The local dynamical behaviors of a four-dimensional hyperchaotic Lorenz system, including stability and bifurcations, are investigated in this paper by analytical and numerical methods. The equilibriums and their stability under different parameter conditions are analyzed by applying Routh-Hurwitz criterion. The results indicate that the system may exist one, three and five equilibrium points for different system parameters. Based on the central manifold theorem and normal form theorem, the pitchfork bifurcation and Hopf bifurcation are studied respectively. By using the Hopf bifurcation theorem and calculating the first Lyapunov coefficient, the Hopf bifurcation of this system is obtained as supercritical for certain parameters. Finally, the results of theoretical parts are verified by some numerical simulations.
In 1963, Lorenz, an American meteorologist, discovered the first chaotic attractor while studying the atmospheric motion, which started the study of chaos. The Lorenz model also has become a classical model in the field of chaos.
Based on Lorenz system, many scholars proposed Lorenz-like systems, which are widely used in image encryption, secure communication and many other fields. Perevoznikov et al. [
The bifurcation problem also has a profound application background. Zhang et al. [
The following manuscript is organized as follows: a four-dimensional hyperchaotic Lorenz system is presented in the next section. In Section 3, the equilibrium points and their stability are studied. The pitchfork bifurcation and Hopf bifurcation are analyzed in Section 4. In the last section, numerical simulations are presented to verify the theoretical results.
Wang et al. [
{ x ˙ = a ( y − x ) + w y ˙ = b x − y − x z z ˙ = x y − c z w ˙ = − y z + d w (1)
Where [ x , y , z , w ] T are the state variables, a , b , c , d are controllable parameters. When a = 10 , b = 28 , c = 8 3 , − 1.52 ≤ d ≤ − 0.06 , the system is in a hyperchaotic state [
In this section, the stability of the equilibrium points of this system will be analyzed.
Theorem 1. Let b ≠ 0 , c ≠ 0 , Δ = b 2 c 2 ( b 2 + a 2 c 2 d 2 + 2 a b c 2 d − 4 a c 2 d ) , t 1 = ( − 2 a c d + a b c d + b 2 c ) + Δ 2 a d , t 2 = ( − 2 a c d + a b c d + b 2 c ) − Δ 2 a d , the system has only one equilibrium point S 0 = ( 0,0,0,0 ) as long as it meets any of the following conditions: 1) Δ < 0 i.e. b 2 + a 2 c 2 d 2 + 2 a b c 2 d − 4 a c 2 d < 0 ; 2) Δ = 0 and also − 2 a c d + a b c d + b 2 c 2 a d < 0 ; 3) Δ > 0 and also t 1 , t 2 < 0 . And the system has three equilibrium points as long as it meets any of the following conditions: 1) Δ = 0 ; 2) Δ > 0 and also t 1 > 0 , t 2 < 0 ; 3) Δ > 0 and also t 1 < 0 , t 2 > 0 . The system has five equilibrium points as long as it meets the condition: both Δ > 0 and t 1 > 0 , t 2 > 0 .
Proof 1. Solving the equations to find the equilibrium points of system (1):
{ a ( y − x ) + w = 0 b x − y − x z = 0 x y − c z = 0 − y z + d w = 0 (2)
when x = 0 , it’s easy to obtain the equilibrium point S 0 = ( 0,0,0,0 ) ; and when x ≠ 0 ,we have
a d ( x 2 + c ) 2 − b 2 c x 2 − a b c d ( x 2 + c ) = 0 (3)
let t 1 = ( − 2 a c d + a b c d + b 2 c ) + Δ 2 a d , t 2 = ( − 2 a c d + a b c d + b 2 c ) − Δ 2 a d , where Δ = b 2 c 2 ( b 2 + a 2 c 2 d 2 + 2 a b c 2 d − 4 a c 2 d ) .
When Δ < 0 the system has only one equilibrium point S0.
