ON THE METHOD OF CONTROLLING OBJECTS WHOSE MOTION IS DESCRIBED BY A SYSTEM OF LINEAR DIFFERENTIAL-DIFFERENCE EQUATIONS

Volume 04 Issue 11-2024

101

American Journal Of Applied Science And Technology
(ISSN

–

2771-2745)

VOLUME

04

ISSUE

11

Pages:

101-105

OCLC

–

1121105677

Publisher:

Oscar Publishing Services

Servi

ABSTRACT

This article explores the methods of controlling objects whose motion is described by a system of linear differential-
difference equations. It provides an analysis that serves as a basis for developing an approach to eliminate existing
shortcomings.

KEYWORDS

Control function parameters, optimal solution, kinematic chain, system of differential-difference equations.

INTRODUCTION

The shortcomings of controllability in linear stationary

systems are described in [1], and these issues are also

relevant for systems of differential-difference

equations. The primary criterion for checking the full

controllability of such systems is Kalman's criterion,

which applies universally to controllable systems.

The general form of a system of linear differential-
difference equations is as follows::

( )

(

)

( )

( )

( )

x t

Ax t

h

Bu t

y t

Hx t

=

−

+





=



(1)

where:

( )

x

x t

n

=

− −

a vector representing the state of the system at time

t

;

Research Article

ON THE METHOD OF CONTROLLING OBJECTS WHOSE MOTION IS
DESCRIBED BY A SYSTEM OF LINEAR DIFFERENTIAL-DIFFERENCE
EQUATIONS

Submission Date:

November 20, 2024,

Accepted Date:

November 25, 2024,

Published Date:

November 30, 2024

Crossref doi:

https://doi.org/10.37547/ajast/Volume04Issue11-15

Dilshod Davronovich Aroev

PhD, Associate Professor, Kokand State Pedagogical Institute, Uzbekistan
Orchid: - https://orcid.org/0009-0004-0392-7597

Journal

Website:

https://theusajournals.
com/index.php/ajast

Copyright:

Original

content from this work
may be used under the
terms of the creative
commons

attributes

4.0 licence.

Volume 04 Issue 11-2024

102

American Journal Of Applied Science And Technology
(ISSN

–

2771-2745)

VOLUME

04

ISSUE

11

Pages:

101-105

OCLC

–

1121105677

Publisher:

Oscar Publishing Services

Servi

A

−

constant matrices of specific dimensions;

(

)

n n

 −

ўлчовли ўзгармас матрица;

(

)

B

n m

− 

−

A constant matrix with non-zero elements;;

h

−

an infinitesimally small quantity;;

( )

(1

)

u t

m

− 

−

a control function vector;

0

0,

h

t

t

T



 

;

( )

y t

n

− −

a vector of specific dimensions depending on the state vector

(1

)

n

− 

;

(

)

H

r n

−  −

A constant matrix of specified dimensions.

The first equation in (1) represents the differential-
difference equation, while the second equation
describes the phase state of the first one.

Main Section.

Objects whose motion is described by a

system

of

differential-difference

equations,

particularly for industrial robots, have the following
advantages and disadvantages for the system in (1):

1.

Motion system:

Deterministic.

2.

Control system:

Deterministic.

3.

Form of the motion model:

Linear

differential-difference

equation-

( )

(

)

( )

x t

Ax t

h

Bu t

=

− +

.

4.

Advantage of the model:

The form of the

model is simple for systematic analysis and
convenient for verifying full controllability
using Kalman's criterion.

5.

Disadvantage of the model:

It is known that if

2

1

[ ,

,

,...,

]

n

rank B AB A B

A

B

n

−

=

the system (1) is fully controllable according to
Kalman's criterion. In the system of equations (1), the

matrix

B

has dimensions of

(

)

n m

− 

, particularly

for the motion of industrial robots,

m n

=

.

Thus, the matrix,

B

(

)

n n

 −

is extended to the

required dimensions. The dimension of the
controllable subspace of the system (1) becomes equal
to

𝑛

n. As a result, the obtained system satisfies the

property of full controllability in

n

R

-dimensional space

but does not satisfy the property of observability. To
ensure the property of full controllability, the system
(1) is considered as two autonomous systems as
follows [2]:

1

1

1

11 1

11 1

1

1

2

22

2

1

1

1 1

2

2

( )

(

)

( )

( )

(

)

( )

( )

( )

x t

A x t

h

B u t

x t

A x t

h

y t

H x t

H x t



=

−

+



=

−





=

+



(2)

The second part of the system (2) is discarded because
it does not satisfy the property of observability. In
practice, particularly in the complex phase motion of

industrial robots, the second part of system (2)
complements the properties of the first part [1].

