Optimization of Biodynamic Seated Human Models Using Genetic Algorithms

doi:10.4236/eng.2010.29092

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Engineering, 2010, 2, 710-719

doi:10.4236/eng.2010.29092 Published Online September 2010 (http://www.SciRP.org/journal/eng)

Optimization of Biodynamic Seated Human Models Using

Genetic Algorithms

Wael Abbas1*, Ossama B. Abouelatta2, Magdi El-Azab3, Mamdouh Elsaidy4, Adel A. Megahed5

1Engineering Physics and Mathematics Department, Faculty of Engineering (Mataria), Helwan University,

Cairo, Egypt

2Production Engineering and Mechanical Design Department, Faculty of Engineering, Mansoura University,

Mansoura, Egypt

3,4Mathematics and Engineering Physics Department, Faculty of Engineering, Mansoura University,

Mansoura, Egypt

5Mathematics and Engineering Physics Department, Faculty of Engineering, Cairo University, Cairo, Egypt

E-mail: wael_abass@hotmail.com

Received May 16, 2010; revised July 21, 2010; accepted August 4, 2010

Abstract

Many biodynamic models have been derived using trial and error curve-fitting technique, such that the error

between the computed and measured biodynamic response functions is minimum. This study developed a

biomechanical model of the human body in a sitting posture without backrest for evaluating the vibration

transmissibility and dynamic response to vertical vibration direction. In describing the human body motion, a

three biomechanical models are discussed (two models are 4-DOF and one model 7-DOF). Optimization

software based on stochastic techniques search methods, Genetic Algorithms (GAs), is employed to deter-

mine the human model parameters imposing some limit constraints on the model parameters. In addition, an

objective function is formulated comprising the sum of errors between the computed and actual values (ex-

perimental data). The studied functions are the driving-point mechanical impedance, apparent mass and seat-

to-head transmissibility functions. The optimization process increased the average goodness of fit and the

results of studied functions became much closer to the target values (Experimental data). From the optimized

model, the resonant frequencies of the driver parts computed on the basis of biodynamic response functions

are found to be within close bounds to that expected for the human body.

Keywords: Biodynamic Response, Seated Human models, Simulation, Genetic algorithms

1. Introduction

Recently, many people have focused their attention on

the ride quality of vehicle which is directly related to

driver fatigue, discomfort, and safety. As traveling in-

creases, the driver is more exposed to vibration mostly

originating from the interaction between the road and

vehicle. Whole-body vibration occurs in transportation

and when near heavy machinery [1]. The vibrations

cause the operator’s whole body to vibrate, as opposed to

just one part of their body, says their hand or foot. Harm-

ful effects of whole-body vibration are experienced when

the exposure time is longer than the recommended stan-

dard set by ISO 2631-1 [2].

Biodynamic responses of seated human occupant ex-

posed to vibration have been widely characterized to

define frequency-weightings for assessment of exposure,

to identify human sensitivity and perception of vibration,

and to develop seated body models [3]. The biodynamic

response of the human body exposed to vibration have

been invariably characterized through measurement of

force motion relationship at the point of entry of vibra-

tion “To-the-body response function”, and transmission

of vibration to different body segments “Through-the-

body response function”. Considering that the human

body is a complex biological system, the “To-the-body”

response function is conveniently characterized through

non-invasive measurements at the driving point alone.

The vast majority of the reported studies on biodynamic

response to whole-body vibration have considered vibra-

tion along the vertical axis alone.

The reported studies on biodynamic responses under

W. ABBAS ET AL.

711

vertical vibration are thoroughly reviewed, specifically

their response characteristics, experimental conditions,

and the measured data. The biodynamic response char-

acteristics reported in terms of either the driving-point me-

chanical impedance (DPMI) or apparent mass (APMS),

and the seat-to-head transmissibility (STHT) are classi-

fied under different experimental conditions used in the

study.