When Δ = 0 and also − 2 a c d + a b c d + b 2 c 2 a d < 0 , the system has equilibrium point S0. And when Δ = 0 and the − 2 a c d + a b c d + b 2 c 2 a d > 0 , the system has three equilibrium points as following: S0; S 1 = ( x 1 , b c x 1 x 1 2 + c , b x 1 2 x 1 2 + c , a x 1 − a b c x 1 x 1 2 + c ) ; S 2 = ( x 2 , b c x 2 x 2 2 + c , b x 2 2 x 2 2 + c , a x 2 − a b c x 2 x 2 2 + c ) . Where x 1 = − 2 a c d + a b c d + b 2 c 2 a d , x 2 = − − 2 a c d + a b c d + b 2 c 2 a d .
When Δ > 0 , t 1 > 0 , t 2 < 0 or Δ > 0 , t 1 < 0 , t 2 > 0 , the system has three equilibrium points. The equilibrium points in the former case are S 0 ; M 1 = ( m 1 , b c m 1 m 1 2 + c , b m 1 2 m 1 2 + c , a m 1 − a b c m 1 m 1 2 + c ) , m 1 = t 1 ; M 2 = ( m 2 , b c m 2 m 2 2 + c , b m 2 2 m 2 2 + c , a m 2 − a b c m 2 m 2 2 + c ) , m 2 = − t 1 respectively. And the equilibrium points in the other case are S0; N 1 = ( n 1 , b c n 1 n 1 2 + c , b n 1 2 n 1 2 + c , a n 1 − a b c n 1 n 1 2 + c ) , n 1 = t 2 ; N 2 = ( n 2 , b c n 2 n 2 2 + c , b n 2 2 n 2 2 + c , a n 2 − a b c n 2 n 2 2 + c ) , n 2 = − t 2 respectively.
When Δ > 0 , t 1 > 0 , t 2 > 0 , the system has five equilibrium points. The equilibrium points are S0, M1, M2, N1, N2. Therefore, Theorem 1 is proved.
Then the stability will be discussed. Choosing case Δ > 0 , t 1 > 0 , t 2 > 0 as an example and the analysis process for other situations are similar. Based on Theorem 1, the system has equilibrium points S0, M1, M2, N1, N2 when Δ > 0 , t 1 > 0 , t 2 > 0 . Since the system has symmetry, the stability of M2, N2 are same as the M1, N1. The Routh-Hurwitz criterion is applied to analyze stability of S0, M1, N1, and the following theorems are obtained.
Theorem 2. When ( a + 1 ) 2 − 4 ( a − a b ) < 0 , c > 0 , d < 0 , a > − 1 ; or ( a + 1 ) 2 − 4 ( a − a b ) ≥ 0 and c > 0 , d < 0 , − ( a + 1 ) ± ( a + 1 ) 2 − 4 ( a − a b ) 2 < 0 the equilibrium point S 0 = ( 0,0,0,0 ) is asymptotic stable.
Proof 2. The Jacobian matrix of system (1) at S0 is as following:
J S 0 = ( − a a 0 1 b − 1 0 0 0 0 − c 0 0 0 0 d )
It’s characteristic polynomial is P 1 ( λ ) = ( λ + c ) ( λ − d ) [ λ 2 + ( a + 1 ) λ + ( a − a b ) ] = 0 . And characteristic roots are λ 1 = − c , λ 2 = d , λ 3 , 4 = − ( a + 1 ) ± ( a + 1 ) 2 − 4 ( a − a b ) 2 .
All characteristic roots have negative real parts if these parameters satisfy ( a + 1 ) 2 − 4 ( a − a b ) < 0 , c > 0 , d < 0 , a > − 1 . Applying the Routh-Hurwitz criterion [
Theorem 3. When a 1 > 0 , a 1 a 2 − a 3 > 0 , a 1 a 2 a 3 − a 1 2 a 4 − a 3 2 > 0 , a 4 ( a 1 a 2 a 3 − a 1 2 a 4 − a 3 2 ) > 0 , the equilibrium point M 1 = ( m 1 , b c m 1 m 1 2 + c , b m 1 2 m 1 2 + c , a m 1 − a b c m 1 m 1 2 + c ) is asymptotically stable.
