Shock and Vibration 14 (2007) 393–406 393
IOS Press

An efficient modal control strategy for the
active vibration control of a truss structure

Ricardo Carvalhala, Vicente Lopes J́uniora,∗ and Michael J. Brennanb
aMechanical Engineering Department, Universidade Estadual Paulista, UNESP/Ilha Solteira, 15385-000 Ilha
Solteira, SP, Brazil
bInstitute of Sound and Vibration Research, University of Southampton, Southampton, SO17 1BJ, UK

Received 29 September 2005

Revised 30 August 2006

Abstract. In this paper an efficient modal control strategy is described for the active vibration control of a truss structure. In
this approach, a feedback force is applied to each mode to be controlled according to a weighting factor that is determined by
assessing how much each mode is excited by the primary source. The strategy is effective provided that the primary source is at
a fixed position on the structure, and that the source is stationary in the statistical sense. To test the effectiveness of the control
strategy it is compared with an alternative, established approach namely, Independent Modal Space Control (IMSC). Numerical
simulations show that with the new strategy it is possible to significantly reduce the control effort required, with a minimal
reduction in control performance.

Keywords: Intelligent truss structures, independent modal space control, piezoelectric stack actuator

1. Introduction

A truss structure is one of the most commonly used structures in aerospace and civil engineering [1]. Because it is
desirable to use the minimum amount of material for construction, the trusses are becoming lighter and more flexible
which means they are more susceptible to vibration. Passive damping is not a preferred vibration control solution
because it adds weight to the system, so it is of interest to study the active control of such a structure. A convenient
way of controlling a truss structure is to incorporate a piezoelectric stack actuator into one of the truss members [2].
A key issue is how many actuators to use [3], and where to place them [1]. Another issue is the dynamics of the
actuators and whether these are important in terms of how they affect the vibration of the structure, and of course
the control system [4,5]. Preumont et al. [6] used a local control strategy to suppress the low frequency vibrations of
a truss structure using two actuators. Their strategy involved the application of integrated force feedback using two
force gauges each co-located with the two piezoelectric actuators, which were fitted into different beam elements in
the structure. In the work presented here, a single actuator is used and its position is determined using the method
described by Carvalhal et al. [7]. The approach taken by Lammering et al. [5] is adopted to account for the actuator
dynamics.

In many structures the lower modes of vibration have the most energy and are hence more critical. For this reason,
these modes are often targeted for active control so that energy is not wasted in controlling the higher modes of
vibration [8]. A sensible control strategy, therefore, is to model the system in terms of modal parameters and to
control individual modes using modal space control strategies, such as IndependentModal Space Control (IMSC) [9].
One of the problems with this approach, however, is that large control forces can be required as identified by Singh

∗Corresponding author. E-mail: vicente@dem.feis.unesp.br.

ISSN 1070-9622/07/$17.00 2007 – IOS Press and the authors. All rights reserved



394 R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure

Fig. 1. Schematic of the truss structure showing the location of the actuator and sensors.

Fig. 2. Piezoelectric active member.

et al. [10]. They proposed a modification to IMSC strategy, which they called Efficient Modal Control (EMC),
whereby the modal control forces are tailored according to the contribution of particular modes to the vibration at
the position of interest. In the same paper, Singh et al. [10] applied the EMC technique to a cantilever beam to
demonstrate the efficacy of the EMC approach.

The aim of this paper is to study the applicability of the EMC technique to control the first few modes of a
truss structure. It is an extension of the work previously presented by the authors [11] and applies the control
strategy suggested by Singh et al. [10] to a more realistic structure. The study involves analysis and computer
simulations. First, the modal control gains are determined for the IMSC strategy. This involves the development
of a state-space model of the structure from an initial finite element model, which includes both active and passive
structural members. Classical Linear Quadratic Regulator (LQR) control theory is then used to determine the modal
control gains. These are then modified in-line with the EMC approach, by considering the contribution of the modal
amplitudes to the vibration at one point on the structure.

The paper is organized as follows. Following the introduction, Section 2 describes the way in which the state-
space model of the structure is developed. In Section 3 the control strategy is outlined, and in Section 4 computer
simulations demonstrate the effectiveness of the approach when applied to a truss structure. Finally, in Section 5,
some general conclusions are drawn.