Volume 04 Issue 11-2024

103

American Journal Of Applied Science And Technology
(ISSN

–

2771-2745)

VOLUME

04

ISSUE

11

Pages:

101-105

OCLC

–

1121105677

Publisher:

Oscar Publishing Services

Servi

From this, it becomes evident that additional scientific
research is required to develop control methods for
linear differential-difference systems.

For linear differential-difference systems, the following
problem is posed:

Is it possible to ensure full controllability of the system
(1) by optimizing the number of parameters of the
control function during its management?

The problem was posed in a similar form for
autonomous control systems in [1]. However, although
the system was given in an autonomous linear form,
the problem concerning the differential-difference
nature of the system was not resolved., pecifically, in
mathematical

terms

1

:

(

n

k

n

f R

R

R

R

f





→

−

−

continuous

function) does there exist a control function

( )

k

n

v t

R

R





−

?

The problem condition is defined as follows:

The system is in the form of a linear differential-
difference equation.

The system is finite-dimensional.

For robotic systems, the problem is posed as follows:

It is known that the stages of industrial robot motion
can be divided into three phases: strategic, tactical,
and execution. In the strategic phase, design issues are
addressed; in the tactical phase, modeling and
planning are carried out; and in the execution phase,
control issues are solved. This is schematically
represented as shown in Figure 1:

In this case, MADS

–

the methods of automated design

systems

; М

M- methods of modeling; MP- Methods of

planning.; MC- Methods of control.

Figure 1. Control diagram of an industrial robot

.

Volume 04 Issue 11-2024

104

American Journal Of Applied Science And Technology
(ISSN

–

2771-2745)

VOLUME

04

ISSUE

11

Pages:

101-105

OCLC

–

1121105677

Publisher:

Oscar Publishing Services

Servi

CONCLUSION

The issues of designing, modeling, and controlling

industrial robot motion have been thoroughly studied,

investigated, and the necessary results have been

obtained. An analysis of the literature on the research

topic revealed the following shortcomings and gaps

related to industrial robot motion modeling and

control:

It is known that the dynamic motion of an industrial

robot is expressed using Lagrange's second law,

Newton-Euler, D'Alembert, Gauss, Appel, and Kane

equations, and there are several methods for solving

these equations [3, 4]. When solving these equations,

the number of equations increases twofold in relation

to the number of unknowns [4]. This indicates that in

the case of the robot's complex phase motion, the

optimal trajectory is not unique. The decision-maker is

unable to reach a consensus in choosing the

appropriate trajectory. As a result, the process stops

due to the collision of the industrial robot with objects

in the external environment [5]. The SR (robot arm)

changes the structure of the working hand. Such cases

lead to excessive dependencies in the kinematic chain

of the industrial robot, which requires the acceptance

of alternative solutions and further research [1].

2. For the optimal control of an industrial robot, errors

in calculating the coefficients of the system of

equations representing its motion in trapezoidal form,

as well as obstacles in communication channels, can

lead to delays in the movement of the robot's links and

an increase in the overall time required for

technological operations. Furthermore, this can cause

a decrease in the stability of the robot's motion and

deteriorate its performance.

From these shortcomings in the mathematical models

of the industrial robot's motion and their solving

methods, it is evident that the correct specification of

robot motion and the execution of complex phase

operations,

based

on

technical

and

design

characteristics, require the development of an optimal

solution. Effective use of control function parameters

in selecting the appropriate solution enhances the

robot's operational efficiency. This, in turn, highlights

the necessity to improve the methods of modeling and

controlling industrial robot motion.

REFERENCES

1.

Onorboev B.O., Abdullaev A.Q., Siddiqov R.Y.

"Issues of improving positional accuracy and

sensitivity in the control of robotic systems" //

Current state and development trends of

information technologies

—

Republic Scientific

and Technical Conference, Tashkent, September

23-25, 2008, pp. 209-212.

2.

Li E.B., Markus L.M. Fundamentals of Optimal

Control Theory

—

Moscow: Nauka Publishing,

1972.

—

p. 576.

Volume 04 Issue 11-2024

105

American Journal Of Applied Science And Technology
(ISSN

–

2771-2745)

VOLUME

04

ISSUE

11

Pages:

101-105

OCLC

–

1121105677

Publisher:

Oscar Publishing Services

Servi

3.

Belousov I.R. Formation of robot manipulator

dynamics equations. Preprint. IPM M.V. Keldysh

RAN, 2002.

—

36 p.

4.

Fu K., Gonzalez R., Lee K. Robotics

—

Moscow: Mir

Publishing, 1989.

—

p. 624.

5.

Khonboboev Kh.I., Siddiqov R.Y., Aroev D.D. On

industrial robots in unknown environments //

Uzbek Journal of Informatics and Energy Problems

—

Tashkent, 2011, No. 2, pp. 31-34.