Difference between revisions of "Differential equations with small parameter"

A system of the type

$$ \tag{1 } \mu \frac{dz}{dt} = F ( z , y , t ) ,\ \frac{dy}{dt} = f ( z , y , t), $$

where $ z $ and $ y $ are, respectively, $ M $- and $ m $- dimensional vectors, and $ \mu > 0 $ is a small parameter. If one puts, formally, $ \mu = 0 $ in (1), one obtains the so-called system of reduced equations

$$ \tag{2 } 0 = F ( z , y , t ) ,\ \frac{dy}{dt} = f ( z , y , t ) . $$

Let the solution $ x ( t , \mu ) $ of (1) ( $ x $ stands for the vector $ ( y, z) $) be defined by certain additional conditions. The clarification of the possibility of using equations (2) to construct an approximation to $ x ( t , \mu ) $ which is asymptotic for small $ \mu $ proves to be difficult owing to the fact that the system (2) is of a lower order than (1), so that its solution cannot meet all the conditions to be satisfied by (1). It is unclear a priori which of the additional conditions to be satisfied by (1) should be retained in defining the solution of (2) and which are to be discarded. Moreover, the equation $ F ( z , y , t ) = 0 $ usually has several roots in $ z $ and, again, it is a priori unclear which of them is to be used in solving system (2) in order to obtain the correct approximation. These features constitute the difference between the problem of the asymptotics of the solution of (1) and the regular case in which $ \mu $ appears not as a coefficient of the derivatives, but appears regularly on the right-hand side.

The first studies of systems such as (1) were concerned with the initial value problem

$$ \tag{3 } \left . z \right | _ {t = 0 } = z ^ {0} ,\ \left . y \right | _ {t = 0 } = y ^ {0} . $$

The most complete result was given by A.N. Tikhonov [1]; its main features are as follows. Let the equation $ F ( z , y , t ) = 0 $ define a number of isolated roots

$$ z = \phi _ {i} ( y , t ) $$

in some closed bounded domain $ D $. Introduce the so-called associated system

$$ \tag{4 } \frac{dz}{d \tau } = F ( z , y ^ {*} , t ^ {*} ) , $$

in which $ y ^ {*} $ and $ t ^ {*} $ are considered as parameters. Take one of the roots $ z = \phi _ {i} $ and denote it by $ z = \phi ( y , t ) $. The root $ z = \phi ( y , t ) $ is said to be stable in $ D $ if for each point $ ( y ^ {*} , t ^ {*} ) \in D $ the corresponding rest point $ z = \phi ( y ^ {*} , t ^ {*} ) $ of the associated system (4) is asymptotically stable. The domain of influence of the stable root $ z = \phi ( y , t ) $ is the set of points $ ( z ^ {*} , y ^ {*} , t ^ {*} ) $ such that the solution of (4) defined by the initial condition $ z \mid _ {\tau = 0 } = z ^ {*} $ tends to $ \phi ( y ^ {*} , t ^ {*} ) $ as $ \tau \rightarrow \infty $. It turns out that if $ z = \phi ( y , t ) $ is a stable root, while the point $ ( z ^ {0} , y ^ {0} , 0 ) $, which is the initial point for the solution $ x ( t , \mu ) $ of the initial value problem (3), belongs to its domain of influence, then, as $ \mu \rightarrow 0 $, the solution tends towards the solution of the system of reduced equations (2), the solution of the first equation in (2) is $ z = \phi ( y , t ) $, while condition (3) is the initial condition for $ y $, but is discarded for $ z $. In other words,

$$ \tag{5 } \lim\limits _ {\mu \rightarrow 0 } \ y ( t , \mu ) = y _ {0} ( t) ,\ 0 \leq t \leq T , $$

$$ \tag{6 } \lim\limits _ {\mu \rightarrow 0 } z ( t , \mu ) = z _ {0} ( t) \equiv \phi ( y _ {0} ( t) , t ) ,\ 0 < t \leq T , $$

where $ y _ {0} ( t) $ is found from the system

$$ \tag{7 } \frac{dy}{dt} = f ( \phi ( y , t ) , y , t ) $$

under the initial condition $ y _ {0} \mid _ {t= 0 } = y ^ {0} $; $ T $ is connected with the dimension of $ D $. Thus, unlike in the regular case, it is only under special conditions that the solution $ x ( t , \mu ) $ of (1) for small $ \mu $ approaches the solution of the system in which $ \mu = 0 $, i.e. system (2).