2. Model of the truss structure

In this section a state-space model of the truss structure that is suitable for control analysis is developed. The
approach is similar to that described by Gawronski [12]. The structure considered consists of an active member that



R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure 395

includes an actuator, and passive members, as shown in Fig. 1. A model of the passive members can be obtained using
the finite element approach. With some modification it can also be used to model the active member, which consists
of a piezoelectric stack actuator and two metallic bars as shown in Fig. 2. The stiffness matrix for an active member
is obtained by combining the stiffness matrix for the piezoelectric actuator with the stiffness matrices of two metallic
bars; each piezoelectric active member has an additional electrical degree of freedom. The mechanical-electric
stiffness matrix for the piezoelectric active member, described by Lammering et al. [5], is

Kel =




k1k2k3

k1k2 + k1k3 + k2k3

−k1k2k3

k1k2 + k1k3 + k2k3

−k1c2k3

k1k2 + k1k3 + k2k3−k1k2k3

k1k2 + k1k3 + k2k3

k1k2k3

k1k2 + k1k3 + k2k3

k1c2k3

k1k2 + k1k3 + k2k3−k1c2k3

k1k2 + k1k3 + k2k3

k1c2k3

k1k2 + k1k3 + k2k3

−c2
2 (k1 + k3)

k1k2 + k1k3 + k2k3
− c̄2




(1)

where

ki = EiAi/Li
, c2 = npeA2/L2

, c̄2 = n2
pεA2

/
L2

(2a,b,c)

ande is the piezoelectric coefficient,ε is the dielectric coefficient;E i, Ai andLi are the elastic modulus, the
cross-section area, and the length of theith part of the active member respectively;n p is the number of elements in
the piezoelectric stack actuator. The global equations of motion for the truss structure are determined by assembling
the matrices for the active and passive members to give

Mq̈ + Dq̇ + Kq = Btut (3a)

y = Cqq + Cq̇q̇ (3b)

whereq, q̇ and q̈ aren-length vectors of displacement, velocity and acceleration, respectively;M, D andK are
then × n mass, damping, and stiffness matrices, respectively;Bt =

[
Bw Bv

]
is an × s spatial coupling matrix

related to thes-length input vectorut =
[
w v

]T
, wherew is the disturbance vector,v is the vector of applied

voltages to the actuators (in the study presented here there is only one actuator), and the superscript (.)T denotes
the transpose. Ther-length output vector isy, which is related to the displacement and velocity vectors through the
matricesCq andCq̇, respectively. Assuming that the damping matrixD can be diagonalised, Eqs (3a) and (3b) can
be written in modal coordinates as

q̈m + 2ZΩq̇m + Ω2qm = Bmu (4a)

y = Cqmqm + Cq̇mq̇m (4b)

where qm = Φ−1q is the vector of modal coordinates andΦ is an n × n modal matrix; Z =
0.5

(
ΦTMΦ

)−1/2 (
ΦTKΦ

)−1/2 (
ΦTDΦ

)
is then×n damping matrix;Ω =

(
ΦTMΦ

)−1/2 (
ΦTKΦ

)1/2
is then×

n natural frequency matrix;Bm =
(
ΦTMΦ

)−1 ΦTBt is then×s input matrix andCqm = CqΦ, Cq̇m = Cq̇Φ are
ther×n modal displacement and velocity matrices, respectively. Equations (4a) and (4b) are a set ofn independent
equations for each mode of the system. The equations for theith mode are given by

q̈mi + 2ζiωiq̇mi + ω2
i qmi = Bmiu (5a)

yi = Cqmiqmi + Cq̇miq̇mi (5b)

whereBmi is the ith row of the modal spatial coupling matrix andCqmi and Ċqmi are theith columns of the
displacement and velocity matrices, respectively.

