Jtam.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

2, 40, 2002

ESTIMATION OF DYNAMIC RESPONSE OF BUILDINGS

WITH LOAD BEARING WALLS USING RESPONSE SPECTRA

AND NEURAL NETWORKS

Krystyna Kuźniar

Pedagogical University of Cracow

e-mail: kkuzniar@wsp.krakow.pl

The paper deals with application of neural networks and response spectra
for estimation of dynamic response of medium-height buildings with load
bearing walls. Averaged spectra are also used. Computed results are com-
pared with experimental ones on actual structures. Results from the study
show that effects of the neural network analysis are quite satisfactory.

Key words: neural network, response spectra, dynamic response

1. Introduction

The estimation of dynamic response of buildings (displacements and iner-
tial forces) is a very important problem of structural dynamics. The dynamic
response of buildings subjected to seismic-type excitations by tests on actual
full-scale buildings was described e.g. in Ciesielski et al. (1995) and Maciąg
(1986). However a theoretical structural dynamic analysis involves many com-
plex tasks like creating an idealizedmodel of abuildingand selection of ground
flexibility parameters.Besides, theproblem is relative to very complex structu-
res as buildings, in particular – prefabricated buildings.Recently, some papers
have dealt with using the neural network technique for dynamic problems (cf.
e.g. Chen et al., 1995; Cheng and Popplewell, 1994). Earthquake response
spectra are often used in analysis and design of structures. But both response
spectra andneural networks are used for vibration problems e.g. inGhaboussi,
Lin (1998) and Cheng, Popplewell (1994). The problem related to simulation
of the displacement response in the time domain of a building subjected to
seismic-type excitations (one-step algorithm) was discussed in Kuźniar et al.
(2000).



484 K.Kuźniar

This paper is concerned with application of artificial neural networks for
estimation of the dynamic response of medium-height buildings (five-storey
buildings) with load bearing walls. They are prefabricated buildings erected
using the panel or block technology, so they are particularly sensitive to dy-
namic effects. The sets of training and testing patterns were formulated on
the basis of tests performed on real structures, that means – on actual full-
scale buildings. Displacement response spectra are utilized here. The trial of
estimation of averaged ground spectra and neural network usefulness to real
building dynamic response calculations are also presented in this paper.

2. Analysed buildings

Typical residential, prefabricated, with load bearingwalls, five-storey buil-
dings were tested. Buildings of theWUF-GT84 type (one object), C/MBY/V
(III) type (one object),DOMINO-68 type (one object) andWUF-T-67-S.A./V
type (one object) were erected in the large panel technology and buildings of
the BSK type (two objects) in large block technology. The walls constituting
a transverse-longitudinal system are the vertical bearing elements in the bu-
ildings. Every storey is 2.7m or 2.8m high. All the buildings have basements
and they are founded on different grounds with concrete strip foundations.
In Fig.1 a selected pattern of the plan and vertical section of the considered
buildings are shown.

Fig. 1. Plan and vertical section of the BSK type building



Estimation of dynamic response of ... 485

3. Description of the tests on real buildings

Full scale testsweremademany times for a periodof a fewyears (Ciesielski
et al., 1995). Firings of explosives in nearby quarries were the sources of the
building vibrations. The investigated buildings were located at a distance of
300m to 1200m fromthe site of the explosions.Theblowing chargeswere fired
in different places on the walls of excavations. Hence, various distances and
angles of thewaves reaching analysedbuildingswere obtained.Explosionswere
carried out using the technology of long, almost vertical as well as horizontal
holes.Theamount of the explosives varied from300kg to 2100kg in the case of
vertical holes, and 45kg in the case of horizontal ones. Themain attentionwas
devoted tomeasurements of horizontal vibration components in the directions
parallel to transverse and longitudinal axis of the buildings. The seismographs
were placed on the ground in front of the building, at the basement level
and at the fourth floor. In Table 1 in the third, fourth and fifth columns the
numbers of recorded building vibrations at the above mentioned three levels
are collected, respectively. In Fig.2, as an example, vibrations of the building
of the BSK type in the longitudinal direction on the ground, on the basement
and fourthfloor level are shown, respectively.Oneof the explosions (longholes
technology) in the nearby quarry was the source of these vibrations.

