Dynamic systems describe the interdependence of system variables and their change over time. Dynamic systems are described by differential and difference equations. H. Poincaré first considers the properties of solutions of ordinary differential equations of the second order. He introduces topological methods and the concept of trajectories. A more abstract formulation of dynamic systems was given by A.A. Markov, H. Whitney, and G.D. Birkhoff in 1927 [1] . A significant contribution to the study of periodic points of continuous functions on the segment was made by A.N. Sharkovsky in 1964 [2] . Important developments in the theory of dynamic systems can also be observed in the works of T.-Y. Li and J.A. Yorke in 1975 [3] , W. Melo and S. Strien in 1993 [4] , and J. Milnor and W. Thurston in 1977 [5] . Recent theories of dynamic systems (continuous and discrete) are presented in the works [6] - [8] .

The aim of the research in this manuscript is the possibility of applying dynamic systems to the behavior and discharge of capacitors C in the RC circuit.

Before abstractly defining a dynamic system on some set, the concepts of an open set and open neighborhood of a point will be defined.

Definition 1. Set $A\subseteq R^n$ is open if it holds $\forall x\in A$, $\exists \epsilon >0$, $K\left(x,\epsilon \right)\subseteq A$.

Definition 2. Open neighborhood of a point $x\in R^n$ is any open set that contains the point x.

Definition 3. To set $A\subseteq R$ open in the set R if for $\forall x\in A$, $\exists \epsilon \in A$ such that $\left(x-\epsilon ,x+\epsilon \right)\subset A$.

The entire set R is an open set, and so is $\varnothing$.

Let be the given set of initial values $A\subseteq R^n$. Let be the given set of initial values. The dynamic system represents the evolution of this set over time.

Definition 4. Let be $A\subseteq R^n$ open set. A dynamic system is a set A of functions $\phi \left(t,x\right):R\times A\to A$ class C1 for which applies [1] - [3] :

$\phi \left(0,x\right)=x,x\in A$(1)

$\phi \left(t+p,x\right)=\phi \left(t,\phi \left(p,x\right)\right),t,p\in R$(2)

If we introduce the notation ${\phi }_t\left(x\right)=\phi \left(t,x\right)$ properties (1) and (2) are equivalent to the properties:

${\phi }_0=i{d}_A$ (identity mapping)(1’)

${\phi }_{t+p}={\phi }_t\circ {\phi }_p$(2’)

A dynamic system can also be defined so that the function $\phi$is not defined on the entire product $R\times A$ but on the product $\left\{0\right\}\times A$ (local dynamic system). Similarly, a mapping can be introduced $\phi \left(t,x\right):R_0^{+}\times A\to A$ that generates a dynamic system with the time set $R_0^{+}$. Dynamic system is called a flow if it is $t\in R$ or a semiflow if it is $t\in R_0^{+}$.

For a flow, the mapping is $x\left(t\right)=\phi \left(t,x\right)$ transformation invertible, as it is $\phi \left(-t,x\right)=\phi {\left(t,x\right)}^{-1}$. If time is considered $t\in Z$ for a dynamic system, we say that it is discrete.

Definition 5. For $x\in A$, let’s define:

1) Positive orbit $O_{\phi }^{+}\left(x\right)={\cup }_{t\ge 0}\phi \left(t,x\right)$

2) Negative orbit $O_{\phi }^{-}\left(x\right)={\cup }_{t\le 0}\phi \left(t,x\right)$

3) Orbit $O_{\phi }\left(x\right)=O_{\phi }^{+}\left(t,x\right)\cup O_{\phi }^{-}\left(t,x\right)={\cup }_t\phi \left(t,x\right)$

Definition 6. If for $\forall t\in R,R_0^{+},Z$ or $N_0$ if the relation $\phi \left(t,x\right)=x$ then x fixed point. In dynamical systems, hyperbolic fixed points play a special role. For such points, the following holds $\left|{\phi }^{\prime }\left(t,x\right)\right|\ne 1$, for $\forall t\in R$, $x\in A$. If it:

An attractive fixed point x for the mapping $\phi$ has the property that there exists an open set U containing the point x, whose all points converge to x. Repellent fixed point x for the mapping $\phi$, it has the property that there exists an open set U containing the point x, which repels all points from its vicinity U.