Proof 3. The Jacobian matrix of system (1) at M1 is as following:
J M 1 = ( − a a 0 1 b − b t 1 t 1 + c − 1 − t 1 0 b c t 1 t 1 + c t 1 − c 0 0 − b t 1 t 1 + c − b c t 1 t 1 + c d )
The characteristic polynomial of this matrix is
P 2 ( λ ) = λ 4 + a 1 λ 3 + a 2 λ 2 + a 3 λ + a 4
where
a 0 = 1 , a 1 = a + c − d + 1 , a 2 = a + c + a c + t 1 − a b c t 1 + c − a d − c d − d , a 3 = a c + a t 1 − a b c 2 t 1 + c + a b c t 1 t 1 + c − a d − c d − a c d − d t 1 + a b c d t 1 + c + b 2 c t 1 + b 2 c 2 t 1 ( t 1 + c ) 2 , a 4 = 3 b 2 c 2 t 1 − b 2 c t 1 2 ( t 1 + c ) 2 − a c d − a d t 1 + a b c 2 d − a b c d t 1 t 1 + c .
Calculating the following determinants: Δ 1 > 0 , Δ 2 > 0 , Δ 3 > 0 , Δ 4 > 0 . According to Routh-Hurwitz critetion, the equilibrium point M1 is asymptotically stable.
The analysis process of equilibrium N1 is the same as that of M1. Simply replace the value of t1 with t2 in the coordinate of equation M1, then the stability of point N1 can be obtained.
In this section, the pitchfork bifurcation of equilibrium point S0 is investigated. b is set to the bifurcation parameter, which leads to the following theorem.
Theorem 4. Assuming the parameters satisfy conditions that a ≠ − 1 , c ≠ 0 , d ≠ 0 , the pitchfork bifurcation occurs when the parameter b crosses the critical value b = 1 .
Proof 4. The Jacobian matrix of S0 is
J S 0 | b = 1 = ( − a a 0 1 1 − 1 0 0 0 0 − c 0 0 0 0 d )
It’s characteristic polynomial is P 3 ( λ ) = ( λ + c ) ( λ − d ) [ λ 2 + ( a + 1 ) λ ] = 0 and the characteristic roots are λ 1 = 0 , λ 2 = − ( a + 1 ) , λ 3 = − c , λ 4 = d , respectively. In other words, the system has one zero eigenvalue and the others with non-zero real parts. The corresponding eigenvectors of these four eigenvalues are calculated as follows:
ξ 1 = ( 1 1 0 0 ) , ξ 2 = ( − a 1 0 0 ) , ξ 3 = ( 0 0 1 0 ) , ξ 4 = ( d + 1 1 0 d 2 + d + a d )
Let
T = ( ξ 1 , ξ 2 , ξ 3 , ξ 4 ) = ( 1 − a 0 d + 1 1 1 0 1 0 0 1 0 0 0 0 d 2 + d + a d )
Using the following transformation
( x y z w ) = T ( x 1 x 2 x 3 x 4 )
Then system (1) becomes
( x ˙ 1 x ˙ 2 x ˙ 3 x ˙ 4 ) = ( 0 0 0 0 0 − ( a + 1 ) 0 0 0 0 − c 0 0 0 0 d ) ( x 1 x 2 x 3 x 4 ) + ( g 1 g 2 g 3 g 4 ) (4)
where
g 1 = 1 1 + a [ ( a 2 + a ) x 2 + ( a 2 + d ) x 4 ] + a 1 + a [ ( b − 1 ) x 1 − ( a b + 1 ) x 2 + ( b d + b − 1 ) x 4 − x 1 x 3 + a x 2 x 3 − ( d + 1 ) x 3 x 4 ] − a + d + 1 ( a + 1 ) ( d 2 + a d + d ) [ − x 1 x 3 − x 2 x 3 − x 3 x 4 + ( d 3 + a d 2 + d 2 ) x 4 ] ,
g 2 = − 1 1 + a [ ( a 2 + d ) x 4 ] + 1 1 + a [ ( b − 1 ) x 1 − ( a b + 1 ) x 2 + ( b d + b − 1 ) x 4 − x 1 x 3 + a x 2 x 3 − ( d + 1 ) x 3 x 4 ] + d ( a + 1 ) ( d 2 + a d + d ) [ − x 1 x 3 − x 2 x 3 − x 3 x 4 + ( d 3 + a d 2 + d 2 ) x 4 ] ,
g 3 = x 1 2 − a x 2 2 + ( d + 1 ) x 4 2 + ( 1 − a ) x 1 x 2 + ( d + 2 ) x 1 x 4 + ( d + 1 − a ) x 2 x 4 ,
g 4 = 1 d 2 + a d + d ( − x 1 x 3 − x 2 x 3 − x 3 x 4 ) .