In early studies, various biodynamic models have been

developed to depict human motion from single-DOF to

multi-DOF models. These models can be divided as dis-

tributed (finite element) models, lumped parameter mod-

els and multi-body models. The distributed model treats

the spine as a layered structure of rigid elements, repre-

senting the vertebral bodies, and deformable elements

representing the intervertebral discs by the finite element

method. Multi-body human models are made of several

rigid bodies interconnected by pin (two-dimensional) or

ball and socket (three-dimensional) joints, and can be

further separated into kinetic and kinematic models.

The lumped parameter models consider the human

body as several rigid bodies and spring-dampers. This

type of model is simple to analyze and easy to validate

with experiments. However, the disadvantage is the

limitation to one-directional analysis. Coermann [4],

measured the driving-point impedance of the human

body and suggested 1-DOF model. Suggs et al. [5] de-

veloped a 2-DOF human body. It was modeled as a

damped spring-mass system to build a standardized ve-

hicle seat testing procedure. A 3-DOF analytical model

for a tractor seat suspension system is presented by Te-

wari et al. [6]. It was observed that the model could be

employed as a tool in selection of optimal suspension

parameters for any other type of vehicles. Boileau et al.

[7] used an optimization procedure to establish a 4-DOF

human model based on test data. In addition, Zong and

Lam [8] validated a 4-DOF nonlinear model originating

from Liu et al. [9].

Furthermore, Muksian and Nash [10] presented a 6-

DOF nonlinear model dedicated to the analysis of vibra-

tion imposed on a seated human. This model was modi-

fied by Patil et al. [11], who suggested a 7-DOF model.

This model was further incorporated with a tractor model

to evaluate vibration responses of an occupant-tractor

system. A complete study on lumped-parameter models

for seated human under vertical vibration excitation has

been carried out by Liang and Chiang [12], based on

analytical study and experimental validation.

On the other hand, GA optimization is used by Bau-

mal et al. [13] to determine both active control and pas-

sive mechanical parameters of a vehicle suspension sys-

tem, to minimize the extreme acceleration of the passen-

ger’s seat, subjected to constraints representing the re-

quired road holding ability and suspension working

space. The GA is used to solve the problem and results

were compared to those obtained by simulated annealing

technique and found to yields similar performance mea-

sures.

It is clear that the lumped-parameter model is probably

one of the most popular analytical methods in the study

of biodynamic responses of seated human subjects,

though it is limited to one-directional analysis. However,

vertical vibration exposure of the driver is our main con-

cern. Therefore, this paper carries out a thorough survey

of literature on the lumped-parameter models for seated

human subjects exposed to vertical vibration.

This work aims to develop a biomechanical model of

the human body in a sitting posture without backrest for

evaluating the vibration transmissibility and dynamic

response to vertical vibration direction.

2. Biodynamic Response of the Human Body

The biodynamic response of a seated human body ex-

posed to whole-body vibration can be broadly catego-

rized into two types. The first category “To-the-body”

force motion interrelation as a function of frequency at

the human-seat interface, expressed as the driving-point

mechanical impedance or the apparent mass. The second

category “Through-the-body” response function, gener-

ally termed as seat-to-head transmissibility for the seated

occupant.

The DPMI relates the driving force and resulting ve-

locity response at the driving point (the seat-buttocks

interface), and is given by [3]:

() ()

() () ()

jFj

Zj Vj









 (1)

where, ()



is the complex DPMI, ()



and

()Vj



or ()



 are the driving force and response

velocity at the driving point, respectively.



is the an-

gular frequency in rad/s , and j = 1 is the complex

phasor.

