Compensation of Mismatched Disturbances for Nonlinear Plants with

Distributed Time-delay

Igor Furtat

1,2 a

, Pavel Gushchin

1,3 b

, Dmitrii Konovalov

2

and Sergey Vrazhevsky

1,2 c

1

Institute of Problems of Mechanical Engineering Russian Academy of Sciences, Bolshoj pr. V.O., 61,

St. Petersburg, Russia

2

ITMO University, Kronverksky pr., 49, St. Petersburg, Russia

3

Gubkin Russian State University of Oil and Gas (National Research University), Leninsky pr., 65, Moscow, Russia

Keywords: Backstepping, Disturbance, Time-delay.

Abstract: The paper deals with the robust algorithm for compensation of unknown mismatched disturbances

depending on a state vector of plants with distributed time-delay. The algorithm based on generalization of a

backstepping method and disturbance compensation method. The proposed control system compensates

disturbances with required accuracy. The simulation results illustrate the efficiency and robustness of the

suggested control system. System". MIMO System".

a

https://orcid.org/0000-0003-4679-5884

b

https://orcid.org/0000-0002-8813-2723

c

https://orcid.org/0000-0001-9725-5330

1 INTRODUCTION

The paper is devoted to a new robust scheme for

compensation of unknown mismatched disturbances.

It is known, that the backstepping method is

effective method for control of plant under

mismatched condition.

The first backstepping method is proposed in

(Kokotovic, 1992). In more detail the backstepping

method is presented in (Fradkov, Miroshnik, and

Nikiforov, 1999; Khalil, 2002). Currently there are a

lot of modification of the backstepping algorithm.

In (Chang and Cheng, 2010) a methodology of

designing the block backstepping controller for a

class of multi-input systems with mismatched

perturbations is proposed. Some adaptive

mechanisms are embedded both in the virtual input

controller and in the backstepping controllers such

that some part knowledge of the upper bound of

perturbation is not required.

The paper (Ma, Schilling, and Schmid, 2005) is

concerned with the adaptive sliding-mode control of

a class of nonlinear systems in nonlinear parametric-

pure-feedback form with mismatched uncertainties.

Backstepping design procedure is applied, which

leads to a new adaptive sliding-mode control.

Gaussian radial-basis-function networks are used to

approximate the unknown system dynamics. More

nodes are added to the networks progressively in

order to improve the transient behaviour. With ideal

sliding mode, asymptotic stability is reached.

In (Xu and Min, 2010) for a class of strict-

feedback nonlinear systems with mismatched

uncertainties, an adaptive backstepping fuzzy

controller design is presented. By applying

backstepping design strategy and online approaching

uncertainties with fuzzy approximator, the control

inputs and adaptive tuning rules are derived from the

Lyapunov stability theory. To deal with the problem

of extreme expanded operation quantity of

backstepping method, a nonlinear tracking

differentiator is introduced. By choosing suitable

design parameters, the developed control scheme

guarantees that all the signals of the closed-loop

system are uniformly ultimately bounded and the

system tracking error can reach to a very small

region around zero.

However, the above mentoined algorithms

cannot compensate disturbances with distributed

time-delay. For disturbances compensation there are

a lot of methods, for example (Bobtsov and

Kremlev, 2005; Tsykunov, 2007). The main idea of

Furtat, I., Gushchin, P., Konovalov, D. and Vrazhevsky, S.

Compensation of Mismatched Disturbances for Nonlinear Plants with Distributed Time-delay.

DOI: 10.5220/0007915202690275

In Proceedings of the 16th International Conference on Informatics in Control, Automation and Robotics (ICINCO 2019), pages 269-275

ISBN: 978-989-758-380-3

Copyright

c

269

disturbances compensation consists representation of

uncontrollable disturbances as a new function in the

control system which we can use for design of the

control system. Among of them the auxiliary loop

algorithm (Tsykunov, 2007.) is one of the

effectiveness algorithm. The auxiliary loop

algorithm based on parallel reference model

(auxiliary loop) to the plant. The auxiliary loop is

used for obtaining the uncertainties acting on the

plant. The idea of this method consists in

implementing an auxiliary loop with desired

parameters parallel to the plant. The difference

between the output of the plant and the output of the

auxiliary loop gives a function which depends on

parametric and external disturbances. This function

gives the control law that guarantees required

accuracy of the control system. The proposed

algorithm provides the tracking by the output of the

plant of the reference output with the required

accuracy. However, mismatched disturbances may

control system get unstable. It will be demonstrated

in Section 4.