For analysis of the control system it is convenient to write the equations describing dynamics of the structure in
state-space form as

ẋ = Ax + Bu (6a)



396 R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure

Table 1
Material properties and dimensions of the smart truss structure

Structure Active member

Elastic modulus (GPa) 210 52.6
Mass density (kg/m3) 7800 7600
Cross-section area (m2) 2.83× 10−5 5.65× 10−5

L(m) 0.5 0.25
Piezoelectric coefficient (N/V.m) — 44
Dielectric coefficient (F/m) — 2.12× 10−8

Table 2
Optimal feedback gains for the controlled modes

Mode number (i) Gdi(103) Gvi(103)

1 1.00 0.44
2 5.02 0.45
3 2.98 0.43
4 −1.05 −0.38

y = Cx (6b)

whereA is the 2n× 2n dynamic matrix,B is the 2n × s input matrix andC is ther× 2n output matrix. The state
vectorx of modal displacements and velocities consists of 2n independent components,x i, that represent the state

of each mode and are given byx i =
{

qmi

q̇mi

}
, whereqmi is theith modal displacement anḋqmi is theith modal

velocity. The modal state-space realization is characterized by the block-diagonal dynamic matrix and the related
input and output matrices given by

A = blockdiag(Ami), B =




...
Bmi

...


 , C =

[ · · · Cmi · · ·
]

(7)

where Ami =
[
0 1
−ω2

i −2ζiωi

]
, andBmi andCmi are 2×s, andr× 2 blocks respectively,ζ i is the ith modal

damping ratio,ωi is theith natural frequency, and the subscript (.)mi relates to theith mode.
The order of the state-space modal is large. However, a low order model is essential for the successful implemen-

tation of a controller. This can be obtained by partitioning the modes into those that will be controlled and those that
will not be controlled. Thus, Eqs (6a) and (6b) can be written as.{

ẋc
ẋr

}
=

[
Ac 0
0 Ar

] {
xc
xr

}
+

[
Bc
Br

]
u (8a)

y =
[
Cc Cr

]{
xc
xr

}
(8b)

where the subscripts (.)c and (.)r are for the controlled and residual modes, respectively.

3. Efficient modal control (EMC)

This control strategy is a simple modification of the IMSC, developed by Meirovitch and Baruh [9], and a
description of it is given in this section. As mentioned in the introduction, this method has been applied to a cantilever
beam [10], and here it is applied to a truss structure.

In IMSC the control force vector in physical space is given by (Jia [13])

ut = Lcu, whereLc =
(
LT L

)−1
LT (9)



R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure 397

(a) 

 (b) 

Fig. 3. Uncontrolled response for the reduced model with an impulsive force at (a) sensor 1 and (b) sensor 2.

whereL =
(
ΦT MΦ

)−1 ΦT Bt. An independent controller can be designed for each mode, hence the modal
feedback force in each modeu i is dependent onqmi andq̇mi alone, so that

ui = −Gdiqmi − Gviq̇mi (10)

whereGdi andGvi are the displacement and velocity modal gains, respectively. This ensures that the modal equations



398 R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure

(a)

 (b) 

Fig. 4. Spectra of the uncontrolled response for (a) sensor 1 and (b) sensor 2.

are not coupled through feedback. The modal control forcesu i are determined using optimal control theory [14],
which determines feedback control gains by minimizing a quadratic performance indexJ i given by

Ji = 1
2

∞∫
0

(
xT

i Qixi + Riu
2
i

)
dt = 1

2

∞∫
0

(
ω2

i q2
mi + q̇2

mi + Riu
2
i

)
dt (11)



R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure 399

(a)

(b) 

Fig. 5. Uncontrolled and controlled response for the structure at (a) sensor 1 and (b) sensor 2, when the IMSC strategy is implemented.

where the diagonal matrixQi is the weighting matrix for theith modal state vector;R i is the weighting factor for the

ith modal control force, which trades control performance with control effort. WhenQ i =
[
ω2

i 0
0 1

]
, the performance

index is related to the sum of the potential energyω 2
i q2

mi and the kinetic energẏq2
mi of the vibrating system as well

as the required input control effortu2
i . Theith modal control force can be determined by



400 R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure

Table 3
Performance of the IMSC and EMC approaches for the ten first modes

Modes
Uncontrolled IMSC EMC

Frequency Mag. Damping Frequency Mag. Damping Attenuation Frequency Mag. Damping Attenuation
(Hz) (dB) ratio (10−4) (Hz) (dB) ratio (10−4) (dB) (Hz) (dB) ratio (10−4) (dB)