Fig. 2. Vibrations in the longitudinal direction of the BSK type building developed
by one of explosions in the nearby quarry; (a) on the ground; (b) at the basement

level; (c) on the fourth floor level



486 K.Kuźniar

Table 1. Statement of experimental investigations of buildings

Number of recorded Number
Building Direction vibrations of

ground basement 4th floor patterns

1 2 3 4 5 6

seg. I Transverse 14 9 15 23
BSK (I) Longitudinal 7 13 14 20

seg. II Transverse 6 8 8 14
Longitudinal – 1 1 1

BSK (II) seg. I Transverse 4 – 4 4
Longitudinal – – – –

seg. I Transverse 11 10 21 21
WUF-GT 84 Longitudinal 2 8 8 10

seg. II Transverse 6 5 8 11
Longitudinal – 2 2 2

C/MBY/V (III) Transverse – 1 1 1
Longitudinal – 1 1 1

DOMINO-68 Transverse – 1 1 1
Longitudinal – 1 1 1

WUF-T-67-S.A./V Transverse – 1 1 1
Longitudinal – 1 1 1

Total number of patterns: 112

4. Calculation of dynamic response of prefabricated

medium-height buildings using neural networks

Thepaper concerns the following idea of estimation of the dynamic respon-
se of buildings by neural networks: the input vector includes the description
of excitation vibrations and information about the dynamic properties of the
building; on the output of the network the dynamic response of building is
expected.

All the recorded experimental data in the form of vibrations in the time
domain on the ground, the basement level and the fourth floor level were
first preprocessed. The data preprocessing was carried out in order to obtain
discrete values of variables. For all the excitation vibrations (the ground and
the basement level), the displacement response spectra (Sd) were calculated.



Estimation of dynamic response of ... 487

The range of the vibration period (T) was from0.025s to 1.0s with two steps:
0.01s and 0.02s. It can be stated that the forms of response spectra obtained
for the larger step T (0.02s) are very close to those estimated with greater
precision (step 0.01s). InFig.3 these twoversions of the responsedisplacement
ground spectra are compared for the transverse direction of the building of the
BSK type. These spectra were evaluated on the basis of vibrations caused by
various technologies of explosions in the quarry.

Fig. 3. Response displacement ground spectra for the transverse direction of the
BSK type building; (a) vertical holes technology of explosions; (b) horizontal holes

technology of explosions

Therefore, for the purpose of reduction of the neural network input vec-
tor dimension, it has been decided that the response spectra calculated with
∆T =0.02s would be used for further analysis. Additionally, the description
of excitations is confined to first twenty values of the displacement response
spectrum, from T = 0.025s to T =0.405s. The substantiation of this is the



488 K.Kuźniar

fact, that this range includes the fundamental natural periods of the analysed
buildings with a considerable margin.

Some of the excitation vibrations were recorded on the ground in front of
the buildings and some of them – at the basement level (cf. Table 1). But
in the contact ground – building foundation there is observed the reduction
of vibrations as a result of soil – structure interaction (cf. e.g. Ciesielski et
al., 1990, 1994, 1998). Therefore, not only the excitation (by e.g. response
spectrum), but also the place of its registration has to be described.

The dynamic properties of the analysed buildings (particularly values of
fundamental natural periods) depend on the ground flexibility, the building
dimension in the direction of vibrations, the equivalent bending stiffness and
the shear stiffness (cf. Maciąg, 1986; Maciąg andKuźniar, 1993; Kuźniar and
Maciąg, 1999). Theheight of the buildinghas also an effect on its fundamental
natural period. But the discussed buildings are typical five-storey buildings
and they are practically of the same height (every storey is 2.7m or 2.8m
high). That is why the height of the building is not taken into consideration
in the input vector.

Then the following input vector is proposed

X(25×1) = [d1,d2, ...,d20,p,Cz,b,s,r] (4.1)

where
di – digital values of the displacement spectrum, i=1, ...,20
p – parameter defining the place of recorded excitation; it was

taken p = 0.4 for vibrations recorded on the ground and
p=0.7 for vibrations recorded at the basement level

Cz – coefficient of the elastic uniformvertical deflection of the soil
basement

b – building dimension in the direction of vibrations
s – equivalent bending stiffness, s=

∑

iEIi/a
r – equivalent shear stiffness, r=

∑

iGAi/a
E,G – Young’s and Kirchhoff’s moduli, respectively
Ii,Ai – moment of inertia and area of the ith wall
a – length of the building.