In a similar manner, the apparent mass response re-

lates the driving force to the resulting acceleration re-

sponse, and is given by [14]:

()

() ()

APMS jaj



 (2)

where, ()aj



is the acceleration response at the driv-

ing point. The magnitude of APMS offers a simple

physical interpretation as it is equal to the static mass of

the human body supported by the seat at very low fre-

quencies, when the human body resembles that of a rigid

W. ABBAS ET AL.

712

mass. The above two functions are frequently used in-

terchangeably, due to their direct relationship that given

by:

()

()DPMI j

APMS jj





 (3)

The biodynamic response characteristics of seated oc-

cupants exposed to whole body vibration can also be

expressed in terms of seat-to-head transmissibility, which

is termed as “through-the-body” response function. Un-

like the force-motion relationship at the driving-point,

the STHT function describes the transmission of vibra-

tion through the seated body. The STHT response func-

tion is expressed as:

()

() ()

Hj aj



 (4)

where, ()



is the complex STHT, ()



is the

response acceleration measured at the head of seated

occupant, and ()aj



is the acceleration response at the

driving point. The above three functions have been

widely used to characterize the biodynamic responses of

the seated human subjects exposed to whole body vibra-

tion.

3. Experimental Data

Many mathematical models on the study of biodynamic

responses of seated human subjects have been published

based on individual test data over the years. However,

significant variation is known to exist between various

data sets. Such variation may be partly attributed to the

differences associated with the methodology, experi-

mental conditions or subject population used by different

investigators.

3.1. Basic Assumptions on Experimental Data

The biodynamic of seated human subjects exposed to

vertical vibration has been widely assessed in terms of

STHT, DPMI, and APMS. The first function refers to the

transmission of motion through the body, while the other

two relate the force and motion at the point of vibration

input to the body. A variety of test data used to charac-

terize these response functions has been established us-

ing widely varied test conditions. This has resulted in

considerable discrepancies among the data. To avoid

these discrepancies, a preliminary conclusion was reach-

ed that any attempt to define generalized values might

not be appropriate unless it could be defined specifically

for a particular application or within a limited and well-

defined range of situations [12].

Data sets satisfying the following requirements are se-

lected for the synthesis of biodynamic characteristics of

the seated human subjects [15-17].

 A human subject is considered to be sitting erect

without backrest support, irrespective of the hands’

position.

 Body masses will be limited within 49-94 kg.

 Feet are supported and vibrated.

 Analysis is constrained to the vertical direction.

 Vibration excitation amplitudes are below 5 m/s2,

with the nature of excitation specified as being si-

nusoidal wave.

 Excitation frequency range is limited to 0.5-20 Hz.

3.2. Experimental Results

While vertical DPMI, APAS, and STHT characteristics

were not measured as part of this study, applicable target

values were defined on the basis of a synthesis of pub-

lished data Boileau [14], Liang et al. [12,17] and Wu [18].

Figure 1 shows upper, lower, and target values of DPMI,

APMS, and STHT magnitude established as target values

within 0.5-20 Hz frequency range, respectively.

4. Biomechanical Modeling

The human body in a sitting posture can be modeled as a

mechanical system that is composed of several rigid

bodies interconnected by springs and dampers. In this

study, three types of biomechanical models are discussed

to describe the vertical response: 4-DOF Wan and

Schimmels model, 4-DOF Boileau and Rakheja model,

and 7-DOF Patil and Palanichamy model as shown in

Figure 2.

4.1. Wan and Schimmels 4-DOF Model

In this model, the seated human body was constructed

with four separate mass segments interconnected by five

sets of springs and dampers, with a total human mass of

60.67 kg [19]. The four masses represent the following

body segments: head and neck (m1), upper torso (m2),

lower torso (m3), and thighs and pelvis (m4). The arms

and legs are combined with the upper torso and thigh,

respectively. The stiffness and damping properties of

thighs and pelvis are (k5) and (c5), the lower torso are (k4)

and (c4), upper torso are (k2, k3) and (c2, c3), and head are

(k1) and (c1). The schematic of the model is shown in

Figure 2(a), and biomechanical parameters of the model

are listed in Table 1.

