Beispiel #1
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def myFunc():
    """
    Runs train analysis
    """

    # Define system to analyse
    bridge_sys = modalsys.ModalSys()
    bridge_sys.AddOutputMtrx()
    """
    Determine reasonable time step to use for results presentation
    Note: only influences time interval at which results are output
    Scipy's solver determines its own time step for solving ODEs
    """
    max_fn = numpy.max(bridge_sys.fn)
    dt_reqd = 0.01  #(1/max_fn)/2 # sampling freq to be 10x maximum modal freq - rule of thumb for accurately capturing peaks

    ## Run moving load analysis for specified speed
    speed_kmph = 450
    loading_obj = loading.LoadTrain(fName="train_defs/trainA6.csv",
                                    name="trainA6")

    ML_analysis = dyn_analysis.MovingLoadAnalysis(
        modalsys_obj=bridge_sys,
        dt=dt_reqd,
        max_dt=dt_reqd,
        loadVel=speed_kmph * 1000 / 3600,
        loadtrain_obj=loading_obj,
        tEpilogue=1.0,
        writeResults2File=True,
        results_fName="my_results.csv")

    results_obj = ML_analysis.run()

    return results_obj
Beispiel #2
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    return T_vals, Se_vals

  
    
# ********************** TEST ROUTINE ****************************************

if __name__ == "__main__":
    
    testRoutine=5
    
    if testRoutine==1:
        
        import modalsys
    
        modal_sys = modalsys.ModalSys(isSparse=False)
        modal_sys.AddOutputMtrx(fName="outputs.csv")
        
        def sine(t):
            return numpy.sin(5*t)
        
        loading_obj = loading.LoadTrain(loadX=0.0,loadVals=100.0,
                                        intensityFunc=sine,
                                        name="Sine test")
        
        #loading_obj = loading.LoadTrain()
        
        ML_analysis = MovingLoadAnalysis(modalsys_obj=modal_sys,
                                         dt=0.01,
                                         loadVel=20,
                                         loadtrain_obj=loading_obj,
Beispiel #3
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"""
Script to illustrate walkers/joggers pedestrian dynamics analyses 
to UK NA to BS EN 1991-2
"""

# DynSys package imports
import modalsys
from ped_dyn import UKNA_BSEN1991_2_walkers_joggers
from ped_dyn import PedestrianDynamics_transientAnalyses

#%%

bridgeClass = 'b'

# Define modal system
my_sys = modalsys.ModalSys(name="Bridge example")
#my_sys.PrintSystemMatrices()

# Add output matrix
my_sys.AddOutputMtrx()

#%%

# Define single walkers/joggers analysis
my_analysis = UKNA_BSEN1991_2_walkers_joggers(modalsys_obj=my_sys,
                                              mode_index=4,
                                              analysis_type="joggers",
                                              bridgeClass=bridgeClass)

results_obj = my_analysis.run()
tstep_obj = results_obj.tstep_obj
Beispiel #4
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"""
Example to demonstrate (and test) use of constraints
"""

import matplotlib.pyplot as plt
plt.close('all')

# dynsys library imports
import modalsys
from damper import TMD
from ped_dyn import UKNA_BSEN1991_2_walkers_joggers

#%%

# Define a modal system
my_modal_sys = modalsys.ModalSys(name="my_modal_sys")
my_modal_sys.AddOutputMtrx(fName='accn_outputs.csv')
my_modal_sys.AddOutputMtrx(fName='vel_outputs.csv')
my_modal_sys.AddOutputMtrx(fName='disp_outputs.csv')

#%%

# Define some TMD systems
TMD1 = TMD(sprung_mass=10, nat_freq=1.0, damping_ratio=0.1, name='TMD1')
TMD2 = TMD(sprung_mass=20, nat_freq=1.2, damping_ratio=0.15, name='TMD2')

#%%

# Append TMDs to modal system
my_modal_sys.AppendSystem(child_sys=TMD1, Xpos_parent=30.0, DOF_child=0)
my_modal_sys.AppendSystem(child_sys=TMD2, Xpos_parent=50.0, DOF_child=0)
Beispiel #5
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"""

# Python dist imports
import numpy
import matplotlib.pyplot as plt

# DynSys package imports
import modalsys
from ped_dyn import UKNA_BSEN1991_2_crowd

#%%

bridgeClass = 'b'

# Define modal system
my_sys = modalsys.ModalSys(name="Bridge example", fname_modeshapes=None)

# Add output matrix
my_sys.AddOutputMtrx()

#%%

# Define files to define modeshapes along edges of deck strips
mshape_fnames = [["modeshapes_edge_MS_NSS.csv", "modeshapes_CL_MS_NSS.csv"],
                 ["modeshapes_CL_MS_SSS.csv", "modeshapes_edge_MS_SSS.csv"],
                 ["modeshapes_CL_NSS_SSS.csv", "modeshapes_edge_NSS_SSS.csv"]]
mshape_fnames = numpy.array(mshape_fnames)

# Define functions to define how wdith varies with chainage in each region

Beispiel #6
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import matplotlib.pyplot as plt

# DynSys imports
import modalsys
from damper import TMD

plt.close('all')

#%%

# Define modal system, based on input files
modal_params = {}
modal_params['Mass'] = 362000
modal_params['Freq'] = 0.88
modal_params['DampingRatio'] = 0.007
modal_sys = modalsys.ModalSys(name='Main system',
                              modalParams_dict=modal_params)
modal_sys.add_outputs()

# Get frequency response of systems without TMDs
freq_response_rslts = modal_sys.calc_freq_response(fmax=2.0)

# Get maximum ordinate of frequency response relating modal force to modal disp
max_Gf_noTMD = npy.abs(npy.max(freq_response_rslts.Gf[0, 0]))

#%%


def RRF_given_TMDs(M=[5000, 4800],
                   f=[0.88, 0.92],
                   eta=[0.15, 0.05],
                   Xpos=[50.0, 60.0],
Beispiel #7
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# -*- coding: utf-8 -*-
"""
Runs train analysis
"""

import numpy
import matplotlib.pyplot as plt
import os

import dyn_analysis
import loading
import modalsys

#%%
# Define system to analyse
bridge_sys = modalsys.ModalSys(name='My Bridge')
bridge_sys.AddOutputMtrx()
"""
Determine reasonable time step to use for results presentation
Note: only influences time interval at which results are output
Scipy's solver determines its own time step for solving ODEs
"""
max_fn = numpy.max(bridge_sys.modalParams_dict['Freq'])
dt_reqd = 0.01  #(1/max_fn)/2 # sampling freq to be 10x maximum modal freq - rule of thumb for accurately capturing peaks

#%%

## Run moving load analysis for specified speed
train_code = 'trainA6'
speed_kmph = 450
loading_obj = loading.LoadTrain(fName="train_defs/%s.csv" % train_code,
Beispiel #8
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# Standard imports
import numpy
import matplotlib.pyplot as plt

# DynSys imports
import modalsys
import damper
import ped_dyn

plt.close('all')

#%%

# Define modal system
bridge_sys = modalsys.ModalSys(name="Stockton Infinity Footbridge",
                               fname_modeshapes='deck_modeshapes.csv',
                               fname_modalParams='modal_params.csv')

#%%

# Define TMD systems and append to bridge system
damper.append_TMDs(modal_sys=bridge_sys,
                   fname="TMD_defs.csv",
                   append=True,
                   verbose=True)

fig = bridge_sys.PlotModeshapes()[0]
fig.savefig('modeshapes.png')

#%%