The output of the network is the maximum displacement of the fourth
building floor

Y =Dmax (4.2)

In Table 1 the total number of patterns and their division among the
buildings and their vibration directions are put. The backpropagation neural



Estimation of dynamic response of ... 489

network of architecture 25-4-1 with the Resilient backpropagation learning
method was formulated. The sigmoid activation function was applied, so all
the parameters were scaled to the range [0.1,0.9].
The calculations for the input vector in the form of (4.3) are also made

X1(22×1) = [d1,d2, ...,d20,p,T ] (4.3)

where
di,p – parameters as in (4.1)
T – fundamental natural period of building determined by neural

analysis on the basis of parameters: Cz, b, s, r according to
Kuźniar andMaciąg (1999).

The output of the network is just the same as the output of 25-4-1 ne-
twork. The backpropagation neural network of structure 22-4-1 with the Re-
silient backpropagation learning method was applied. For the two versions of
networks the SNNS package (Zell, 1995) was used.
For eachof themaximumdisplacement of the fourthbuildingfloor (Dmax),

a relative error was calculated

erel =
(

1−
Dcommax
D
exp
max

)

·100% (4.4)

where
Dexpmax,D

com
max – maximum displacement of the fourth building floor,

experimental and computed by neural network, re-
spectively.

In Fig.4 the success rate (SR) for maximum displacements of the fourth
building floor is shown as a function of the relative error (erel) computed for
all the patterns (for networks: 25-4-1 and 22-4-1, respectively).
Using neural network analysis, Dmax with the relative error not greater

than 10% is predicted for 83% of patterns for network 25-4-1 and for 80% of
patterns for network 22-4-1. Each of the two network versions also allowed
determination of themaximum displacement of the fourth building floor with
the relative error not greater than 15% for above 90% of the patterns. Similar
results were obtained examining the transverse and longitudinal directions of
the buildings separately.
Figure 5 presents the estimation of neural network analysis usability for

the evaluation of the maximum displacement on the fourth building floor,
separately in the case of kinematic excitation recorded on the ground and at
the basement level.
It is stated that without regard for the place of recorded excitation (gro-

und or basement level), the effects are similar. It results from the fact, that



490 K.Kuźniar

Fig. 4. Success rate (SR) for maximum displacements of the fourth building floor vs.
relative error erel (all patterns); (a) network 25-4-1; (b) network 22-4-1



Estimation of dynamic response of ... 491

Fig. 5. Success rate (SR) for maximum displacements of the fourth building floor vs.
relative error erel; (a) network 25-4-1; (b) network 22-4-1



492 K.Kuźniar

the input vector includes information about the place of recorded excitation.
The parameter p, cf. (4.1), is the parameter describing the soil-structure in-
teraction. Thus, the relative errors not greater than 10%were obtained in the
case of about 80% patterns using displacement response spectra based both
on the vibrations on the ground and at the basement level. The relative er-
rors for above 90% patterns are not greater than 15% for each of the places
of excitation measurements. The above observations are very important from
the practical point of view. Using the proposed neural networks allows one
to take the soil-structure interaction into consideration in a very easy way.
Even then, when the building is only in the phase of design (which excludes
the excitations recording at the building basement level, of course), we can
predict its dynamic response well, having measured ground vibrations on the
place of its planned foundation.

5. Determination of the dynamic response by neural networks

and averaged spectra

Because of economic reasons, in engineering practice, recording of real
kinematic excitation is not possible for every building. Therefore, averaged
response spectra are permitted to be applied (cf. e.g. Maciąg et al., 1999).
The averaged response spectra are prepared on the basis of a huge number of
recorded vibrations for each region of tremors.

In Fig.6 the averaged displacement response spectra (Sd) for Chabry di-
strict in Opole, Poland are shown. Firings of explosives in the nearby quarry
were the sources of vibrations. The spectrawere determined separately for vi-
brations recorded on the ground in front of the BSK type building (cf. Fig.1)
and at its basement level. They are based on the vibrations recorded on the
ground and at the basement level at the same time and also in the cases, when
only the ground or basement vibrations were recorded. That explains the oc-
currence of greater ordinates of the averaged displacement response spectrum
(Sd) based on vibrations recorded at the basement level. If in computations of
Sd only the vibrations simultaneously recorded on the ground and at the ba-
sement level are taken into consideration, the obviously, in Fig.5 the effect of
vibrations reductionwill be evident as a result of the soil-structure interaction.

The neural networks of architecture 25-4-1 and 22-4-1 were trained and
tested using displacement response spectra determined on the basis of real
experimental data of the vibrations. Itwas stated that the application of these



Estimation of dynamic response of ... 493

Fig. 6. Averaged displacement response spectra for Chabry district in Opole, Poland

neural networks enables us to predict the dynamic response ofmedium-height
prefabricated buildings with satisfactory accuracy.