1 70.5 −71.6 2.2 70.8 −102.5 91.7 −30.9 70.6 −103.0 99.8 −31.4
2 81.8 −81.2 2.6 81.8 −125.9 346.0 −44.7 81.8 −117.0 134.0 −35.8
3 117.6 −72.4 3.7 117.3 −107.2 178.6 −34.8 117.6 −104.8 144.7 −32.4
4 202.1 −92.2 6.3 202.1 −106.5 37.2 −14.3 202.1 −99.2 15.7 −7.0
5 240.3 −112.9 7.6 240.3 −107.3 4.3 +5.6 240.3 −111.5 6.8 +1.4
6 315.1 −103.9 9.9 315.1 −104.8 10.4 −0.9 315.1 −104.5 10.1 −0.6
7 423.4 −133.1 13.3 423.4 −130.2 13.4 +2.9 423.4 −131.8 13.3 +1.3
8 467.9 −136.3 14.7 467.9 −136.3 14.7 0.0 467.9 −136.3 14.7 0.0
9 483.8 −112.0 15.2 483.8 −112.0 15.2 0.0 483.8 −112.0 15.2 0.0

10 580.9 −145.3 18.2 580.9 −145.3 18.2 0.0 580.9 −145.3 18.2 0.0

ui = −R−1
i BT

miPixi (12)

whereBT
mi is the part of the matrixB in Eq. (4a) that is related to theith control input,P i is a semi-definite symmetric

matrix, and it is governed by the Riccati equation (Xu and Jiang [15])

PiAmi + AT
miPi + Qi − PiBmiR

−1
i B−1

mi Pi = 0 (13)

Since all modal states are not available for feedback in Eq. (12), the estimated modal statesx̂ i are used instead and
the modal control force becomes

u = −Gx̂c (14)

whereG is the controller gain matrix. To estimate the full controlled modal statex̂ c from the outputy, a deterministic
modal observer can be used [14], which is described by

ˆ̇xc = Acx̂c + Bcuc + H [y − Ccx̂c] (15)

whereH is the observer gain matrix, which can be determined optimally by solving a matrix Riccati equation. For
a time-invariant modal observer, the Riccati matrix satisfies the algebraic matrix Riccati equation

SAT
c + AcS− SCT

c W−1CcS + V = 0 (16)

whereS is the Riccati equation solution. Equation (16) yields the optimal observer gain matrixH for theV andW
weighting matrices

H = SCT
c W−1 (17)

The error vector,ec = x̂c − x, can be written as

ėc = (Ac − HCc) ec + HCrxr (18)

Combining Eqs (8a), (14) and (18) the system of equations can be written in matrix form as


ẋc

ẋr

ėc


 =


Ac − BcG 0 −BcG

−BrG Ar −BrG
0 −HCr Ac − HCc







xc

xr

ec


 (19)

The term−BrG is the cause of the residual modes being excited by the control forces, which is known as control
spillover. This term has no effect on the eigenvalues of the closed-loop system and it cannot destabilize the system,
although it can cause some degradation in the performance. On the other hand, the term−HC r can cause instability
in the residual modes, which is known as observation spillover. However, a small amount of modal damping, inherent
in the structure can help to reduce the effects of observation spillover. Another way to minimize this effect is to use
a large number of sensors or to filter the sensor signals, in order to diminish the contribution of residual modes [14].

Equation (19) can be solved to determine the closed-loop response of the system in any mode. Fang et al. [8] show
in a recent study that the modal control forces may increase the amplitudes of higher modes of vibration (uncontrolled



R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure 401

(a)

 (b) 

Fig. 6. Spectra of the uncontrolled and controlled system at (a) sensor 1 and (b) sensor 2 when the IMSC strategy is implemented.

modes) if the IMSC algorithm is used to design a control system for a multi-degree-of-freedom structural system.
Thus, the effects of control forces on higher modes must be considered in the response analysis.