The equations of motion of the human-body can be

obtained as follows:

W. ABBAS ET AL.

713

111 121 12

221 121 12223

22 332 432 4

332 232 23

434434

444 344343 24

32 4

()()

()()()

()()

()()()

(

mxc xxkxx

mxc xxk xxcxx

kx xcx xkx x

mxc xxkxx

cxxkx x

mxcx xkxxcxx

kx x

 

  



 



 

 







 



 54 54

)( )( )

se se

cx xkx x











 



(5)

0 24 6 810 1214 16 18 20

0.2

0.4

0.6

0.8

1.2

1.4

1.6

Frequency (Hz)

STHT

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(a)

0 2 4 6810 1214 16 1820

500

1000

1500

2000

2500

3000

Frequency (Hz)

DPMI (N s/m)

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(b)

0 24 6 810 12 14 16 18 2

500

1000

1500

2000

2500

3000

Frequency (Hz)

APMS (kg)

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(c)

Figure 1. Experimental data of (a) STHT; (b) DPMI; and (c)

APMS.

(a) (b)

(c)

Figure 2. Biomechanical models. (a) Wan and Schimmels

4-DOF model; (b) Boileau and Rakheja 4-DOF model; and

4.2. Boileau and Rakheja 4-DOF Model

The human-body consists of four mass segments inter-

connected by four sets of springs and dampers with a

total mass of 55.2 kg [7], as shown in Figure 2(b). The

four masses represent the following four body segments:

the head and neck (m1), the chest and upper torso (m2),

the lower torso (m3), and the thighs and pelvis in contact

with the seat (m4). The mass due to lower legs and the

feet is not included in this representation, assuming their

negligible contributions to the biodynamic response of

the seated body. The stiffness and damping properties of

W. ABBAS ET AL.

714

thighs and pelvis are (k4) and (c4), the lower torso are (k3)

and (c3), upper torsos are (k2) and (c2), and head are (k1)

and (c1). The biomechanical parameters of the model are

listed in Table 2. The equation of motion of the human

body can be obtained as follows:

111 121 12

221 121 12223

22 3

332 232 23334

33 4

443 243 2444

()()

()()()

()

()()()

()

()()()

()

mxc xxkxx

mxcx xkxxcx x

kx x

mxcxxkx xcx x

kx x

mxcx xkx xcx x

kx x

 

 

 

























(6)

4.3. Patil and Palanichamy 7-DOF Model

Based on Muksian’s 6-DOF model, a 7-DOF nonlinear

model was developed by Patil and Palanichamy [11]. In

this model, the human body consists of seven mass seg-

ments interconnected by eight sets of springs and damp-

ers, with total mass of 80 kg. The seven masses represent

the following body segments: head and neck (m1), back

(m2), upper torso (m3), thorax (m4), diaphragm (m5), ab-

domen (m6) and thighs and pelvis (m7). The arms and

legs are combined with the upper torso and thigh, respec-

tively. The stiffness and damping properties of thighs

and pelvis are (k8) and (c8), abdomen are (k6) and (c6),

the diaphragm are (k5) and (c5), the thorax are (k4) and

(c4), the torso are (k2, k3) and (c2, c3), back are (k7) and

(c7), and head are (k1) and (c1). The schematic of the

model is shown in Figure 2(c), and biomechanical pa-

rameters of the model are listed in Table 3.

The equation of motion of the human-body can be

obtained as follows:

111 121 12

221 121 12727

72 722 322 3

332 232 23334

33 4

443343 344 45

445

()()

()()()

()

()()()

(

mxc xxkxx

mxcx xkxxcx x

kx xcx xkx x

mxcxxkxxcxx

kx x

mxc xxk xxcxx

kx x

 

  



  

 

 



 









554 454 455 56

55 6

665 565566 67

66 7

776 676 67727

72 78787

)

()()()

()

()()()

()

()()()

()()( )

sese

mxcxxkxxc xx

kxx

mxcxxk xxc xx

kx x

mxc xxkxxc xx

kx xcx xkx x



 

 















 















(7)

5. Estimation of Biodynamic Response

Characteristics

There are two methods to solve system equations of mo-

tion; time domain and frequency domain. Frequency

domain solutions are often of more interest than the time

history and can usually be performed more conveniently

than in the time domain. However, for the solutions to be

applicable, the equations must either be linear, or lin-

earized. Frequency domain analysis employs the Fourier

transformation.

