In this research two-dimensional dynamical system was taken. The system was analyzed through its fixed points, stability analysis, chaos diagnoses and adaptive control technique. It was found that the system had a hidden attractor and unstable fixed points. The largest value of Lyapunov exponent equals 1.853981 and from binary test we get: k = 0.9305, which indicates that the system is chaotic. Adaptive control technique was performed, and it was found that the system is stable and regular after control.
In recent years, we have seen that there is great interest in the subject of hidden and self-Excited attractors, the attractors in chaotic dynamical systems are classified into two categories: dynamical systems with self-Excited attractors and dynamical systems with hidden attractors, as it is said for the systems whose basin of attraction intersects with the neighborhood. The Lorenz system [
Models in dynamical systems have hidden attractors for many applications, especially in the field of engineering designs, because they do not allow for unforeseen accidents [
Two-dimensional discrete time dynamical system, suggested by Panahi [
F = { x t + 1 = x t + y t y t + 1 = 0.1 x t 2 + 0.1 + y t ( − x t − b y t ) + y t (1)
b = 2 (2)
where x t , y t represent variables system and b represent parameter system.
In this section analysis the system was done by means of its fixed points. Let us assume that:-
f 1 ( x t , y t ) = x t f 2 ( x t , y t ) = y t
To find the fixed points of system (1), suppose that:
y t = 0 (3)
0.1 x t 2 + 0.1 + y t ( − x t − b y t ) + y t = y t (4)
By solving Equations (3) and (4), we obtain the following points:-
p 0 = ( i , 0 ) , p 1 = ( − i , 0 )
Since the obtained fixed points are nodal points, we can say that the dynamical system (1) have hidden attractors.
The Jacobian matrix of system (1) obtained as:
J ( x t , y t ) = [ 1 1 0.2 x t − y t − x t − 2 b y t + 1 ] (5)
Proposition (1):- Let
L ( λ ) = a 2 λ 2 + a 1 λ + a 0 = 0 (6)
A characteristic Equation of (5) and | λ i | , i = 1 , 2 are values of the roots of Equation (6), then the following cases are true:
1) If | λ i | < 1 , then the fixed point of system (1) is locally asymptotically stable and is called the sink.
2) If | λ i | > 1 , then the fixed point of system (1) is unstable and is usually called source, but if at least one of the values of the roots of Equation (6) is greater than one, then the fixed point is called Saddle.
3) If | λ i | = 1 , then the fixed point of system (1) is called Non-Hyperbolic point, but if | λ i | ≠ 1 , then the fixed point is called Hyperbolic point.
Proposition (2):-
From the Equation (6), then the jury
Such that
b k = | a 0 a n − k a n a k | , k = 0 , 1 , n = 2 , c k = | b 0 b n − 1 − k b n − 1 b k | , k = 0 , n = 2
Then the fixed point of system (1) is called stable if the satisfies following conditions:
L ( 1 ) > 0 , ( − 1 ) n L ( − 1 ) > 0 , | a 0 | < a n , | b 0 | > | b n − 1 | , | c 0 | > | c n − 2 | ,
where L is the characteristic equation. Otherwise, the fixed point is called unstable.
In this section the stability analysis of the fixed points of the system (1) is analyzed.
| λ2 | λ1 | λ0 |
|---|---|---|
| a2 | a1 | a0 |
| a0 | a1 | a2 |
| b1 | b0 | |
| b0 | b1 | |
| c0 |
We will test the stability of the fixed points of system (1) by using the test of roots characteristic equation. To test the stability of the fixed point p 0 , we substitute the point p 0 = ( i , 0 ) in Equation (5), we obtain:-
J ( i , 0 ) = [ 1 1 0.2 i − i + 1 ]
Finding the determinant ( Det ( λ I − J ) = 0 ), we get:-
| [ λ 0 0 λ ] − [ 1 1 0.2 i − i + 1 ] | = 0
⇒ λ 2 + ( − 2 + i ) λ + ( 1 − 1.2 i ) = 0 (7)
By analyzing Equation (7), we get:-
λ 1 = 1 , λ 2 = 1
From the Proposition (1) we obtain the following values:-
| λ 1 | = 1 , | λ 2 | = 1
Then the fixed point p 0 = ( i , 0 ) is a non-hyperbolic point, and in the same way point p 1 = ( − i , 0 ) was tested, and its results are shown in
Note (1)
In this system, we did not use Jury test to study the stability of fixed points of the system, since Jury test depends on the coefficients Equation (7) which represent complex values.
After studying the theoretical side of the system, we will discuss the practical side of the system, and at the beginning we will use Newton Raphson’s numerical method, Newton Raphson’s numerical method was used to generate the best values for the system (1) with the least possible error, as the system parameter was fixed at the value b = 2, the following values were obtained: ( x , y ) = ( 1.8 , − 0.39 ) and an error of (0.0001). Time behavior of system (1) was studied by generating a time series of system states with time (t = 100), shown in
| Status | Results of the roots of the characteristic equations of points | Fixed points |
|---|---|---|
| Non-hyperbolic | λ 1 = 1 , λ 2 = 1 | p 0 = ( i , 0 ) |
| Non-hyperbolic | λ 1 = 1 , λ 2 = 1 | p 1 = ( − i , 0 ) |
of the bifurcation parameter of the system (1) were found, the parameter b was fixed at the interval ranging from 1.975 to 2, shown in
To study the chaotic behavior of system (1) we will use Lyapunov exponent test, and after applying and calculating Lyapunov exponent of system (1) the following values were obtained:-
L 1 = − 0.250000 , L 2 = 1.853981
And since one of the values of Lyapunov exponent is a positive value, this indicates that system (1) is a chaotic system, and
To find Lyapunov dimension, we use the following formula:
p + L 1 | L 2 | = 1 + − 0.250000 | 1.853981 | = 1 − 0.134844 = 0.865156 = D L
To study and define the mess more broadly, binary test (0 - 1) was used to determine the chaos of system (1), and by using a mathematical program in MATLAB, the system binary test was applied as a time series of system states and (1000) were generated from the iterations with a fixed value Parameter b = 2 and ( x , y ) = ( 1.8 , − 0.39 ) , and q c ( t ) was calculated against p c ( t ) and shown
in
To address the chaos of system (1) we will use the adaptive control technique and design an adaptive control law with the unknown parameter b of the system.
