath<=3) || ($tempexpr > 0.000001 && $AnalOk == 0 && $currentPath==4)} {
set controlDisp [nodeDisp $IDctrlNode $IDctrlDOF]
set Dstep [expr $controlDisp/$Dmax]
if {($Nk==2 && $AnalOk==0) || ($Nk==1 && $AnalOk==0)} {
set Nk 1
if {$returnToInitStepFlag} {
puts "\nBack to initial step\n"
set returnToInitStepFlag 0
}
if {$firstFail == 0} {; # for the first time only, do not repeat previous failed step
if {$Dmax > 0} {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DispIncr; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DispIncr
}
} else {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DispIncr; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DispIncr
}
}
set t [getTime]
set AnalOk [analyze 1]; # zero for convergence
} else {
set AnalOk 1
set firstFail 0
}
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [getTime]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set committedSteps [expr $committedSteps+1]
}
}; # end if Nk=1
# substepping /2
if {($AnalOk !=0 && $Nk==1) || ($AnalOk==0 && $Nk==4)} {
set Nk 2; # reduce step size
set continueFlag 1
puts "\nInitial step is divided by 2\n"
set DincrReduced [expr $DispIncr/$Nk]
if {$Dmax > 0} {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DincrReduced; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DincrReduced
}
} else {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DincrReduced; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DincrReduced
}
}
for {set ik 1} {$ik <=$Nk} {incr ik 1} {
if {$continueFlag==0} {
break
}
set t [getTime]
set AnalOk [analyze 1]; # zero for convergence
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [getTime]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set committedSteps [expr $committedSteps+1]
} else {
set continueFlag 0
}
}
if {$AnalOk == 0} {
set returnToInitStepFlag 1
}
}; # end if Nk=2
# substepping /4
if {($AnalOk !=0 && $Nk==2) || ($AnalOk==0 && $Nk==8)} {
set Nk 4; # reduce step size
set continueFlag 1
puts "\nInitial step is divided by 4\n"
set DincrReduced [expr $DispIncr/$Nk]
if {$Dmax > 0} {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DincrReduced; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DincrReduced
}
} else {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DincrReduced; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DincrReduced
}
}
for {set ik 1} {$ik <=$Nk} {incr ik 1} {
if {$continueFlag==0} {
break
}
set t [getTime]
set AnalOk [analyze 1]; # zero for convergence
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [getTime]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set committedSteps [expr $committedSteps+1]
} else {
set continueFlag 0
}
}
if {$AnalOk == 0} {
set returnToInitStepFlag 1
}
}; # end if Nk=4
# substepping /8
if {$AnalOk !=0 && $Nk==4 || ($Nk == 16 && $AnalOk == 0)} {
set Nk 8; # reduce step size
set continueFlag 1
puts "\nInitial step is divided by 8\n"
set DincrReduced [expr $DispIncr/$Nk]
if {$Dmax > 0} {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DincrReduced; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DincrReduced
}
} else {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DincrReduced; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DincrReduced
}
}
for {set ik 1} {$ik <=$Nk} {incr ik 1} {
if {$continueFlag==0} {
break
}
set t [getTime]
set AnalOk [analyze 1]; # zero for convergence
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [getTime]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set committedSteps [expr $committedSteps+1]
} else {
set continueFlag 0
}
}
if {$AnalOk == 0} {
set returnToInitStepFlag 1
}
}; # end if Nk=8
# substepping /16
if {($Nk == 8 && $AnalOk!=0)} {
set Nk 16; # reduce step size
set continueFlag 1
puts "\nInitial step is divided by 16\n"
set DincrReduced [expr $DispIncr/$Nk]
if {$Dmax > 0} {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DincrReduced; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DincrReduced
}
} else {
if {$currentPath == 1 || $currentPath == 4 } {
integrator DisplacementControl $IDctrlNode $IDctrlDOF -$DincrReduced; # bring back to original increment
} else {
integrator DisplacementControl $IDctrlNode $IDctrlDOF $DincrReduced
}
}
for {set ik 1} {$ik <=$Nk} {incr ik 1} {
if {$continueFlag==0} {
break
}
set t [getTime]
set AnalOk [analyze 1]; # zero for convergence
if {$AnalOk != 0} {
puts "\nTrying NR/initial\n"
test NormDispIncr $TolStatic $maxNumIterStatic 0
algorithm Newton -initial
set t [getTime]
set AnalOk [analyze 1]
test $testTypeStatic $TolStatic $maxNumIterStatic 0
algorithm $algorithmTypeStatic
}
if {$AnalOk == 0} {
set committedSteps [expr $committedSteps+1]
} else {
set continueFlag 0
}
}
if {$AnalOk == 0} {
set returnToInitStepFlag 1
}
}; # end if Nk=16
set controlDisp [nodeDisp $IDctrlNode $IDctrlDOF]
set Dstep [expr $controlDisp/$Dmax]
set tempexpr1 [expr abs($Dstep-1)]
set tempexpr2 [expr abs($Dstep+1)]
set tempexpr3 [expr abs($Dstep)]
if {$tempexpr1 < 0.0000001 || $tempexpr2 < 0.0000001 || $tempexpr3 < 0.0000001} {
set currentPath [expr $currentPath+1]
}
set tempexpr [expr abs($Dstep)]
}; # end while loop
}; # end if $AnalOk !=0
if {$AnalOk != 0 } {
break
}
}; # end i
}; # end of iDmax

if {$AnalOk == 0} {
puts "\nAnalysis completed SUCCESSFULLY"
puts "Committed steps : $committedSteps\n"
} else {
puts "\nAnalysis FAILED"
puts "Committed steps : $committedSteps\n"
}

