Quasi-linearization
A collection of methods for the numerical solution of non-linear problems by reducing them to a sequence of linear problems. Lying at the basis of the apparatus of quasi-linearization is the Newton method and its generalization to function spaces, the theory of differential inequalities (cf. Differential inequality) and the method of dynamic programming. The simplest example illustrating a method of quasi-linearization is the use of the Newton–Raphson method for finding the root $ r $
of a scalar monotone-decreasing strictly-convex function $ f $.
In case the original non-linear function $ f $
is approximated at each stage of the iteration process by a linear function $ \phi $,
the root of $ \phi $
is found, which serves as the next approximation, so that
$$ x _ {n+} 1 = x _ {n} - \frac{f ( x _ {n} ) }{f ^ { \prime } ( x _ {n} ) } ,\ \ n = 0 , 1 ,\dots . $$
Under fairly general conditions the sequence so constructed has the property of monotonicity $ ( x _ {0} < x _ {1} < \dots < r ) $ and quadratic convergence:
$$ | x _ {n+} 1 - r | \leq k | x _ {n} - r | ^ {2} . $$
The application of quasi-linearization to solving the Riccati equation
$$ v ^ \prime + v ^ {2} + p ( t) v + q ( t) = 0 ,\ \ v ( 0) = c $$
(it is assumed that a solution exists on an interval $ [ 0 , t _ {0} ] $), is as follows. The original equation is replaced by the equivalent equation
$$ v ^ \prime = \min _ { u } [ u ^ {2} - 2 u v - p ( t) v - q ( t) ] , $$
where the minimum is taken over all functions $ u $ defined on $ [ 0 , t _ {0} ] $. This equation has a number of properties inherent to linear equations, and in order to solve it one uses the linear differential equation
$$ w ^ \prime = u ^ {2} - 2 u w - p ( t) w - q ( t) ,\ \ w ( 0) = c , $$
where $ u $ is a fixed function. By appealing to the property $ v ( t) \leq w ( t) $( equality holding when $ u ( t) = v ( t) $), one can construct a system of successive approximations
$$ v _ {1} \geq v _ {2} \geq \dots $$
satisfying the linear equations
$$ v _ {n+} 1 ^ \prime = v _ {n} ^ {2} - 2 v _ {n} v _ {n+} 1 - p ( t) v _ {n+} 1 - q ( t) ,\ \ v _ {n+} 1 ( 0) = c . $$
The same recurrence relation can be obtained by applying the Newton–Kantorovich method (cf. Kantorovich process) to the original non-linear equation.
The employment of a quasi-linearization scheme in the solution of boundary value problems for the non-linear second-order differential equation
$$ u ^ {\prime\prime} = f ( u ^ \prime , u , t ) ,\ \ t _ {1} \leq t \leq t _ {2} , $$
$$ g _ {1} ( u ( t _ {1} ) , u ^ \prime ( t _ {1} ) ) = 0 ,\ \ g _ {2} ( u ( t _ {2} ) , u ^ \prime ( t _ {2} ) ) = 0, $$
leads to a sequence of functions $ \{ u _ {n} \} $ satisfying the linear equations
$$ u _ {n+} 1 ^ {\prime\prime} = f ( u _ {n} ^ \prime , u _ {n} , t ) + f _ {u ^ \prime } ( u _ {n} ^ \prime , u _ {n} , t ) ( u _ {n+} 1 ^ \prime - u _ {n} ^ \prime ) + $$
$$ + f _ {n} ( u _ {n} ^ \prime , u _ {n} , t ) ( u _ {n+} 1 - u _ {n} ) , $$
with the linearized boundary conditions
$$ g _ {i} ( u _ {n} ( t _ {i} ) ,\ u _ {n} ^ \prime ( t _ {i} ) ) + g _ {iu} ( u _ {n} ( t _ {i} ) , u _ {n} ^ \prime ( t _ {i} ) ) ( u _ {n+} 1 ( t _ {i} ) - u _ {n} ( t _ {i} ) ) + $$
$$ + g _ {i u ^ \prime } ( u _ {n} ( t _ {i} ) , u _ {n} ^ \prime ( t _ {i} ) ) ( u _ {n+} 1 ^ \prime ( t _ {i} ) - u _ {n} ^ \prime ( t _ {i} ) ) = 0 . $$
The existence, uniqueness and quadratic convergence of the sequence follows from the corresponding convexity of the functions $ f , g _ {1} , g _ {2} $ over a sufficiently small interval $ [ t _ {1} , t _ {2} ] $.
The method of quasi-linearization finds application in the solution of two-point and multi-point boundary value problems for linear and non-linear ordinary differential equations, boundary value problems for elliptic and parabolic partial differential equations, variational problems, differential-difference and functional-differential equations, etc. As with every iteration scheme, the method of quasi-linearization is suitable for computer implementation and has various modifications enabling one to accelerate the convergence for narrower classes of problems. There exists a variety of examples of its use as a heuristic method for solving a number of problems in physics, technology and economy.
References
[1] | R.E. Bellman, R.E. Kalaba, "Quasilinearization and nonlinear boundary-value problems" , Elsevier (1965) (Translated from Russian) |
Comments
References
[a1] | R. Bellman, G. Adomian, "Partial differential equations" , Reidel (1985) pp. Chapt. IV |
[a2] | R. Bellman, R. Vasudevan, "Wave propagation. An invariant imbedding approach" , Reidel (1986) |
Quasi-linearization. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Quasi-linearization&oldid=17538