Definition 7. For $x\in A$, we say that it is a periodic point with period $n>0$, if it ${\phi }^n\left(t,x\right)=x$ The smallest non-negative integer n for which the ${\phi }^n\left(t,x\right)=x$ is called the fundamental period of x.

Theorem 1. Let be $\phi \left(t,x\right):R\times A\to A$ a dynamical system. Suppose there $x\left(t\right)=\phi \left(t,x_0\right)$ exists $x_0\in A$. Such that $x\left(t\right)$ is a solution to the autonomous system:

$\begin{array}{l}{x}^{\prime }=f\left(x\right)\\ x\left(0\right)=x_0\end{array}\}$(3)

where is function $f\left(x\right)$ defined by

$f\left(x\right)=\frac{\partial \phi \left(0,x\right)}{\partial t}$(4)

Proof: Let $x\left(t\right)=\phi \left(t,x_0\right)$. Then, according to property (1) of the dynamic system, $x\left(0\right)=\phi \left(0,x_0\right)=x_0$. According to property (2) of the dynamic system, we have:

$x^{\prime }\left(t\right)=\frac{\partial \phi \left(t,x_0\right)}{\partial t}=\frac{\partial \phi \left(0+t,x_0\right)}{\partial t}=\frac{\partial \phi \left(0,\phi \left(t,x_0\right)\right)}{\partial t}=\frac{\partial \phi \left(0,x\left(t\right)\right)}{\partial t}=f\left(x\left(t\right)\right)$(5)

According to, $x\left(t\right)$ is a solution of the system $x^{\prime }=f\left(x\right)$.

Now, let’s consider the autonomous system (RC circuit) depicted in Figure 1 . Initially, the capacitor C is charged with a “capacitive” voltage $U_0$. At time $t=0$, the switch P is turned on, so the capacitor through the resistor begins to discharge. In this case, the condenser acts as a voltage source.

From Kirchhoff’s laws, it follows [9] [10] :

$U_C+U_R=0$(6)

By using the relationships between the voltage and current of individual circuit components, we have:

$U_R=R\cdot I,I=C\cdot {U^{\prime }}_C$(7)

By substituting the expression from Equation (7) into Equation (6), we obtain the differential equation of the RC circuit.

$R\cdot C\cdot {U^{\prime }}_C\left(t\right)+U_C\left(t\right)=0$(8)

The initial condition is the initial voltage across the capacitor $U_C\left(0\right)=U_0$.

If we introduce the time constant $\tau =R\cdot C$, Equation (8) takes the form:

${U^{\prime }}_C\left(t\right)+\frac{1}{\tau }\cdot U_C\left(t\right)=0$(9)

with the initial condition $U_C\left(0\right)=U_0$.

Equation (9) is a homogeneous first-order differential equation with constant coefficients, and its solution is:

$U_C\left(t\right)=K\cdot {\text{e}}^{-\frac{t}{\tau }}$(10)

where K is a constant.

The value of the constant K is determined by the condition $U_C\left(0\right)=U_0=K$.

Now, the general solution is represented as:

$U_C\left(t\right)=U_0\cdot {\text{e}}^{-\frac{t}{\tau }}$(11)

which is defined over the entire set $R_0^{+}$ and $\tau >0$.

The graph depicting the dependence of the capacitor voltage $U_C\left(t\right)$ on time is shown in Figure 2 .

It can be observed that the capacitor discharges not instantaneously, but according to an exponential law. The time constant $\tau =RC$ influences the rate of capacitor discharge. The larger the time constant, the slower the discharge. At the moment $t=\tau =RC$ when the “capacitive” voltage on the capacitor reaches 36.79% of its maximum value. If the transient lasts approx $t=5\tau$ then in engineering applications the capacitor is considered to be nearly discharged.

The “capacitive” voltage on the capacitor is then equal to 0.67% of its maximum value, and then the stationary state occurs. It can be considered that the transient process is over and that the voltage on the capacitor has reached its final value.

In a similar way, the expression for determining the current I in the RC circuit is obtained:

$I=I_0\cdot {\text{e}}^{-t/\tau }$ (12)

where is:

$I_0=\frac{U_0}{R}$ (13)

The graph of Equation (12) is similar to the graph shown in Figure 2 , which also shows an exponential decline in time $t=\tau$ and the current also drops to 36.79% from its maximum value.