The analysis above relates to IMSC. As mentioned previously, one of the problems with this control strategy is that
if a number of modes are excited, the voltages supplied to the control actuator(s) can be very large [10]. A significant
reduction in the control force can be achieved with only a small reduction in performance, if the primary excitation



402 R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure

Fig. 7. Feedback control voltage applied by the piezoelectric actuator when the IMSC strategy is implemented.

is at a fixed position on the structure, and if this source is stationary in the statistical sense. The information about
the uncontrolled system response can be utilized to tailor the control forces. Singh et al. [10] observed that when the
IMSC strategy was implemented on a cantilever beam, the optimal feedback gains were higher for higher modes of
vibration, and the amplitude of vibration was generally lower in these modes. In the truss structure, the increase in
control force amplitude with frequency for IMSC was not observed. This is probably because the modal gains are
dependent on the type of structure and the placement of the actuators and sensors.

The EMC control strategy simply weights the control gains for each mode according to their contribution to the
overall vibration level at a particular location on the structure. The ratios of the amplitudes of different modes are
first calculated with respect to the mode having maximum amplitude, when the structure is excited by the primary
excitation source alone. The feedback gains are then weighted such that the modes that have smaller amplitudes
have a smaller gain. Thus the gains for theith, jth andkth modes are determined by

Gr(i) : Gr(j) : Gr(k) = 1 :
displacement(j)
displacement(i)

:
displacement(k)
displacement(i)

(20)

whereGr(i) is the gain ratio of the modei, and theith mode has the maximum amplitude.

4. Numerical simulations

Numerical simulations are presented to demonstrate the efficacy of the EMC approach applied to a truss structure,
and the results are compared to the IMSC approach on the same structure. The structure considered is a 2-bay truss
structure with 31 members as shown in Fig. 1; nodes 1 to 4 are clamped. The passive members are made of steel
with a diameter of 6 mm, and the damping is assumed to be proportional to the stiffness and mass matrices so that
D = 10−6. K + 10−4. M. At each node there is a centralized mass block of 0.3 kg, and the piezoelectric actuator
comprises 250 circular piezoelectric elements. The material properties and dimensions are given in Table 1. Each
node has three degrees of freedom (dof), translation inx, y andz directions, so the truss structure has 24 active dofs,
and the state-space model consequently has an order of 48. The strategy is to control the first four modes (8 states),
with the sixteen remaining modes (32 states) being considered as residual modes.

The optimal positioning of the active member with the objective of controlling the first four modes of this structure,
using one actuator and four sensors (to estimate the modal states), was developed using the H∞ norm for each



R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure 403

(a)

(b) 

Fig. 8. Uncontrolled and controlled response for the structure at (a) sensor 1 and (b) sensor 2, when the EMC strategy is implemented.

sensor/actuator candidate position. This methodology is described by Carvalhal et al. [7]. These positions correspond
to a situation where the actuator and sensors couple into and sense the motion to be controlled effectively. The
optimal placement of the actuator and of the two sensors (to show the control performance) is shown in Fig. 1. The
four sensors used for the observer design are located at nodes 5 and 9 in thex andy directions.

An impulsive force is applied at node 9 in thex direction of the structure, which excites some modes of the system.



404 R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure

(a)

(b) 

Fig. 9. Spectra of the uncontrolled and controlled system at (a) sensor 1 and (b) sensor 2 when the EMC strategy is implemented.

This type of force is used as it will excite many modes of vibration and hence will be a difficult test for the control
system. The uncontrolled responses of the truss structure in the time domain at sensors 1 and 2 are shown in Fig. 3.
The spectra of the uncontrolled responses are shown in Fig. 4. It should be noted that the response at sensor 1 is
much larger than that at sensor 2. Using Eq. (12) withR = 10−5 IMSC feedback gains for the four controlled modes
of the structure can be calculated and are given in Table 2. The actuator forces for different modes are summed to



R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure 405

Fig. 10. Feedback control voltage applied by the piezoelectric actuator when the EMC strategy is implemented.

give the resultant force required and hence the total voltage applied can be calculated. Figure 5 shows the controlled
response of the truss structure measured by both sensors. With this configuration and weighting factor, the overall
amplitude decreases from the initial value of about 0.8× 10−3 (m) to 0.5× 10−4 (m) in about 0.3 s measured by
sensor 1 and from 2.5× 10−4 (m) to 0.4× 10−4 (m) in about 0.3 s measured by sensor 2. Figure 6 compares the
spectra of uncontrolled and controlled responses at sensors 1 and 2. Figure 7 shows the feedback voltage supplied
to the actuator. The maximum control voltage required is 2350 V.