In this paper we propose a new modified

backstepping algorithm with mismatched

disturbances compensation (MBADC), where

disturbances are presented nonlinear functions

depending on external bounded disturbances,

parametric uncertainties and state vector with

distributed time-delay. This algorithm is a

generalization of results (Khalil, 2002; Tsykunov,

2007) for robust control of nonlinear plants under

mismatched parametric uncertainties and external

disturbances. It is assumed that input signal and state

vector of the plant are available for measurement.

The proposed algorithm guarantees stabilization by

the plant state vector with the required accuracy.

The paper is organized as follows. The problem

statement is presented in Section 2. The MBADC for

control of nonlinear plants under mismatched

perturbations is proposed in Section 3. In Section 4

the efficient of MBADC is illustrated by modeling

of an unstable nonlinear plant. Also, in Section 4 the

comparison of the simulation results for the

MBADC, the backstepping algorithm and auxiliary

loop algorithm are presented. Concluding remarks

are given in Section 5. Appendix A gives the proof

of the MBADC.

2 PROBLEM STATEMENT

Consider the plant model with distributed time-delay

in the form

 

,,)()(

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

)()(

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

)()(

2

00

332

32

00

221

21

221

111

tftbutx

tfdtxdtxtxtx

txtx

tfdtxdtxxtx

txtx

n

h

n

h

n

h

n

h

n

















































(1)

where x(t) = [x

1

(t), x

1

(t), …, x

n

(t)]

T

is a state vector,

u(t)  R is an input,



i

()  R, i = 1, 2, …, n are

unknown functions depending on parametric

uncertainties and external disturbances, f is a vector

of unknown parameters, b > 0 is unknown constant

and [f

T

, b]

T

 ,  is a known bounded set, h

ij

,

i, j = 1, 2, …, n are unknown time delay.

We assume that signal x(t) is available for

measurement.

Additionally assume that the functions



i

()  R,

i = 1, 2, …, n are bounded or bounded on t and f, and

Lipchitz in x(t),







0

2

)(

ij

h

dtx



,







0

2

)(

ij

h

dtx



, ...,







0

)(

ij

h

n

dtx



, i, j = 1, 2, …, n.

The problem is to synthesis a control law such

that the goal condition holds



)(tx

for t > T, (2)

where



> 0 is a prespecified required accuracy,

T > 0 is a transient time, || is Euclidean norm of the

corresponding vector.

3 MAIN RESULT

Let us denote

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

00

1



















tfdtxdtxtx

ini

h

n

h

ii



The synthesis of the control system is split into n

steps. Auxiliary loops and auxiliary controls will are

designed on 1, …, n – 1 steps for compensation of

unknown function



i

. The control law u(t) will be

introduced on the n-th step.

Step 1. Introduce the first auxiliary loop in the

form

),()()(

2111

txtzctz 



(3)

where c

1

> 0 is a coefficient chosen by a designer.

ICINCO 2019 - 16th International Conference on Informatics in Control, Automation and Robotics

270

Taking into account the first equation of system

(1) and equation (3), rewrite the function



1

(t) = x

1

(t) – z

1

(t) as follows

.)()(

1111



 tzct



(4)

From (4) it follows that the function



1

() may be

rewritten in the form

).()(

1111

tzct 





(5)

Substituting (5) to the first equation of (1), we

have

).()()()(

11121

tzcttxtx 





(6)

Assume that the function x

2

(t) is a control signal

in (6) and define x

2

(t) in the form x

2

(t) = v

1

(t). Since

the function

)(

1

t





is not available for measurement,

we introduce the first auxiliary control law v

1

(t) as

follows

),(

ˆ

)()(

1111

ttctv





(7)

where

)(

ˆ

1

t



is an estimate of the function

)(

1

t





.

Substituting (7) to (6), we get

),()()(

1111

ttxctx







(8)

where

)(

ˆ

)()(

111

ttt







is an error estimate.

