Dynamic Evolution Analysis of Stock Price Fluctuation and Its Control

This paper studies a simple dynamical system of stock price fluctuation time series based on the rule of stock market. When the stock price fluctuation system is disturbed by external excitations, the system exhibits obviously chaotic phenomena, and its basic dynamic properties are analyzed. At the same time, a new fixed-time convergence theorem is proposed for achieving fixed-time control of stock price fluctuation system. Finally, the effectiveness of the method is verified by numerical simulation.


Introduction
Since Lorenz found the first chaotic attractor [1], a variety of chaotic systems have been found, and in particular chaotic phenomenon also appeared in the economic system; for example, Chen discovered the existence of chaotic attractor in stock market [2].Xie et al. studied chaos synchronization of financial chaotic system with external perturbation [3].Ma et al. studied chaotic financial Cournot model with dual-channel recycling and uncertain consumer perception [4].Despite the existence of chaotic phenomena in the economic system, but the development of dynamic model in the economy is relatively slow; the main reason is that there are some difficulties to establish complex dynamic system by abstracting the economic phenomenon.Recently, some researchers discussed stock price problem by dynamic method; for example, Li et al. considered the problem of the dynamic pricing and the periodic ordering for deteriorating items with a stochastic inventory level depending on the stock-dependent demand and the selling price [5].Grassetti and Hunanyan discussed the economic growth theory with Kadiyala production function [6].Arévalo et al. discussed the dynamic trading rule based on filtered flag pattern recognition for stock market price forecasting [7].Zhang et al. studied dynamic static pricing in a supply chain with advertising [8].Primbs and Barmish presented robustness of simultaneous long-short stock trading control with timevarying price dynamics [9].In [5][6][7][8][9], although the authors studied the price index problem with dynamics, it did not discuss the price fluctuation problem from the nonlinear point of view; in particular the external excitations problem of the price fluctuation system was not discussed.However, the nonlinear phenomenon of price fluctuation and the external excitations of the dynamic system [10] are common in practice.Therefore, it is meaningful to discuss the nonlinear characteristics of price fluctuation system under external excitations.
In addition, the chaos is sometimes harmful to the dynamical system in some cases, so it is essential for the effective control of the dynamical system.The various methods of chaos control have been put forward by researchers [11][12][13][14][15][16]; these control methods were mostly based on infinite time control.In fact, complex systems are usually required to be controlled in a certain amount of time, the finite time control became an important index to measure the quality of the control criteria, and it not only has important theoretical significance and also has important practical value [17].However, the stable time of finite time control depends largely on the initial state of the system, so there are some limitations in the practical application.In order to compensate for the Complexity finite time control, Polyakov proposed the fixed-time stability of the system [18], and the stability is as follows: (1) fixed time guaranteed that the system is the finite time stability without regard to initial conditions.Hence, the study of fixed-time control has a wide range of research interests, and more and more fixed-time control methods were also proposed [19][20][21][22].In particular, in [23], Zuo proposed a class of fixed-time stability theory for the differential equation: ẏ = − 2−/ −  / , which was fixed-time stable at  ≤ /2√( − ).Subsequently, the theorem proposed by Zuo was used to discuss the fixed-time control of dynamical systems; please see [21,[24][25][26][27].This paper attempts to propose a new finite time convergence theory to discuss the control problem of stock price fluctuation system, the new fixed-time stability method proposed in this paper converged faster than the proposed method by Zuo, and the new fixed-time stable theorem contains the theorem proposed by Zuo, so the new fixed-time stable theorem can be applied more widely.
Motivated by the existing works, the aim of this paper is to discuss dynamic evolution of stock price fluctuation and its control.The main contributions of this paper are as follows: (1) a stock price fluctuation dynamical system is established under the influence of external excitations, and its basic dynamic behavior is analyzed.(2) A new fixedtime convergence theorem is proposed.(3) According to the new fixed-time convergence theorem, the fixed-time control criterion of the stock price fluctuation dynamical system is given.
According to the literature [28], the difference between supply and demand of the stock at time  is described in mathematical model as follows: Assume that all variables are continuous functions about time , according to (1): ( As long as the introduction coefficient meets dimensional requirements, formula (2) can be written into an equation; that is, Ṗ () =  () .
Assuming a risk neutral, "buy low sell high" strategy is to be executed in the stock market.According to the law of the stock market,   () is inversely proportional to (), and   () is proportional to the negative value of Ṗ ().Thus the equation is obtained: In (4), if Ṗ () ≈ ( + 1) − () > 0, that is, ( + 1) > (), then the amount of stock purchase should be reduced; on the other hand, the amount of stock purchased should be increased for Ṗ () ≈ ( + 1) − () < 0. However, the rate of change in stock buying not only is related to the price of stock and the rate of stock price change at the moment  but also has a direct relationship with the buying and selling volume of stock at the moment .Let the rate of change in stock buying be proportional to the buying amount at the moment  and be proportional to the negative value of the stock sold.Thus the equation is obtained: where  1 denotes the outside market interference, such as the impact of external policy.Similar to (5), the rate of change for selling volume   () is directly proportional to the stock price and is proportional to the rate of change for the stock price; meanwhile,   () is proportional to the selling amount at time , and it is proportional to the negative value of the stock buying.Thus the equation is obtained: similar to  1 ,  2 denotes the outside market interference.
From ( 1)-( 6), we have Therefore, the dynamic equation of stock price fluctuation () is , and ( 1 −  2 −  1  0 ) =  cos , and then the dynamic equation of stock price fluctuation () can be reduced to where () represents the state of stock price fluctuation, p () represents the acceleration of stock price fluctuation,  represents the control parameter of the policy, and  represents the frequency of external excitations.
To facilitate the analysis of model ( 9), it can be described in the following: where () = ().
Remark 2. The dynamic method are often utilized to depict the complicated systems in the real world [29], and the nonlinear phenomenon of price fluctuation and the external excitations of the system [10] are common in practice.Therefore, it is meaningful to discuss the nonlinear characteristics of price fluctuation dynamical system under external excitations by dynamic method.