Next, the central manifold theorem [
W c ( S 0 ) = { ( x 1 , x 2 , x 3 , x 4 , b ) ∈ ℝ 5 | x 2 = h 1 ( x 1 , b ) , x 3 = h 2 ( x 1 , b ) , x 4 = h 3 ( x 1 , b ) , | x 1 | < δ , | b | < δ ¯ , h i ( 0 , 0 ) = 0 , D h i ( 0 , 0 ) = 0 , i = 1 , 2 , 3 }
Suppose h 1 , h 2 , h 3 have expressions of the following forms:
x 2 = h 1 ( x 1 , b ) = a 1 x 1 + a 2 x 1 b + a 3 b + ⋯ (5)
x 3 = h 2 ( x 1 , b ) = b 1 x 1 2 + b 2 x 1 b + b 3 b 2 + ⋯ (6)
x 4 = h 3 ( x 1 , b ) = c 1 x 1 3 + c 2 x 1 2 b + c 3 x 1 b 2 + ⋯ (7)
According to the chain rule for derivatives, we have
D h g 1 = B h + g (8)
where
h = ( h 1 h 2 h 3 ) , g = ( g 2 g 3 g 4 ) , B = ( − ( a + 1 ) 0 0 0 − c 0 0 0 d )
Substituting Equations (4)-(6) to Equation (7), and comparing the coefficients of the corresponding terms with equal exponents, we can calculate the expressions of h i as follows:
x 2 = − 1 a 2 + a + 1 x 1 + ( a + 1 ) 2 ( a 2 + a + 1 ) 2 x 1 b + ⋯ (9)
x 3 = a + 1 a c − 2 a + c x 1 2 + ⋯ (10)
x 4 = ( a + 1 ) 2 ( d 2 + a d + d ) ( a c − 2 a + c ) ( 3 a + a d + d ) x 1 3 + ⋯ (11)
Finally, substituting expressions (8)-(10) to Equation (3), we can obtain the vector field of the system on the central manifold.
( x ˙ 1 = [ ( a 2 + d + a b d + a b − a 1 + a − ( a + d + 1 ) ( d 3 + a d 2 + d 3 ) ( a + 1 ) ( d 2 + a d + d ) ) c 1 + ( a + d + 1 ( a + 1 ) ( d 2 + a d + d ) − a 1 + a ) b 1 + ( a 2 1 + a + a + d + 1 ( a + 1 ) ( d 2 + a d + d ) ) a 1 b 1 ] x 1 3 + [ ( a 2 − a 2 b 1 + a ) a 1 + a b − a a + 1 ] x 1 + ( a 2 − a 2 b 1 + a ) a 2 x 1 b + ⋯ b ˙ = 0 (12)
a 1 = − 1 a 2 + a + 1 ; a 2 = ( a + 1 ) 2 ( a 2 + a + 1 ) 2 ; b 1 = 1 + a a c − 2 a + c ; c 1 = ( 1 + a ) 2 ( d 2 + a d + d ) ( a c − 2 a + c ) ( 3 a + a d + d ) .