The limit transition (6) is not uniform since, in general, $ z ^ {0} \neq \phi ( y ^ {0} , 0 ) $. In other words, owing to the "loss" of the initial conditions for $ z $, a neighbourhood of $ t = 0 $ also contains a domain in which $ z ( t , \mu ) $ is not near to $ z _ {0} ( t) $ even though this domain unboundedly contracts as $ \mu \rightarrow 0 $. The name of this effect is boundary layer, in analogy to an effect in hydrodynamics.

The concept of stability of a root $ z = \phi ( y , t ) $ plays an important role in the study of (1). To the various stability criteria of the rest point according to Lyapunov (cf. Lyapunov stability) there correspond various stability criteria of the root $ z = \phi ( y , t ) $. The most useful one is the criterion of the first approximation, which requires that the eigen values $ \lambda $ of the matrix

$$ \tag{8 } \left . \frac{\partial F }{\partial z } \right | _ {z = \phi ( y , t ) } $$

satisfy the inequality $ \mathop{\rm Re} \lambda < 0 $ in $ D $. If $ \mathop{\rm Re} \lambda > 0 $, then the result obtained for the problem (1), (3) is similar to that described above, but for $ t < 0 $. If the matrix (8) has eigen values with real parts of opposite signs, i.e.

$$ \tag{9 } \mathop{\rm Re} \lambda _ {i} < 0 ,\ i = 1 \dots k ; \ \mathop{\rm Re} \ \lambda _ {i} > 0 ,\ i = k + 1 \dots M , $$

the solution of the initial problem (1), (3) usually has no limit as $ \mu \rightarrow 0 $. However, if a boundary condition rather than an initial condition is stipulated for (1), if $ k $ components of the vector $ z $( components will be denoted by subscripts) are specified for $ t = 0 $, while $ M - k $ components of $ z $ are specified for $ t = T $( the value of $ y $ may be specified both for $ t = 0 $ and $ t = T $),

$$ \tag{10 } \left . \begin{array}{c} \left . z _ {i} \right | _ {t = 0 } = \ z _ {i} ^ {0} ,\ i = 1 \dots k; \\ \left . z _ {i} \right | _ {t = T } = \ z _ {i} ^ {0} ,\ i = k+ 1 \dots M, \end{array} \right \} $$

$$ \tag{11 } \left . y \right | _ {t = 0 } = y ^ {0} , $$

then, if certain conditions are satisfied (in analogy to the requirement imposed on the initial value problem, i.e. that the initial point be contained in the domain of attraction of the stable root), then the limit transition (5), (6), where $ y _ {0} ( t) $ is defined as before by the system (7), applies to the solution $ x ( t , \mu ) $ of the problem (1), (10), (11). The limit transition (6) applies for $ 0 < t < T $, and a boundary layer appears both in a neighbourhood of $ t = 0 $ and in a neighbourhood of $ t = T $, since if $ \mu = 0 $, the supplementary conditions (10), specified both for $ t = 0 $ and $ t = T $, are lost. Case (9) is known as the conditionally stable case [2].

Following the establishment of the limit transitions (5), (6), studies were conducted with the purpose of obtaining an asymptotic expansion of its solution. In the regular case the solution of the initial value problem is represented as a power series in $ \mu $:

$$ \tag{12 } x ( t , \mu ) = x _ {0} ( t) + \mu x _ {1} ( t) + \dots $$

which is an asymptotic series if the right-hand sides are sufficiently smooth. In the case (1), owing to the presence of a boundary layer, the asymptotic expansion of the solution may be more complicated, since a so-called boundary-layer correction or boundary-layer series

$$ \tag{13 } x ( t , \mu ) = x _ {0} ( t) + \mu x _ {1} ( t) + \dots $$

$$ \dots + \Pi _ {0} x \left ( \frac{t} \mu \right ) + \mu \Pi _ {1} x \left ( \frac{t} \mu \right ) + \dots $$