By adding the control units to the system, we get:-
{ x t + 1 = x t + y t + u 1 y t + 1 = 0.1 x t 2 + 0.1 + y t ( − x t − b y t ) + y t + u 2 (8)
where u 1 , u 2 are the controllers for the adaptive feeding, defined as follows:-
{ u 1 = − x t − y t − M 1 x t u 2 = − 0.1 x t 2 − 0.1 + x t y t + β y t 2 − y t − M 1 y t (9)
where β is an approximate parameter of b and M 1 , M 2 are positive constants by substituting (9) in (8) we get:
{ x t + 1 = − M 1 x t y t + 1 = ( − b + β ) y t 2 − M 2 y t (10)
Let the error for the discretionary parameter as follows:
e b = − b + β (11)
By substituting (11) into (10):
{ x t + 1 = − M 1 x t y t + 1 = e b y t 2 − M 2 y t (12)
In this section we will stability test of fixed points p 0 , p 1 for system (1) in system (10), where M 1 = 0.7 , M 2 = 0.5 and parameter β is an estimated parameter of b which is estimated at = 2.1.
To study the stability of fixed points in System (1), using the characteristic equation root test, we will find the Jacobian Matrix of System (10) as follows:
J ( x t , y t ) = [ − M 1 0 0 2 ( − b + β ) y t − M 2 ] (13)
Substituting fixed point p 0 = ( i , 0 ) and the values of M 1 , M 2 , into Equation (13) we get:-
J ( 0 , 0 ) = [ − 0.7 0 0 − 0.5 ]
Finding the determinant ( Det ( λ I − J ) = 0 ) we obtain the following equation:-
λ 2 + 1.2 λ + 0.35 = 0 (14)
By analyzing the quadratic Equation (14), and Proposition (1) we get:-
| λ 1 | = 0.5 , | λ 2 | = 0.7
Therefore, the point p0 is stable. Since point p1 is symmetric to point p0, it has the same results, that is, it is also a stable point, which leads to the system (9) being a stable system.
After the adaptive control technique of system was carried out and the characteristic equation roots were tested for the points in the controlled system (10), distinct equations were obtained with the values of their real coefficients, and thus it became possible for us to use a jury test to study the stability of fixed points in system (10). The coefficients of characteristic Equation (14) are:
a 0 = 0.35 , a 1 = 1.2 , a 2 = 1
Accordingly, we form the Jury test
Since all of the conditions for Jury test for point p0 are satisfies Proposition (2), then point p0 is stable, and point p1 is stable too, which leads to the system (10) is stable.
In this section we will use Lyapunov exponent test to study the chaotic behavior of
| λ0 | λ1 | λ2 |
|---|---|---|
| 0.35 | 1.2 | 1 |
| 1 | 1.2 | 0.35 |
| −0.8775 | −0.78 | |
| −0.78 | −0.8775 | |
| 0.1616 |
system (10), and by using a written program in MATLAB, we obtained:-
L 1 = − 0.700000 , L 2 = − 0.418868
And since all the obtained values are negative values, this means that system (10) is a regular system as shown in
In this paper, the stability and chaos of a two-dimensional discrete time dynamical system with hidden attractors was studied, and the fixed points were found: p 0 = ( i , 0 ) , p 1 = ( − i , 0 ) which shows us that the points are complex. The stability analysis of fixed points was analyzed by using the characteristic equation roots test, which shows us that the points are non-hyperbolic points, so we could not use jury test for the stability, the dynamic behavior of system was analyzed and a time series was generated for each state of system and phase space and bifurcation diagrams of the system were found. Chaos diagnosis in the system by using Lyapunov exponent test and it was obtained: L 1 = − 0.250000 , L 2 = 1.853981 . Lyapunov dimension: D L = 0.865156 , and from the binary test (0 - 1) we get the index value k = 0.9305, which is close to one, all show that the system (1) is chaotic. The adaptive control technique of the chaotic system was carried out. Stability tests: roots of the characteristic equation and jury test for points in the controlling system (10), and Lyapunov exponent test obtaining the values: L 1 = − 0.700000 , L 2 = − 0.41886 , which all show that the system after control is stable and regular.
The authors acknowledge the support university of Mosul and college of computer science and mathematics.
The authors declare no conflicts of interest regarding the publication of this paper.
Aziz, M.M. and Jihad, O.M. (2021) Stability & Chaos Tests of 2D Discrete Time Dynamical System with Hidden Attractors. Open Access Library Journal, 8: e7501. https://doi.org/10.4236/oalib.1107501