The equilibrium point of this system in this expression is S p = ( 0,1 ) . To satisfy the condition that pitchfork bifurcation occurs, letting F ( x , b ) = x ˙ 1 , we calculate the value at b = 1 of the following equations:
F ( 0 , 0 ) = 0 , ∂ F ∂ x 1 | ( 0 , 1 ) = 0 , ∂ F ∂ b | ( 0 , 1 ) = 0 , ∂ 2 F ∂ x 1 2 | ( 0 , 1 ) = 0 ;
∂ 2 F ∂ x 1 ∂ b | ( 0 , 1 ) = − a 2 ( a 1 + a 2 ) 1 + a ≠ 0 ,
∂ 3 F ∂ x 1 3 | ( 0 , 1 ) = [ a 2 + d + a b d a + 1 − ( a + d + 1 ) ( d 3 + a d 2 + d 3 ) ( a + 1 ) ( d 2 + a d + d ) ] 6 c 1 + ( a + d + 1 ( a + 1 ) ( d 2 + a d + d ) − a 1 + a ) 6 b 1
+ ( a 2 1 + a + a + d + 1 ( a + 1 ) ( d 2 + a d + d ) ) 6 a 1 b 1 ≠ 0.
According to the pitchfork bifurcation theory [
This section focuses on Hopf bifurcation with a as the bifurcation parameter.
Theorem 5. Assume b > 1 , c > 0 , d < 0 , when the parameter a crosses the critical value −1, the Hopf bifurcation will occur at the point S0.
Proof 5. The characteristic polynomial of Jacobian matrix of the system at S0 is
P 4 ( λ ) = ( λ + c ) ( λ − d ) ( λ 2 + ( a + 1 ) λ + ( a − a b ) ) = 0.
when b > 1 , c > 0 , d < 0 , the eigenvalues are λ 1 = − c , λ 2 = d , λ 3,4 = ± b − 1 i . From calculating, we obtain d d a R e ( λ ( a ) ) | a = − 1 = − 1 2 ≠ 0 , which satisfy the two conditions for generating Hopf bifurcation. According to Hopf bifurcation theory the system generates Hopf bifurcation at S0.
Normal form theory [
A = [ 1 − 1 0 1 2 − 1 0 0 0 0 − 1 0 0 0 0 − 2 ]
The F ( x ) has Taylor expansion near the S0: F ( x ) = 1 2 B ( x , y ) + 1 6 C ( x , y , z ) + O ( ‖ X ‖ 4 ) where
B ( x , y ) = [ 0 − 2 x z 2 x y − 2 y z ] , C ( x , y , z ) = [ 0 0 0 0 ]
Letting q ∈ ℂ n is the complex eigenvector which is corresponding to the eigenvalue λ 3 = i , p ∈ ℂ n is adjoint eigenvector which meets A T p = − i p and the standardized condition 〈 p , q 〉 = 1 . From calculation we have the value of q and p:
q = ( 1,1 − i ,0,0 ) T , p = ( 1 2 + 1 2 i , − 1 2 i ,0, 1 10 + 3 10 i ) T (13)
The critical real eigenspace T c corresponds to λ 3 , λ 4 and T s u corresponds to λ 1 , λ 2 are both two-dimensional and is spanned by { R e q , I m q } . For any x ∈ ℝ n , x = z q + z q ¯ + y , where z ∈ ℂ 1 , z q + z ¯ q ¯ ∈ T c , y ∈ T s u . The complex variable z is the coordinate on T c , having
( z = 〈 p , x 〉 y = x − 〈 p , x 〉 q − 〈 p ¯ , x 〉 q ¯ (14)
Therefore, system (33) has the following form in the coordinate system (36):
( z ˙ = i z + 1 2 G 20 z 2 + G 11 z z ¯ + 1 2 G 02 z ¯ 2 + 1 2 G 21 z 2 z ¯ + z 〈 p , B ( q , y ) 〉 + z ¯ 〈 p , B ( q ¯ , y ) 〉 + ⋯ y ˙ = A y + 1 2 H 20 z 2 + H 11 z z ¯ + 1 2 H 02 z ¯ 2 + ⋯ (15)
where
G 20 = 〈 p , B ( q , q ) 〉 , G 11 = 〈 p , B ( q , q ¯ ) 〉 , G 02 = 〈 p , B ( q ¯ , q ¯ ) 〉
( H 20 = B ( q , q ) − 〈 p , B ( q , q ) 〉 q − 〈 p ¯ , B ( q , q ) 〉 q ¯ H 11 = B ( q , q ¯ ) − 〈 p , B ( q , q ¯ ) 〉 q − 〈 p ¯ , B ( q , q ¯ ) 〉 q ¯
The central manifold W c has an expression:
y = V ( z , z ¯ ) = 1 2 w 20 z 2 + w 11 z z ¯ + 1 2 w 02 z ¯ 2 + o | z | 3 .