Some Basic Properties of the Dynamics Model
In this section, we will investigate some basic properties of (11).
(2) When () ̸ = 0 and  cos  ̸ = 0, the equilibrium points are (3) When () ̸ = 0 and  cos  = 0, the equilibrium points are Equations ( 11) are linearized, and the Jacobian matrix is defined as To gain its eigenvalues, we let | − | = 0, so the corresponding eigenvalues are 2 . ( According to (16), the eigenvalues are only related to the abscissa of the equilibrium points, so there are the following conclusions: (i) When  3 > 0, all the equilibrium points are unstable.
(iii) All the equilibrium points are stable except for two cases (i)-(ii).

Dissipativity and the Existence of Attractor.
For system (11), we can obtain when  3 is a negative value, system (11) is a dissipative system, and an exponential contraction of system (11) is

Complexity
In system (11), a volume element  0 is apparently contracted by the flow into a volume element  0   3  at time .It means that each volume containing the trajectory of the systems shrinks to zero as  → ∞ at an exponential rate  3 .So, all the systems orbits are eventually confined to a specific subset that have zero volume; the asymptotic motion settles onto an attractor of system (11) [30].
In addition, the Lyapunov dimension of the system is which means that system ( 11) is really a dissipative system and the Lyapunov dimension of the system is fractional.
When the parameters change, the bifurcation diagram would be far better to summarize all of the possible behaviors.For  ∈ [0, 1], the bifurcation diagram of system (11) shows the complicated bifurcation phenomena in Figure 3.The maximum Lyapunov exponent diagram is shown in Figure 4. Figure 4 shows that the system has some periodic windows, which play a very important role in the dynamics evolution of the system.In addition, Figure 5 shows the continuous broadband features of the system.Figure 6 shows the Poincare diagram of the system; it is clear that some sheets are folded, which also leads to complex dynamical behavior of the system.Remark 3. In [5][6][7][8][9], although the authors analyzed some dynamical properties of price indices based on dynamics, some nonlinear properties of the price fluctuation system were not considered, such as the equilibrium point and stability, Lyapunov exponent, fractal dimension, and bifurcation diagram.
Then, system ( 21) is fixed-time stable, and Based on Lemma 5, we obtain Lemma 6.
Remark 8.If  > ( + )/,  <  < ( 2 /4), and then that is, the fixed-time stable of the system presented in this paper achieves more faster convergence than Lemma 5.
Remark 9. Some researchers have discussed the fixed-time control problem of dynamical systems by using the theorem proposed by Zuo [21,[24][25][26][27]. From Remark 8, the fixedtime stable theorem of the dynamical system proposed in this paper achieves more faster convergence than the theorem proposed by Zuo and in [21,[24][25][26][27].

Complexity
Remark 10.In Lemma 6, as  can take any value greater than 2/, and 2/ < 2, Lemma 6 contains Lemma 5 proposed by Zuo, and Lemma 5 can be applied more widely.
Based on Lemma 6, we analyze the fixed-time control problem of system (11).
If system (11) is the driving system, the response system is According to system (11) and ( 31), the error system is where  1 =  1 −  and  2 =  1 − .
Theorem 11.The drive system (11) and the response system (31) are fixed-time synchronization under the following controller:

Conclusion
Chaos and bifurcation are complex phenomena in nonlinear economic and financial systems.In this paper, the stock price fluctuation dynamic system has been established according to the rule of the stock market, and basic dynamic properties of the system has been analyzed by external excitations, such as the equilibrium point and stability, Lyapunov exponent, fractal dimension, and bifurcation diagram.At the same time, the new fixed-time convergence theorem has been proposed in this paper, and the fixed-time control criterion of the stock price fluctuation system has also been studied.Our future work is to study dynamic properties of stock price fluctuation system with time-delay.