The system equations of motion, Equations (5-7), for

the model can be expressed in matrix form as follows:





















 

xCxKxf

 

 (8)

where,









C and





are n × n mass, damping,

and stiffness matrices, respectively;





is the force

vector due to external excitation.

By taking the Fourier transformation of equation (8),

the following matrix form of equation can be obtained:



 



() ()

jKMjCFj



 





 



(9)

where,





()



and





()



are the complex Fourier

transformation vectors of





and





respectively.

ω is the excitation frequency. Vector



()



contains

complex displacement responses of n mass segments as a

function of ω

(





123

( ),(),( ),......()

jxjxj xj



 





()



, consists of complex excitation forces on the

mass segments as a function of ω as well.

The driving-point mechanical impedance is defined as

the ratio of driving force (summation of spring and

damping forces between pelvis and seat) to the driving-

point velocity (input velocity of the seat). Accordingly,

DPMI can be represented as follows (e.g. Boileau and

Rakheja, model):

44 4

()

() ()

()

DPMI j

kxjk

jx j









(10)

Seat-to-head transmissibility is defined as the ratio of

output responses (head) to input excitation.

()

() ()

STHTj



 (11)

Apparent mass, can be expressed in terms of DPMI,

Equation (3), as follows (e.g. Boileau and Rakheja

model):

44444

()

()()

()

DPMI j

APMS jj

ckxj ck

jxjj













 



(12)

W. ABBAS ET AL.

715

Table 1. The biomechanical parameters of the Wan and

Schimmels model (Before and after optimization).

Damping coefficient

(N.s/m) Spring constant (N/m)

Mass

(kg) Before After Before After

m1 =

4.17 c1 = 250 c1 =310 k1 =

134400

k1 =

166990

m2 = 15 c2 = 200 c2 =200 k2 =

10000

k2 =

10000

m3 =

5.5 c3 = 909.1 c3 =

909.1

k3 =

192000

k3 =

144000

m4 = 36 c4 = 330 c4 =330 k4 =

20000

k4 =

20000

5 = 2475 c5 =2475 k5 = 49340 k5 =49340

6. Development of Models

Many biodynamic models have been derived using trial

and error curve-fitting technique, such that the error be-

tween the computed and measured biodynamic response

functions is minimum. Such curve-fitting methods may

lead to a proper fit over a specific frequency range, but

rarely provide good results when extended over a broad

frequency range. Alternatively, nonlinear programming

based optimization techniques may be effectively em-

ployed to determine the model parameters, involving the

use of a constrained optimization algorithm in conjunc-

tion with well defined biodynamic response function [14].

A constrained objective function may be defined to

minimize the error between the computed and the target

values of specific biodynamic response function over a

specific frequency range.

Optimization software based on stochastic techniques

search methods, Genetic algorithms (GAs), is employed

to determine the human model parameters imposing

some limit constraints on the model parameters. An ob-

jective function is formulated comprising the sum of

errors between the computed and of the driving-point

mechanical impedance, apparent mass and seat-to-head

transmissibility functions. The model thus derived can

provide reasonable correlation with the impedance, ap-

parent mass and transmissibility characteristics.

Starting with an assumed set of model parameters, the

differential equations of motion are solved for unit dis-

placement excitation to drive the driving-point mechani-

cal impedance using Equation (1), apparent mass using

Equation (3), and seat-to-head transmissibility using

Equation (4). At each iteration of search, the sum of

square errors defined by an objective function over the

entire frequency range is examined, and the procedure is

re-initiated with modified parameter values when the

error exceeds that from the previous search. The search

is terminated when the computed error approaches the

minimum value.