We also have 〈 p , w i j 〉 = 0 , by combining the quadratic forms with respect to z and z ¯ in the invariance condition in W c , we can obtain y ˙ = V z z ˙ + V z ¯ z ¯ ˙ , w i j ∈ ℂ 4 satisfy the following system of linear equations
( ( 2 i ω 0 I n − A ) w 20 = H 20 − A w 11 = H 11 ( − 2 i ω 0 I n − A ) w 02 = H 02 (16)
According to all the above formulas, the following results can be obtained:
B ( q , q ) = ( 0,0,2 − 2 i ,0 ) T , B ( q , q ¯ ) = ( 0,0,2,0 ) T , B ( q ¯ , q ¯ ) = ( 0,0,2 + 2 i ,0 ) T
G 20 = 0 , G 11 = 0 , G 02 = 0
H 20 = ( 0,0,2 − 2 i ,0 ) T , H 02 = H ¯ 20 = ( 0,0,2 + 2 i ,0 ) T , H 11 = ( 0,0,2,0 ) T
w 20 = ( 0,,0, − 2 5 − 6 5 i ,0 ) T , w 11 = ( 0,0,2,0 ) T , w 02 = ( 0,0, − 2 5 + 6 5 i ,0 ) T .
Then the constraint equation of the original system on W c is
z ˙ = i z + 1 2 G 20 z 2 + G 11 z z ¯ + 1 2 G 02 z ¯ 2 + 1 2 ( G 21 + 2 〈 p , B ( q , w 11 ) 〉 + 〈 p , B ( q ¯ , w 20 ) 〉 ) z 2 z ¯ + ⋯
Calculating the first Lyapunov coefficient
l 1 ( 0 ) = 1 2 ω 0 R e [ 〈 p , C ( q , q , q ¯ ) 〉 − 2 〈 p , B ( q , A − 1 B ( q , q ¯ ) ) 〉 + 〈 p , B ( q ¯ , ( 2 i ω 0 I n − A ) − 1 B ( q , q ) ) 〉 ] = 4 5 > 0.
Therefore, the Hopf bifurcation is subcritical.
In this section we present some numerical simulations of system (1) to verify the above theoretical analysis. For showing the stability of the equilibrium point S0 of system (1) under the parameter conditions satisfying Theorem 1, we give the time histories of the solutions by Fourth-order Runge-Kutta methods. The parameters are chosen to be ( a , b , c , d ) = ( 2, − 8,1, − 2 ) and ( a , b , c , d ) = ( 2,0.5,2, − 3 ) , satisfying the first and second cases of Theorem 1, respectively. According to
The bifurcation of the system is analyzed in Section 4. According to the results of the theoretical analysis, choosing a = − 1 , b = 5 , c = 1 , d = − 2 , at this point, the parameter conditions for the system to generate Hopf bifurcation are satisfied. We give the time histories, Lyapunov exponential spectrum, projections of four-dimensional phase portrait diagram of the model at this time.
The local dynamics of a new four-dimensional Lorenz-like system is investigated with both analytical and numerical methods in this paper. Starting with a discussion of the number of equilibrium points, the stability is analyzed under different parameters by applying the Routh-Hurwitz criterion. The parameter conditions corresponding to the occurrence of pitchfork bifurcation and Hopf bifurcation, respectively, are given, and the related properties of the bifurcations are analyzed. Finally, numerical simulations verify the correctness of the theoretical parts and show the change in the number of equilibrium points as the pitchfork bifurcation parameter crosses the critical value.
The project was supported by National Natural Science Foundation of China (11772148, 12172166) and China Postdoctoral Science Foundation (2013T60531).
The authors declare no conflicts of interest regarding the publication of this paper.
Ren, Y. and Zhou, L.Q. (2023) Local Dynamics Analysis of a Four-Dimensional Hyperchaotic Lorenz System. Journal of Applied Mathematics and Physics, 11, 2789-2802. https://doi.org/10.4236/jamp.2023.1110182