Relaxation oscillation

A periodic process in which slow smooth change of the state of an object over a finite interval of time is alternated with rapid irregular change of the state during an infinitely short time. Such oscillatory processes are observed in many real mechanical, radiotechnical, biological, etc., objects (see e.g. [1]–[3]).

The mathematical models describing relaxation oscillations are autonomous systems (cf. Autonomous system) of ordinary differential equations with a small parameter in front of some of the derivatives:

$$ \tag{1 } \epsilon \dot{x} = f( x, y),\ \ \dot{y} = g( x, y),\ \ \dot{ {}} = \frac{d}{dt} , $$

$$ x \in \mathbf R ^ {k} ,\ y \in \mathbf R ^ {m} ,\ 0 < \epsilon \ll 1 . $$

A periodic solution with respect to the time $ t $ of such a system is called a relaxation oscillation. The traditional example of a system with one degree of freedom and having relaxation oscillations is the van der Pol equation

$$ \tag{2 } \frac{d ^ {2} x }{d \tau ^ {2} } - \lambda ( 1- x ^ {2} ) \frac{d x }{d \tau } + x = 0 $$

for large positive values of the parameter $ \lambda $( from this point of view the value $ \lambda = 10 $ can be considered as large). Putting

$$ y = \int\limits _ { 0 } ^ { x } ( x ^ {2} - 1) dx + \frac{1} \lambda \frac{dx}{d \tau } ,\ \ t = \frac \tau \lambda ,\ \ \epsilon = \frac{1}{\lambda ^ {2} } , $$

equation (2) is reduced to a system of the form (1):

$$ \epsilon \dot{x} = y - \frac{x ^ {3} }{3} + x,\ \ \dot{y} = - x. $$

The problem of the existence and number of relaxation oscillations in a system (1) is solved in terms of a degenerate system

$$ \tag{3 } f( x, y) = 0,\ \ \dot{y} = g( x, y), $$

which is a hybrid system of equations. The trajectories of the system (3) in the phase space $ \mathbf R ^ {k} \times \mathbf R ^ {m} $ are naturally treated as limits of the phase trajectories of the non-degenerate system (1) as $ \epsilon \rightarrow 0 $. In particular, the trajectory of a relaxation oscillation of the system (1), as $ \epsilon \rightarrow 0 $, tends towards a closed trajectory of the system (3) that consists of alternating sections of two types: sections lying on $ f( x, y) = 0 $ and satisfying $ \dot{y} = g( x, y) $ and "jumps" from one point of $ f( x, y) = 0 $ to another. Each of these jumps starts at a break point, i.e. at a point where

$$ f( x, y) = 0,\ \ \mathop{\rm det} \left \| \frac{\partial f }{\partial x } \right \| = 0 $$

and lies in a plane parallel to $ \mathbf R ^ {k} $. The solution of the system (3) corresponding to such a closed trajectory is called a discontinuous periodic solution. Consequently, the relaxation oscillation of the system (1) is often called the periodic solution close to the discontinuous one, or even simply the discontinuous oscillation. (The system (3) may have a closed trajectory entirely lying on the surface $ f( x, y) = 0 $ and not passing through a break point. In this case (1) has a closed trajectory near to it, but the periodic solution of (1) corresponding to it will not be a relaxation oscillation; see [6].)

An important question is the asymptotic (for $ \epsilon \rightarrow 0 $) calculation of the phase trajectory of the relaxation oscillation of the system (1), and the establishment of asymptotic formulas for the characteristics of this oscillation — its period, amplitude, etc. The trajectory of the relaxation oscillation of the van der Pol equation (2) has been calculated by A.D. Dorodnitsyn [7] by constructing asymptotic approximations, for $ \lambda \rightarrow \infty $, for the amplitude

$$ a = 2 + 0.77937 \lambda ^ {-4/3} - \frac{16}{27} \frac{ \mathop{\rm ln} \lambda }{ \lambda ^ {2} } - 0.8762 \lambda ^ {-2} + O( \lambda ^ {-8/3} ), $$

and for the period (see also [8])

$$ T = 1.613706 \lambda + 7.01432 \lambda ^ {-1/3} - \frac{2}{3} \frac{ \mathop{\rm ln} \lambda } \lambda + $$

$$ - 1.3233 \lambda ^ {-1}+ O( \lambda ^ {-5/3} ). $$

If the system (1) is of the second order (i.e. for $ k= m= 1 $) with break points in general position, the problem of the asymptotic calculation of the relaxation oscillation has been solved completely [9]. In particular, the structure of the asymptotic expansion, for $ \epsilon \rightarrow 0 $, of the period of the relaxation oscillation has been clarified:

$$ T = T _ {0} + \sum_{n=2}^ \infty \epsilon ^ {n/3} \sum _ {\nu = 0 } ^ { { } \chi ( n- 2) } K _ {n, \nu } \mathop{\rm ln} ^ \nu \frac{1} \epsilon , $$

where

$$ \chi ( n) = \frac{n}{3} + \frac{2 \sqrt 3 }{9} \mathop{\rm tan} \frac{\pi n }{3} ,\ \ n \in \mathbf Z ; $$

and the $ K _ {n, \nu } $ are coefficients which are effectively calculable directly from the functions $ f( x, y) $ and $ g( x, y) $( see [10]). In a general system (1) of arbitrary order, the results of L.S. Pontryagin and E.F. Mishchenko (1983) have not been surpassed: they calculated the asymptotics of the relaxation oscillation correctly up to $ O( \epsilon ) $( see [11], [12], [9]).

Periodic solutions of the type of relaxation oscillations of non-autonomous systems of ordinary differential equations have also been studied (see e.g. [13]).

References

Comments

For weakly-forced and weakly-coupled relaxation oscillations one can derive formulas for synchronization and phase shift between the oscillators, see [a1]. In this reference also a survey of the Western literature on relaxation oscillations is given. Moreover, a method is presented to analyze chaotic relaxation oscillations.

When by a Hopf bifurcation a relaxation oscillation branches off from a stable equilibrium, a typical transition is observed known as the "canardcanard" . It was first analyzed mathematically with non-standard analysis, see [a2].

The study of perturbed equations

$$ \tag{a1 } \dot{x} = f( x, y) ,\ \ \dot{y} = \epsilon g ( x, y) $$

and the corresponding constrained differential equation

$$ \tag{a2 } \dot{x} = f( x, y) ,\ \ g ( x, y) = 0 $$

and their solutions in relation to each other belongs to the theory of singular perturbations; cf. also Differential equations with small parameter and Boundary-layer theory. A selection of references dealing with singular perturbations is [a3]–[a5]. Some early papers dealing with the interrelations of solutions of (a1), (a2) are [a6]–[a8]. To discuss the relations between solutions of (a1), (a2) one needs an appropriate concept of solution for constrained differential equations like (a2). For this see [a9], [a10].

A brief, explicit discussion of relaxation oscillations for the case of the van der Pol equation (complete with figure) can be found in [a11], pages 34-35, see also [a12], sections 14.2 and 14.3.

The phrase "relaxation oscillation" was introduced by B. van der Pol in 1926.

References