may have to be added to a power series of type (12). The terms $ \Pi _ {k} x ( t / \mu ) $ are known as the boundary-layer terms. They are significant near $ t = 0 $, after which they rapidly decrease in accordance with the law $ \mathop{\rm exp} ( \alpha t / \mu ) $, where $ \alpha > 0 $. A detailed description of an algorithm for the construction of an asymptotic expansion of the problem (1), (3) was given in [2], where it was proved that the remainder of the asymptotic expansion (13) is of the order $ O ( \mu ^ {n+} 1 ) $ uniformly with respect to $ t \in [ 0 , T ] $, provided that the right-hand sides of (1) are sufficiently smooth. A similar asymptotic expansion applies to the solution of the problem (1), (10), (11). The difference is that two boundary-layer corrections rather than one have to be added to the power series of the type (12), since a boundary layer is present both in a neighbourhood of $ t = 0 $ and in that of $ t = T $.

The asymptotic representation (13) (if a stable root exists) or the analogous representation with two boundary layers (if a conditionally stable root exists) makes it possible to prove the existence of and to obtain the asymptotics of the solution subject to supplementary conditions which are more complicated than (3) or (10), (11) [2]:

$$ \tag{14 } R ( x ( 0) , x ( T) ) = 0 . $$

All the problems described above for constructing the function to which the unknown solution tends as $ \mu \rightarrow 0 $ involved a single root $ z = \phi ( y , t ) $ of the equation $ F ( z , y , t ) = 0 $. However, if this equation has more than one root, one often observes the phenomenon of transition (or discontinuity). In this situation the solution of equation (1) which satisfies certain additional (in general, boundary) conditions is obtained in the limit as a curve (which is usually discontinuous), comprising several segments, each of which is defined, in the respective interval, by (2), when one of the roots $ z = \phi _ {i} ( y , t ) $ is suitably chosen as a solution of the equation $ F ( z , y , t ) = 0 $. As one passes from one interval to another, the root usually changes. The boundaries of the segments are known as the discontinuity points. In a neighbourhood of each such point a boundary layer is generated — so-called internal boundary layer. The causes of discontinuities may be very different. The asymptotics of the solution with discontinuity points may sometimes be described by an expansion of the type (13) [2] or may be more complicated (see, for instance, [3], [4]).

There exist numerous studies on individual, very different, problems such as the cases when $ \mathop{\rm Re} \lambda $ vanishes, the study of (1) on an infinite interval, the study of the solution of the initial value problem with initial $ z $- values singular in $ \mu $, the study of (1) in its abstract form, etc.; for a review, see [4]. A large number of studies are available on linear equations of the type (1). One of the typical problems in linear equations is the study of the asymptotics of the eigen values and the eigen functions , and the construction of asymptotics of the fundamental system of solutions in the large. The study of the last-named problem becomes very difficult if the system contains so-called turning points (cf. also Small parameter, method of the); for a detailed review of problems of this type see [4].

A number of results obtained for differential equations of the type (1) was applied to integro-differential equations with a small parameter (see, for example, [2]). There is also a large number of studies on partial differential equations containing a small parameter as coefficient of the leading derivative , [7], [10]. Perfectly similar asymptotic relationships are also noted for differential-difference equations with a small deviation of the argument [4].

Differential equations of the type (1), as well as other equations with a similar asymptotic behaviour of the solutions, are named singularly perturbed equations or singular perturbation problems, as distinct from the regular case. Singularly perturbed systems have been studied by the averaging method of Krylov–Bogolyubov, which can be particularly effective in the study of resonance phenomena and oscillation processes; the method of ascent or of regularization has also been proposed [8]. Singularly perturbed equations are also encountered in various domains of physics and technology: in the theory of non-linear oscillations, hydrodynamics, celestial mechanics, quantum mechanics, kinetics, etc. [11].

References

Comments

The technique discussed above to treat the solution by different expansions in the various layers is commonly referred to as the method of matched asymptotic expansions.

The list of references is rather outdated and totally ignores the Western literature. As a general monograph one can consult [a1], recent books on internal layers and relaxation oscillations are [a2], respectively [a3].

It should be noted that Tikhonov's original proof contains a small slip, discovered and amended by F. Hoppensteadt [a4] (see also [a1]). A recent treatise on the averaging method is [a5]. The method is, in general, not applicable to singular perturbation problems of type (1).

References