The qualitative analysis of the circuit will provide a phase portrait along the trajectory. Equation (9) is equivalent to the equation ${U^{\prime }}_C\left(t\right)=-\frac{1}{\tau }{U}_C\left(t\right)$ We define a function $f\left(U_C\right)=-\frac{1}{\tau }{U}_C$, $U_C\ge 0$, $\tau >0$ whose zero point is $U_C^{\ast }=0$ and the considered function is decreasing. From ${U^{\prime }}_C<0$ for $U_C>U_C^{\ast }$ , it is concluded that $U_C$ decreases in that part and we get a phase portrait ( Figure 3 ).

From the phase portrait on the line, it can be seen that the charge (capacitive voltage) $U_C\left(t\right)\to U_C^{\ast }=0$ when $t\to \infty$ regardless of the initial conditions, it stabilizes. Figure 2 shows the same but also provides information about time t.

Since all Solutions (11) of the autonomous System (9) are defined on the set $R_0^{+}$, the corresponding dynamic system can be formed using the function:

$\phi \left(t,U_C\right)=U_C\cdot {\text{e}}^{-\frac{t}{\tau }}$(14)

The function $\phi \left(t,U_C\right):R_0^{+2}\to R_0^{+}$ defined by Expression (14) satisfies both conditions of the dynamic system. It is easy to check that it is valid:

$\phi \left(0,U_C\right)=U_C\cdot {\text{e}}^0=U_C$, condition (1).

$\phi \left(t,\phi \left(p,U_C\right)\right)=\phi \left(t,U_C\cdot {\text{e}}^{-\frac{p}{\tau }}\right)=U_C\cdot {\text{e}}^{-\frac{p}{\tau }}\cdot {\text{e}}^{-\frac{t}{\tau }}=U_C\cdot {\text{e}}^{-\frac{t+p}{\tau }}=\phi \left(t+p,U_C\right)$, $t,p\in R_0^{+}$, condition (2).

According to definition 6, we get $\phi \left(t,U_C\right)=U_C\cdot {\text{e}}^{-t/\tau }=U_C$ from where it follows $U_C\cdot \left(1-{\text{e}}^{-t/\tau }\right)=0$ , so it’s obvious $U_C=0$ fixed point of the dynamic model. Besides that, it is valid $\left|{\phi }^{\prime }\left(t,U_C\right)\right|=\left|{\phi }^{\prime }\left(t,0\right)\right|=\left|{\text{e}}^{-t/\tau }\right|<1$ for $\forall t\in R^{+}$ so the fixed point $U_C=0$ is attractive; that is, it represents an abyss ( Figure 3 ).

The numerical simulation of the dynamic system (Equation (14)) is shown in Figure 4 . It can be seen that the diagram shown in Figure 2 is obtained by the intersection of the surface $\phi \left(t,U_C\right)=U_C\cdot {\text{e}}^{-\frac{t}{\tau }}$ with the plane $U_C=\text{const}$. Figure 4 also shows the behavior of the RC circuit with variable voltage and time.

Using theorem 1, it can be shown that, starting from the dynamic system, the corresponding autonomous system (circuit equation) can be found. We have that:

$f\left(U_C\right)=\frac{\partial \phi \left(0,U_C\right)}{\partial t}=-\frac{1}{\tau }\cdot U_C$

and according to (3) it follows ${U^{\prime }}_C=-\frac{1}{\tau }\cdot U_C$ or ${U^{\prime }}_C+\frac{1}{\tau }\cdot U_C=0$, which is Equation (9), i.e., the equation of the RC circuit.

The paper considers an electric circuit that is initially charged with a “capacitive” voltage U₀. At the moment $t=0$, the P circuit switch is turned on, and the discharge of the “capacitive” voltage on the capacitor is monitored over time, and the following conclusions were reached:

A—expensive

C—condenser

$f\left(x\right)$—function of x

I—electricity

K—constant

$K\left(x,\epsilon \right)$—a sphere with the center at the point of the radius

N₀—set of natural numbers and zero

O—orbit

P—switch

R—a set of real numbers

$R_0^{+}$—the set of non-negative real numbers

R—resistance

t—time

τ—time constant

U—voltage

x—independent variable