6.1. Objective Function

The objective function is selected to comprise the squar-

ed sum errors associated with driving-point mechanical

impedance 1

()U apparent mass 2

()Uand seat-to-head

transmissibility functions 3

()U to minimize the error

between the computed and the target values. This study

used the classical weighted sum approaches to solve a

multi-objective optimization problem as follows:

112 23 3

.( ).().()OBJWUWUWU



 (13)

where,

() (),

iti

UDPMIjDPMIj

















() (),

iti

UAPMS jAPMSj















() ()

iti

USTHT jSTHTj















In the above equations ()

DPMI j



, ()

APMS j



and ()

STHT j



are the target values of driving-point

mechanical impedance, apparent mass, and seat-to-head

transmissibility, respectively. The target values of DPMI,

APMS, and STHT are illustrated in Figure 1. 1

W, 2

and 3

W are weighting factors to emphasize the relative

importance of the terms.

The limit constraints are calculated as ±25% variations

about the biomechanical parameters of the three models.

6.2. Evaluation of Biodynamic Seated Human

Models

To evaluate the prediction accuracy of each human mo-

del in comparison with experimental results from litera-

ture, the ratio of the root-mean-square error to the mean

value is calculated with the following equation:

Goodness of fit (



)

()/(2)







 (14)

where e



is the test datum, c



is the calculated result

from each model, and N is the number of test data points

used in the comparison. The fit of predicted results to test

data is perfect when



is equal to 1. The predictions on

seat-to-head transmissibility, the driving-point mechani-

cal impedance, and apparent mass for each lumped-pa-

rameter model will be compared using Equation (14) to

obtain prediction accuracy.

7. Results and Discussion

1) Wan and Schimmels modified model

The solution of the constrained optimization problem,

W. ABBAS ET AL.

716

Equation (5), resulted in an optimized model parameters

are listed in Table 1. Figure 3 presents a comparison of

the driving-point mechanical impedance, apparent mass,

and seat-to-head transmissibility with the target data,

respectively. It is obvious that the developed model bet-

ter fits target values compared with Wan and Schimmels

model. The calculated goodness of fit for seat-to-head

transmissibility is 92% compared to 90.9% for Wan and

Schimmels model.

On the other hand, the developed model matches the

target values better with a goodness of fit of 82.1% for

05 10 15 20

0.2

0.4

0.6

0.8

1.2

1.4

1.6

Frequency (Hz)

STHT

Wan and Schimmels model (



= 90.9 %)

Developed model (



= 92 %)

:Wan and Schimmels model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(a)

05 10 15 20

500

1000

1500

2000

2500

3000

Frequency (Hz)

DPMI (N s/m)

Wan and Schimmels model (



= 80.1 %)

Developed model (



= 82.1 %)

:Wan and Schimmels model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(b)

05 10 15 20

100

Frequency (Hz)

APMS (kg)

Wan and Schimmels model (



= 86.8 % )

Developed model (



= 87.1 % )

:Wan and Schimmels model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(c)

Figure 3. Comparison of biodynamic response characteris-

tics for Wan model, and optimized model with the target

data.

driving-point mechanical impedance and 87.1% apparent

mass compared to 80.1% and 86.8%, for Wan and

Schimmels model, respectively.

In addition, the peak values of the Wan and Schim-

mels model occur at 4 Hz for seat-to-head transmissibil-

ity, 3.7 Hz for apparent mass, and 7.2 Hz for driving-

point mechanical impedance, whereas for the optimized

model, they occur at 4.05, 3.8 and 6.9 Hz, respectively.

2) Boileau and Rakheja modified model

The solution of the constrained optimization problem,

Equation (6), resulted in optimized model parameters

which are listed in Table 2.

Simulation results are illustrated in Figure 4. This fig-

ure presents a comparison of the driving-point mechani-

cal impedance, apparent mass and seat-to-head transmis-

sibility with the target data, respectively. It is obvious

that the optimized model better fits target values than the

Boileau and Rakheja model; with a goodness of fit for

seat-to-head transmissibility is 80.6%, compared to

76.8% for the Boileau and Rakheja model.