Step i (2 ≤ i ≤ n – 1). Since v

i

(t) is not real

control law, we consider the i-th error function e

i -

1

(t) = x

i

(t) – v

i - 1

(t) as follows

),(

~

)()(

11

ttxte

iii









(9)

where

).()(

~

1

tvt

iii 







Introduce the i-th auxiliary loop in the form

),()()( txtzctz

iiii





(10)

where c

i

> 0 is a coefficient chosen by a designer.

Taking into account (9) and (10), rewrite the

function



i

(t) = e

i - 1

(t) – z

i

(t) as follows

).(

~

)()( ttzct

iiii







(11)

From (11) it follows that the function

)(

~

t

i



may

be rewritten in the form

).()()(

~

tzctt

iiii







(12)

Substituting (12) to (9), we have

).()()()(

11

tzcttxte

iiiii









(13)

Assume that function x

i + 1

(t) is a control signal in

(13) and define x

i + 1

(t) in the form x

i + 1

(t) = v

i

(t).

Since the function

)(t

i





is not available for

measurement, we introduce the second auxiliary

control law v

i

(t) as follows

),(

ˆ

)()( ttctv

iiii





(14)

where

)(

ˆ

t

i



is an estimate of the function

)(t

i





.

Substituting (14) to (13), we get

),()()(

11

ttecte

iiii









(15)

where

)(

ˆ

)()( ttt

iii







is an error estimate.

Step n. Since v

n

(t) is not real control law,

consider the n – 1-th error function e

n - 1

(t) = x

n

(t) –

v

n - 1

(t) in the form

),(

~

)()(

1

ttbute

nn









(16)

where

).()(

~

1

tvt

nnn 







Introduce the n-th auxiliary loop in the form

),()()( tutzctz

nnn







(17)

where c

n

> 0 and



> 0 are coefficients chosen by a

designer.

Taking into account (16) and (17), rewrite the

function



n

(t) = e

n - 1

(t) – z

n

(t) as follows

 

),()(

~

)()( tubttzct

nnnn







(18)

From (18) it follows that the function

)(

~

t

n



may

be rewritten in the form

).()()(

~

tzctt

nnnn







(19)

Substituting (19) to (16), we get

).()()()(

1

tutzctte

nnnn









(20)

Since the function

)(t

n





is not available for

measurement, we introduce the control law u(t) as

follows

 

,)(

ˆ

)(

1

)( ttctu

nnn







(21)

where

)(

ˆ

t

n



is an estimate of the function

)(t

n





.

Substituting (21) to (20), we get

),()()(

11

ttecte

nnnn









(22)

where

)(

ˆ

)()( ttt

nnn







is an error estimate.

The signals

)(t

i





, i = 1, 2, ..., n are not available

for measurement, because it depends on derivatives

of x(t). Therefore, we introduced the estimate

functions

)(

ˆ

t

i



, i = 1, 2, ..., n of the functions

)(t

i





,

Compensation of Mismatched Disturbances for Nonlinear Plants with Distributed Time-delay

271

i = 1, 2, ..., n at each step. For implementation of

)(

ˆ

t

i



, i = 1, 2, ..., n use the following observers

)()(

ˆ

)(

ˆ

1

ttt

iii 









,

,...,,2,1 ni 

(23)

where



> 0 is enough small number.

Theorem: There exist constants c

i

> 0, i = 1, 2, ..., n

and µ

0

> 0 such that for µ ≤ µ

0

the control system

consisting of auxiliary loops (3), (10), (17), auxiliary

control laws (7), (14), control law (21), observers

(23) provides goal (2) for plant (1).

The proof of Theorem is given in Appendix.

It is shown that the proposed algorithm based on

multi-agent system design, where each equation is

associated as appropriate agent. The additional

investigation have shown that the proposed

algorithm is effective for dynamical networks with

unknown distributed time-delays and mismatched

parametric and external disturbances.

4 EXAMPLE

Consider the plant model with distributed time-delay

in the form

 

,,)()(

,,,)(),()()(

22

0

22121

12

tftbutx

tfdtxtxtxtx

h



























(24)

where f = [f

1

, f

2

]

T

The set  is defined by the

following inequalities:

–10 ≤ f

1

≤ 10, –10 ≤ f

2

≤ 10.