The thus trained networks were applied to the estimation usefulness of the
averaged displacement response spectra in the determination of the dynamic
responseof thebuildingof theBSKtype. For this purpose, in the inputvectors
definedby (4.1) and (4.3) respectively, instead of actual values of the displace-
ment spectrum: di, i=1, ...,20, the adequate values of averaged displacement
response spectra for Chabry district in Opole, Poland were put in.

Using network 25-4-1 and the averaged displacement response spectra,
Dmax with the relative error not greater than 30% were predicted for 90%
of patterns based on vibrations recorded on the ground and almost for 70%
of the patterns with the response spectra based on vibrations recorded at the
basement level.

When network 22-4-1 was used, the relative errors for Dmax were a little
greater. But the predicted values of maximum displacements of the fourth
building floors were too great. Therefore, from the engineering point of view,
the results were obtained in ”safety side”.

Thus, it is visible that in spite of application of the very approximate
excitation description (in the formof averaged displacement response spectra),
the discussed neural networks enable us to estimate the dynamic response of
a five-storey building of the BSK type with good accuracy.



494 K.Kuźniar

6. Conclusions

Application of displacement response spectra and using simple neural ne-
tworks allows us to determinemaximumdisplacements of the highest floors of
prefabricatedmedium-height buildings in a simple way without analysing the
equations of motion of the structures. Besides, the soil-structure interaction
can be taken into consideration. The comparison of the results of the neural
network analysis with the experimental ones on actual structures shows that
the computational accuracy is sufficient in practice. The method of the es-
timation of a building dynamic response proposed in this paper can also be
successfully used to prediction of responses of buildings in the design phase.

It seems that the analysed neural networks could also be applied to deter-
mination of the dynamic response of buildings with description of kinematic
excitation in the form of averaged spectra only. Then, of course, with regard
to the approximate character of excitations, the computed dynamic responses
of the buildings will be evaluated with a little greater errors.

References

1. Chen H.M., Qi G.Z., Yang J.C.S., Amini F., 1995, Neural network for
structural dynamic model identification, Journal of Engineering Mechanics,
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2. Cheng M., Popplewell N., 1994, Neural network for earthquake selection
in structural time history analysis,Earthquake Engineering and Structural Dy-
namics, 23, 303-319

3. Ciesielski R., Maciąg E., 1990, Traffic Vibrations and Their Influence on
Buildings, Wyd. Komunikacji i Łączności,Warsaw (in Polish)

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building-foundation dynamic interaction, Workshop WAVE’ 94, Ruhr – Uni-
versity Bochum, Germany

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vibration in precast buildings with bearing concrete walls, Archives of Civil
Engineering, 41, 3, 329-341

6. CiesielskiR.,Kawecki J.,MaciągE., 1998,Dynamicdiagnosticandactual
residential buildings protection of vibrations damaging influences on buildings
useful properties, Instruction 348/98, ITB,Warsaw (in Polish)



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7. Ghaboussi J., Lin Ch. J., 1998,Newmethod of generating spectrum compa-
tible accelerograms using neural networks,Earthquake Engineering and Struc-
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8. Kuźniar K., Maciąg E., 1999, Application of neural networks to estimation
of fundamental periodsofvibrationsof prefabricatedbuildings (inPolish),Proc.
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of buildings on different grounds, Earthquake Engineering and Structural Dy-
namics, 14, 925-932

11. Maciąg E., Kuźniar K., 1993, The influence of ground flexibility on the
fundamental frequencies of natural vibrations of medium-height buildings with
load bearing concrete walls,Archives of Civil Engineering, 39, 2, 139-151

12. Maciąg E., Tatara T., Jaśkiewicz K., 1999, Range of seismological inve-
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Ocena drgań budynków ścianowych na podstawie spektrów odpowiedzi

z wykorzystaniem SSN

Streszczenie

W pracy podjęto próbę zastosowania sztucznych sieci neuronowych oraz prze-
mieszczeniowych spektrów odpowiedzi do wyznaczenia dynamicznej odpowiedzi ścia-
nowych budynków prefabrykowanych o średniej wysokości. Wykorzystano również
uśrednione spektra odpowiedzi.Wyniki obliczeń porównano z rezultatami badań do-
świadczalnych na obiektach rzeczywistych.

Manuscript received February 21, 2001; accepted for print July 11, 2001