In addition, the developed model matches the target

values better with a goodness of fit of 84% for driv-

ing-point mechanical impedance compared to 80.1% for

Boileau and Rakheja model. Optimized model matches

the target values better with a goodness of fit of 87% for

apparent mass compared to 86.7% for the Boileau and

Rakheja model.

On the other hand, the peak values of the Boileau and

Rakheja model occur at 4.7 Hz for seat-to-head trans-

missibility, 4.6 Hz for apparent mass, and 5.5 Hz for

driving-point mechanical impedance, whereas for the

optimized model, they occur at 4.95, 4.55 and 5.9 Hz,

respectively.

3) Patil and Palanichamy modified model

In a similar way, the solution of the constrained opti-

mization problem, Equation (7), resulted in an optimized

of the following model parameters are listed in Table 3.

Figure 5 presents a comparison of the driving-point me-

chanical impedance, apparent mass, and seat-to-head

transmissibility with the target data, respectively. It was

observed that the developed model better fits target val-

ues compared the Patil and Palanichamy model, with a

goodness of fit for seat-to-head transmissibility is 35%

compared to 22% for Patil and Palanichamy model. On

the other hand, the developed model matches the target

values better with a goodness of fit of 13% for driving-

point mechanical impedance compared to 1% for Patil

and Palanichamy model. The developed model matches

the target values with a goodness of fit of 34% for appar-

ent mass compared to 0% for Patil and Palanichamy model.

W. ABBAS ET AL.

717

Table 2. The biomechanical parameters of the Boileau and

Rakheja model (Before and after optimization).

Damping coefficient

(N.s/m) Spring constant (N/m)

Mass (kg)

Before After Before After

m1 =

5.31 c1 =400 c 1 =460 k1 =

310000

k1 =

356370

m2 =

28.49 c2 = 4750 c 2 =5400 k2 =

183000

k2 =

208570

m3 =

8.62 c3 = 4585 c 3 =5190 k3 =

162800

k3 =

187110

m4 =

12.78 c4 = 2064 c 4 =2370 k4 =90000 k4 =

103480

05 10 15 20

0.2

0.4

0.6

0.8

1.2

1.4

1.6

1.8

Frequency (Hz)

STHT

Boileau and Rakheja model (



= 76.8 %)

Developed model (



= 80.6 %)

:Boileau and Rakheja model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(a)

05 10 1520

500

1000

1500

2000

2500

3000

Frequency (Hz)

DPMI (N s/m)

Boileau and Rakheja model (



= 80.1 %)

Developed model (



= 84 %)

:Boileau and Rakheja model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(b)

05 10 15 20

100

Frequency (Hz)

APMS (kg)

Boileau and Rakheja model (



= 86.7 % )

Developed model (



= 86 % )

:Boileau and Rakheja model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(c)

Figure 4. Comparison of biodynamic response characteris-

tics for Boileau model, and optimized model with the target

data.

05 10 15 20

0.5

1.5

2.5

Frequency (Hz)

STHT

Patil et al. model (



= 22 %)

Developed model (



= 35 %)

:Patil et al. model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(a)

05 10 15 20

500

1000

1500

2000

2500

3000

3500

4000

Frequency (Hz)

DPMI (N s/m)

Patil et al. model (



= 01 %)

Developed model (



= 13 %):Patil et al. model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(b)

2 46 810 12 1416 18 20

100

150

200

250

Frequency (Hz)

APMS (kg)

Patil et al. model (



= - % )

Developed model (



= 34 % )

:Patil et al. model

:Developed model

:Experimental Upper limit

:Experimental Lower limit

:Experimental Target value

(c)

Figure 5. Comparison of biodynamic response characteris-

tics for Patil model, and optimized model with the target

data.

In addition, the peak values of Patil and Palanichamy

model occur at 2.5 Hz for seat-to-head transmissibility,

2.5 Hz for apparent mass, and 2.6 Hz for driving-point

mechanical impedance, whereas for the developed model,

they occur at 2.1, 2.1 and 2.3 Hz, respectively.