The problem is to synthesis the control system

providing goal condition (2).

Let us design the control system. Consider

auxiliary loops in the following form

,,

2222111

uzczxzcz







(25)

where c

1

= c

2

= 1 and



= 1.

Introduce the auxiliary control law v

1

(t) and the

control law u(t) as follows

 

,

ˆ

1

,

ˆ

2221111







 cucv

(26)

where



1

(t) = x

1

(t) – z

1

(t),



2

(t) = e

1

(t) – z

2

(t) and

e

1

(t) = x

2

(t) – v

1

(t).

Introduce the observers in the forms

),(

1

)(

ˆ

),(

1

)(

ˆ

2211

t

p

tt

p

t



















(27)

where p = d / dt, µ = 0.01.

Let all initial conditions be zero in the control

system.

Let us choose the functions of (24) as follows

 



.2,)(3.1sin)()(

,1,)()(sin5.01

22

0

2

122

12

0

1111

22

12









hdtxttxtxf

hdtxtxtf

h



(28)

For comparison we also consider the synthesis of

control systems using the backstepping algorithm

(Khalil, 2002) and the auxiliary loop algorithm

(Tsykunov, 2007). According to (Khalil, 2002) the

backstepping algorithm is presented by the

following equations

 

,)(

,

11212

1

12

1111













xcbecu

xcv

(29)

where e

1

(t) = x

2

(t) – v

1

(t). Algorithm (29) depends on

functions



i

, i = 1, 2, therefore, implementations of

(29) requires that functions



i

, i = 1, 2 must be

known.

According to (Tsykunov, 2007), the auxiliary

loop algorithm is presented by the following

equations:

equation of the auxiliary loop

),()(

21

10

)( tutxtx

aa





















(30)

equation of the control law

   

),(10

1

)(21)( t

p

ttu











(31)

where



(t) = x(t) – x

a

(t). Algorithm (30), (31) can

compensate only function



2

and coefficient b and

cannot compensate function



1

. Therefore, algorithm

(30), (31) may be unstable for appropriate values of

the function



1

.

Consider two cases.

Case 1. Let f

1

= 1 and f

2

= 1 in (24) and functions



i

, i = 1, 2 are known.

Case 2. Let f

1

= 2 and f

2

= 3 in (24) and functions



i

, i = 1, 2 are unknown.

In Fig. 1-6 the transients are presented for the state

vector x(t) which is obtained by proposed MBADC,

the backstepping algorithm and the auxiliary loop

algorithm for each of two cases. In Fig.1-6 black

curve and red curve correspond to the signals x

1

(t)

and x

2

(t) respectively.

ICINCO 2019 - 16th International Conference on Informatics in Control, Automation and Robotics

272

Figure 1: The transients of the vector state x(t) with

MBADC for case 1.

Figure 2: The transients of the vector state x(t) with

MBADC for case 2.

Figure 3: The transients of the vector state x(t) with the

backstepping algorithm for case 1.

Figure 4: The transients of the vector state x(t) with the

backstepping algorithm for case 2.

The analysis of simulation results shows that the

proposed MBADC guaranties the fulfillment of goal

(2). The backstepping algorithm is stable if all

functions in (24) are known, but the control system

is sensitive to parametric uncertainty and

external disturbances.

Figure 5: The transients of the vector state x(t) with the

auxiliary loop algorithm for case 1.

Figure 6: The transients of the vector state x(t) with the

auxiliary loop algorithm for case 2.

The auxiliary loop algorithm may be unstable

even we known all functions in the plant model.

We also can note that the proposed algorithm

(25)-(27) compensates parametric uncertainties and

external disturbances with the required accuracy



= 0.04 achieved after 1 s for any uncertainties from

the set . Additional investigation under saturated

control input is shown that the proposed algorithm is

stable while algorithms (Khalil, 2002; Tsykunov,

2007) lose stability. These results are similar for

multi-agent systems.