# --------------------------------------------------------------------------------------------------------------

set hour 0.0
set minute 0.0
set second 0.0
set time_end [clock seconds]
set analysisTime [expr $time_end-$time_start]

puts "Analysis finished at [clock format $time_end -format %H:%M:%S]\n"

if {$analysisTime<60} {
if {$analysisTime==0} {
puts "Analysis time : less than one second"
} elseif {$analysisTime==1} {
puts "Analysis time : 1 second"
} else {
puts "Analysis time : $analysisTime seconds"
}

} elseif {$analysisTime<3600} {
set minutes [expr $analysisTime/60]
set seconds [expr $analysisTime%60]

if {$minutes==1} {
puts -nonewline "Analysis time : 1 minute"
} else {
puts -nonewline "Analysis time : $minutes minutes"
}

if {$seconds==0} {
puts ""
} elseif {$seconds==1} {
puts " and 1 second"
} else {
puts " and $seconds seconds"
}

} else {
set hours [expr $analysisTime/3600]
set minutes [expr ($analysisTime%3600)/60]
set seconds [expr ($analysisTime%3600)%60]

if {$hours==1} {
puts -nonewline "Analysis time : 1 hour"
} else {
puts -nonewline "Analysis time : $hours hours"
}

if {$minutes==0} {
} elseif {$minute==1} {
puts -nonewline ", 1 minute"
} else {
puts -nonewline ", $minutes minutes"
}

if {$seconds==0} {
puts ""
} elseif {$second==1} {
puts " and 1 second"
} else {
puts " and $seconds seconds"
}
}

# --------------------------------------------------------------------------------------------------------------
#
# M E T A D A T A
#
# --------------------------------------------------------------------------------------------------------------

# Number of nodes
# 13

# Elements 1D
# 12

# Elements 2D
# 0

# Elements 3D
# 0

# ForceBeamColumn
# 12
# 1 2 3 4 5 6 7 8 9 10 11 12

# ----------------------------------------------------------------------------------------------------------------------------------------------------------
#
# F R A M E L O C A L A X E S O R I E N T A T I O N
#
# ----------------------------------------------------------------------------------------------------------------------------------------------------------
#
# ID Type Local-x Local-y Local-z Literal
#
# 1 forceBeamColumn {+0.00000 +0.00000 +1.00000} {+0.00000 +1.00000 -0.00000} {-1.00000 +0.00000 +0.00000} { +Z +Y -X }
# 2 forceBeamColumn {+0.00000 +0.00000 +1.00000} {+0.00000 +1.00000 -0.00000} {-1.00000 +0.00000 +0.00000} { +Z +Y -X }
# 3 forceBeamColumn {+0.00000 +0.00000 +1.00000} {+0.00000 +1.00000 -0.00000} {-1.00000 +0.00000 +0.00000} { +Z +Y -X }
# 4 forceBeamColumn {-1.00000 +0.00000 +0.00000} {+0.00000 -1.00000 +0.00000} {+0.00000 +0.00000 +1.00000} { -X -Y +Z }
# 5 forceBeamColumn {-1.00000 +0.00000 +0.00000} {+0.00000 -1.00000 +0.00000} {+0.00000 +0.00000 +1.00000} { -X -Y +Z }
# 6 forceBeamColumn {-1.00000 +0.00000 +0.00000} {+0.00000 -1.00000 +0.00000} {+0.00000 +0.00000 +1.00000} { -X -Y +Z }
# 7 forceBeamColumn {-1.00000 +0.00000 +0.00000} {+0.00000 -1.00000 +0.00000} {+0.00000 +0.00000 +1.00000} { -X -Y +Z }
# 8 forceBeamColumn {-1.00000 +0.00000 +0.00000} {+0.00000 -1.00000 +0.00000} {+0.00000 +0.00000 +1.00000} { -X -Y +Z }
# 9 forceBeamColumn {-1.00000 +0.00000 +0.00000} {+0.00000 -1.00000 +0.00000} {+0.00000 +0.00000 +1.00000} { -X -Y +Z }
# 10 forceBeamColumn {+0.00000 +0.00000 -1.00000} {-0.00000 -1.00000 -0.00000} {-1.00000 +0.00000 +0.00000} { -Z -Y -X }
# 11 forceBeamColumn {+0.00000 +0.00000 -1.00000} {-0.00000 -1.00000 -0.00000} {-1.00000 +0.00000 +0.00000} { -Z -Y -X }
# 12 forceBeamColumn {+0.00000 +0.00000 -1.00000} {-0.00000 -1.00000 -0.00000} {-1.00000 +0.00000 +0.00000} { -Z -Y -X }
buffs
Posts: 15
Joined: Wed Jul 04, 2012 2:08 am
Location: private
Contact:

Re: Question about ForceBeamColumn

Post by buffs »

I don find the .log and don't understand the problem, could you please detail?
Francesco Buffa
Mechanical Engineer
Corso Monte Grappa
10145 Torino
Italy
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