The simulations of the three lumped-parameter models

listed in this study for seated human subjects exposed to

vertical vibration exposure are listed in Table 4. It is

observed that the 4-DOF optimization of Wan and

Schimmels can give the best estimation on seat-to-head

transmissibility with goodness of fit values of 92%. The

W. ABBAS ET AL.

718

Table 3. The biomechanical parameters of the Patil and

Palanichamy model (Before and after optimization).

Damping coefficient

(N.s/m) Spring constant (N/m)

Mass (kg)

Before After Before After

m1 = 5.55 c1 =3651 c 1 =3542 k1 =

53640

k1 =

41978

m2 = 6.94 c2 =3651 c 2 =2685 k2 =

53640

k2 =

40943

m3 =

33.33 c3 =298 c 3 =351 k3 =8941 k3 =1001

m4 =

1.389 c4 =298 c 4 =237 k4 =8941 k4 =845

m5 =

0.4629 c5 =298 c 5 =354 k5 =8941 k5 =1052

m6 = 6.02 c6 =298 c 6 =225 k6 =8941 k6 =1035

m7 = 27.7 c7 =3651 c 7 =2929 k7 =

53640

k7 =

39575

8 =378 c 8 =463 k8 =

25500

k8 =

19325

goodness of fit is 82.1% for driving-point mechanical

impedance. On the other hand, the development model

matches the target values better with a goodness of fit of

87.1% for apparent mass compared to all models.

8. Conclusions and Recommendations

A study on the biodynamic models of seated human sub-

jects exposed to vertical vibration is carried out. A three

lumped-parameter models from literature have also been

analyzed and optimized using genetic algorithms to

match an experimental data in terms of STH transmissi-

bility, DPM impedance, and AP mass. It is shown that

the optimized 4-DOF Wan and Schimmels model can

give the best estimation on STH transmissibility, DPM

impedance, AP mass with goodness of fit values of

91.2%, 82.1%, and 87.1%, respectively. In addition, it

Table 4. Result of STHT, DPMI, and APMS for different models.

STHT DPMI APMS

Model Name Peak fre-

quency (Hz)

Goodness of

fit

(%)

Peak fre-

quency (Hz)

Goodness of

fit

(%)

Peak fre-

quency (Hz)

Goodness of

fit

(%)

Goodness of

fit average

(%)

DOF

Target values 5.1 4.8 4.4

Wan model 4 90.9 7.2 80.1 3.7 86.8 85.8

4 Optimized Wan model 4.05 92 6.9 82.1 3.8 87.1 87

Boileau model 4.7 76.8 5.5 80.1 4.6 86.7 81.2

4 Optimized Boileau 4.95 80.6 5.9 84 4.55 87 83.86

Patil model 2.5 22 2.6 1 2.5 0 7.67

7 Optimized Patil model 2.1 35 2.3 13 2.1 34 27.7

has the highest average of goodness of fit (87%). So, this

model is recommended for the study of biodynamic re-

sponses of seated human subjects exposed to vertical

whole body vibration. The biomechanical parameters of

the Wan and Schimmels model that match the experi-

mental data was changed for the head as c1 = 310 N.s/m

and k1 = 166990 N/m, respectively; and for upper torso

stiffness as k3 = 144000 N/m. From the model, the main

body resonant frequencies computed on the basis of both

biodynamic response functions are found to be within

close bounds to that expected for the human body.

This research provides a comprehensive understanding

of the aforementioned biodynamic responses. Future

research may be extended to the following:

1) Therefore, further research can be conducted on the

other lumped-parameter models from literature. This

work will be done after applying an optimization proc-

esses to determine the much closer one that match ex-

perimental data to STH transmissibility, DPM impedance,

and AP mass values.

2) Quarter, semi, and full car suspension system in-

cluding seat-human car suspension system should be

analyzed and validated to find the actual frequency re-

sponses of driver parts.

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