5 CONCLUSIONS

The paper describes the robust algorithm for

compensation of mismatched disturbances with

distributed time-delay. The synthesis of control

system based on the backstepping algorithm and the

auxiliary loop algorithm. The proposed algorithm

guarantees stabilization of the plant state vector with

the required accuracy. We also compare the

proposed algorithm with the backstepping algorithm

and auxiliary loop algorithm. The simulation results

illustrate the efficiency and robustness of the

suggested control system.

st,

Compensation of Mismatched Disturbances for Nonlinear Plants with Distributed Time-delay

273

ACKNOWLEDGEMENTS

Research in Sections 1-3 and Appendix supported by

Russian Science Foundation (project no. 18-79-

10104) in IPME RAS. The reported study under

saturated control input in Section 4 was funded by

RFBR according to the research project № 17-08-

01266.

REFERENCES

Bobtsov A., Kremlev A.S., 2005. Observer synthesis in

the compensation problem for a finite-demensional

quasi-harmoniv disturbance. J. Computer and Systems

Sciences International, vol. 44, no. 3, pp. 331-337.

Chang Y.N. Cheng C.C., 2010. Block backstepping

control of multi-input nonlinear systems with

mismatched perturbations for asymptotic stability.

International Journal of Control, vol. 83, no. 10, pp.

2028-2039.

Fradkov A.L., Miroshnik I.V., Nikiforov V.O., 1999.

Nonlinear and Adaptive Control of Complex Systems.

Dordrecht: Kluwer.

Furtat I., Fradkov A., Tsykunov A., 2014. Robust

synchronization of linear dynamical networks with

compensation of disturbances. International Journal

of Robust and Nonlinear Control, vol. 24, no. 17, pp.

2774-2784.

Furtat I.B., Gushchin P.A, 2019. A Control Algorithm for

an Object with Delayed Input Signal Based on

Subpredictors of the Controlled Variable and

Disturbance. Automation and Remote Control, vol. 80,

no. 2, pp. 201-216.

Furtat I., Gushchin P., 2019. Tracking control algorithms

for plants with input time-delays based on state and

disturbance predictors and sub-predictors. Journal of

the Franklin Institute, vol. 356, pp. 4496-4512.

Khalil H.K., 2002. Nonlinear Systems. NJ: Prentice Hall.

Kokotovic P.V., 1992. The joy of feedback: nonlinear and

adaptive. IEEE Control Systems Magazine, vol. 12,

no. 3, pp. 7-17.

Ma L., Schilling K., Schmid C., 2005. Adaptive

backstepping sliding mode control with Gaussian

networks for a class of nonlinear systems with

mismatched uncertainties. 44th IEEE Conference on

Decision and Control & European Control

Conference, Seville, Spain, pp. 5504-5509.

Tsykunov A.M., 2007. “Robust control algorithms with

compensation of bounded perturbations,” Automation

and Remote Control, vol. 71, no.7, pp. 1213-1224.

Xu Z.B.,Min J.Q., 2010. Fuzzy Backstepping Control for

Strict-Feedback Nonlinear Systems with Mismatched

Uncertainties. 8th World Congress on Intelligent

Control and Automation (WCICA), Jinan, pp. 5054-

505.

APPENDIX

Lemma (Furtat, 2014; Furtat and Gushchin,

2019). Let the system be described by the following

differential equation

),,,(

21

txfx







, (32)

where

1

s

Rx

,

2

),(col

21

s

R



, f(x, µ

1

, µ

2

, t)

is Lipchitz continuous function in x. Let (34) have a

bounded closed set of attraction  = {x | P(x) ≤ C}

for µ

2

= 0, where P(x) is piecewise-smooth, positive

definite function in

1

s

R

. In addition let there exist

some numbers C

1

> 0 and

0

1





such that the

following condition holds

.)(),0,,(,

)(

sup

11

T

11

CCxPtxf

x

xP





































Then there exists µ

0

> 0 such that the system (32)

has the same set of attraction  for µ

2

≤ µ

0.

Proof of Theorem. Taking into account (30),

rewrite the equations for the error estimates

)(

ˆ

)()( ttt

iii







, i = 1, 2, ..., n as follows

)()()(

1

ttt

iii











, i = 1, 2, ..., n. (33)

Rewrite (8), (15), (22) and (32) as the following

system

,...,,2,1),()()(

,1...,,2,1),()()(

),()()(

21

11

1111

nittt

njttecte

ttxctx

iii

jjjj

















(34)

where µ

1

= µ

2

= µ. To analyze system (34) the

following Lemma is needed.