From the response spectra at sensor 2 shown in Fig. 4(b), the displacement amplitudes in the first four modes are
found to be [32.2, 9.1, 24.5, 2.8]× 10−5 m/N, respectively. Thus, optimal gains in these modes for the EMC control
strategy were reduced by the ratios given in Eq. (20). Figure 8 shows the response of the structure when these gains
are applied. For EMC, the amplitude at sensor 1 decreases from the initial value of about 0.8× 10−3 (m) to 1.2×
10−4 (m) in about 0.3 s and from 2.5× 10−4 (m) to 0.6× 10−4 (m) in about 0.3 s at sensor 2. Figure 9 compares
the spectra of the uncontrolled and controlled system at sensors 1 and 2. The maximum control voltage supplied to
the actuator with the EMC approach is 900 V, and is shown in Fig. 10.

Table 3 lists the vibration attenuation in the first ten modes for the IMSC and EMC approaches, compared with
the uncontrolled system. It can be seen that in both approaches the control systems are effective. The amplitude of
the first mode is attenuated by about 31 dB in each case. With the EMC strategy, the second, third and fourth modes
are attenuated less than for the IMSC strategy as expected, but the performance is still very good. Furthermore, the
controller does not influence the amplitude of mode 6, which is not explicitly included in the controller. Some peaks
increase, however, for example the amplitudes of modes 5 and 7 increase by 5.6 dB and 2.9 dB, respectively, for
the IMSC strategy, and by 1.4 dB and 1.3 dB respectively for the EMC strategy. This occurs, because of control
spillover.

A single quantity can be used as an overall judge of the control performance. It is the area under the curve of
the absolute value of the displacement response. For the responses in Fig. 3 this is 17.5× 10−5 m.s and 3.75×
10−5 m.s for sensor 1 and sensor 2, respectively. For the IMSC strategy (Fig. 5), these values are 3.10× 10−5 m.s
for sensor 1 and 1.28× 10−5 m.s for sensor 2, giving a reduction of 82.3% and 65.9%, respectively. For the EMC
strategy (Fig. 8), the values are 7.15× 10−5 m.s for sensor 1 and 1.91× 10−5 m.s for sensor 2, giving a reduction
of 59.1% and 49.1%, respectively. Figures 5 and 8 shows that EMC and IMSC have comparable settling times,
0.58 s for EMC and 0.44 s for IMSC. The difference lies in the vibration attenuation of the second, third and fourth
modal amplitudes, for which there is much reduced control effort with the EMC approach. Figures 7 and 10 clearly



406 R. Carvalhal et al. / An efficient modal control strategy for the active vibration control of a truss structure

show that the maximum feedback voltage supplied to the actuator for the EMC strategy is reduced by a factor of 2.6
compared with the IMSC strategy. Also, the voltage amplitudes at the settling times are 35.7 V and 21.4 V for the
IMSC and EMC strategy respectively, i.e., it is reduced by a factor of 1.6.

5. Conclusions

In this paper, an efficient modal control strategy has been applied to a truss structure, and its effectiveness has been
compared to that of the IMSC strategy. Optimal modal feedback gains are independent of the applied force for the
IMSC algorithm, but by tailoring the gains according to the modal amplitudes at the location of interest, which are
dependent on the applied force, significant reductions in the control force can be achieved, without a commensurate
loss in performance. Simulations on a truss structure have demonstrated that, provided the nature of the primary
excitation is known and is stationary, the simple modification of the IMSC strategy is very worthwhile.

Acknowledgements

The first two authors would like to acknowledge the financial support from Research Foundation of the State of São
Paulo (FAPESP-Brazil). Prof. Brennan acknowledges the support from FAPESP (process number 04/133242-3 –
Visiting Professor) and the Leverhulme Trust, UK.

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