Let us check conditions of Lemma. Consider

system (34) for µ

2

=0. Let P(x) = V(t), where V(t) is

Lyapunov function defined in the form











n

i

n

j

i

ttetxtV

1

2

1

22

1

)(5.0)(5.0)(5.0)(



. (35)

Take the derivative of V(t) along the trajectories

(34), we get

 

.)()()()(

)()()()(

1

21

1

2

1

11

2

11















n

i

n

j

jjjj

tttetec

ttxtxctV







(36)

Find upper bounds for the fourth term of (36):

.1...,,2,1,5.05.0

2

10

21

01









njee

jjjj



(37)

Substituting (37) to (36), we get

ICINCO 2019 - 16th International Conference on Informatics in Control, Automation and Robotics

274

,

ˆ

2

22

1

2

1

2

11













n

i

ii

n

j

jj

decxcV





(38)

where

1

011

5.0

ˆ









jj

cc

and

0

1

5.0

ˆ







i

d

.

Obviously, there exist coefficients c

j + 1

,

j = 1, 2, ..., n-1, µ

1

, and µ

0

such that

0

ˆ

1



j

c

,

0

ˆ



i

d

and system (34) is asymptotically stable.

Taking into account to (35), rewrite (38) as

follows

),()( tVtV







(39)

where

 

nn

ddccc

ˆ

...,,

ˆ

,,

ˆ

...,,

ˆ

,min2

2

1

121







.

Solving inequality (46) with respect to V(t), we

get

t

eVtV





 )0()(

. (40)

From (40) it follows that solutions of system (33)

are exponentially tend to zero.

Proof boundendess of all signals in the closed-

loop system.

Taking into account (23), rewrite the first

equation of (4) in the following form

).(

)1)((

)(

1

2

1

11

1

tx

p

pcp

t









Since the function x

1

(t) is asymptotically stable

than the functions



1

(t),

)(

1

t





,

)(

1

t





and







0

2

1

)(

i

h

dtx



, i = 1, 2, ..., n are bounded. From

boundedness of



1

(t) it follows that the signal

)(

ˆ

1

t



is bounded. Taking into account (23) and system

(34), the proof of boundedness of the signals



i

(t),

)(t

i





,

)(t

i





and

)(

ˆ

t

i



, i = 2, 3, ..., n is same.

Therefore, from (7), (14) and (21) the signals v

i

(t),

i = 1, 2, ..., n – 1 and u(t) are bounded. Hence, the

function x(t) is bounded. From (3), (10) and (17) it

follows that the functions z

i

(t), i = 1, 2, ..., n are

bounded. Therefore, the functions



i

and

i



~

are

bounded. Consequently, all signals in the closed-

loop system are bounded.

According to Lemma there exist



0

> 0 such that

for



1

≤



0

and



2

≤



0

the attraction set is the same

as for



2

= 0. However, system (34) is not

asymptotically stable for



2

 0. It will be has some

attraction set. Let us find the set of attraction of

system (34) for



2

 0. Taking into account result

(38), take derivative in time of (35) along

trajectories (33) for



1

=



2

=



0

,

~

ˆ

12

22

1

0

1

2

1

2

11













n

l

ll

n

i

ii

n

j

jj

decxcV







(41)

where

.5.0

ˆ

0

1

0







i

d

Use the following upper bounds:

,)(5.05.0)(5.0

0

21

0

2

0

21

0







tt

lllll



(42)

where

 

2

...,2,1, ,

sup5.0

l

nlt







.

Taking into account (42), rewrite (41) in the

form

,5.0

ˆ

0

2

22

1

0

1

2

1

2

11



ndecxcV

n

i

n

j

jj















(43)

where

0

1

0







d

Taking into account (35), rewrite (43) as follows



0

)()( ntVtV 



, (44)

where

 

dccc

n

,5.0,

ˆ

...,,

ˆ

,min2

1

021







.

Solving inequality (44) with respect to V(t), we

get

 

.1)0()(

0

1





neVetV

tt 



(45)

From (45) we can note that goal (2) holds. The

theorem is proved.

Compensation of Mismatched Disturbances for Nonlinear Plants with Distributed Time-delay

275