Boundary Value Problems/Ordinary-Differential-Equations

Let y be an unknown function

${\displaystyle y:\mathbb {R} \to \mathbb {R} }$ 

in x with ${\displaystyle y^{(n)}}$  the n^th derivative of y, then an equation of the form

${\displaystyle F(x,y,y',\ \dots ,\ y^{(n-1)})=y^{(n)}}$ 

is called an ordinary differential equation (ODE) of order n; for vector valued functions,

${\displaystyle y:\mathbb {R} \to \mathbb {R} ^{m}}$ ,

it is called a system of ordinary differential equations of dimension m.

When a differential equation of order n has the form

${\displaystyle F\left(x,y,y',y'',\ \dots ,\ y^{(n)}\right)=0}$ 

it is called an implicit differential equation whereas the form

${\displaystyle F\left(x,y,y',y'',\ \dots ,\ y^{(n-1)}\right)=y^{(n)}}$ 

is called an explicit differential equation.

A differential equation not depending on x is called autonomous.

A differential equation is said to be linear if F can be written as a linear combination of the derivatives of y

${\displaystyle y^{(n)}=\sum _{i=0}^{n-1}a_{i}(x)y^{(i)}+r(x)}$ 

with a_i(x) and r(x) continuous functions in x. The function r(x) is called the source term; if r(x)=0 then the linear differential equation is called homogeneous, otherwise it is called non-homogeneous or inhomogeneous.

Given a differential equation

${\displaystyle F(x,y,y',\dots ,y^{(n)})=0}$ 

a function u: I ⊂ R → R, is called the solution or integral curve for F, if u is n-times differentiable on I, and

${\displaystyle F(x,u,u',\ \dots ,\ u^{(n)})=0\quad x\in I.}$ 

Given two solutions u: J ⊂ R → R and |v: I ⊂ R → R, u is called an extension of v ifI ⊂ J and

${\displaystyle u(x)=v(x)\quad x\in I.\,}$ 

A solution which has no extension is called a global solution.

A general solution of an n-th order equation is a solution containing n arbitrary variables, corresponding to n constant of integration|constants of integration. A particular solution is derived from the general solution by setting the constants to particular values, often chosen to fulfill set 'initial value problem|initial conditions or boundary conditions. A singular solution is a solution that can't be derived from the general solution.

Any differential equation of order n can be written as a system of n first-order differential equations. Given an explicit ordinary differential equation of order n and dimension 1,

${\displaystyle F\left(x,y,y',y'',\ \dots ,\ y^{(n-1)}\right)=y^{(n)}}$ 

we define a new family of unknown functions

${\displaystyle y_{n}:=y^{(n-1)}.\!}$ 

We can then rewrite the original differential equation as a system of differential equations with order 1 and dimension n.

${\displaystyle y_{1}^{'}=y_{2}}$ 

${\displaystyle y_{2}^{'}=y_{3}}$ 

${\displaystyle \vdots }$ 

${\displaystyle y_{n-1}^{'}=y_{n}}$ 

${\displaystyle y_{n}^{'}=F(y_{n},\dots ,y_{1},x).}$ 

which can be written concisely in vector notation as

${\displaystyle \mathbf {y} ^{'}=\mathbf {F} (\mathbf {y} ,x)}$ 

with

${\displaystyle \mathbf {y} :=(y,\ldots ,y_{n}).}$ 

A well understood particular class of differential equations is linear differential equations. We can always reduce an explicit linear differential equation of any order to a system of differential equation of order 1

${\displaystyle y_{i}'(x)=\sum _{j=1}^{n}a_{i,j}(x)y_{j}+b_{i}(x)\,\mathrm {,} \quad i=1,\ldots ,n}$ 

which we can write concisely using matrix and vector notation as

${\displaystyle \mathbf {y} ^{'}(x)=\mathbf {A} (x)\mathbf {y} (x)+\mathbf {b} (x)}$ 

with

${\displaystyle \mathbf {y} (x):=(y_{1}(x),\ldots ,y_{n}(x))}$ 

${\displaystyle \mathbf {b} (x):=(b_{1}(x),\ldots ,b_{n}(x))}$ 

${\displaystyle \mathbf {A} (x):=(a_{i,j}(x))\,\mathrm {,} \quad i,j=1,\ldots ,n.}$ 

The set of solutions for a system of homogeneous linear differential equations of order 1 and dimension n

${\displaystyle \mathbf {y} ^{'}(x)=\mathbf {A} (x)\mathbf {y} (x)}$ 

forms an n-dimensional vector space. Given a basis for this vector space ${\displaystyle \mathbf {z} _{1}(x),\ldots ,\mathbf {z} _{n}(x)}$ , which is called a fundamental system, every solution ${\displaystyle \mathbf {s} (x)}$  can be written as

${\displaystyle \mathbf {s} (x)=\sum _{i=1}^{n}c_{i}\mathbf {z} _{i}(x).}$ 

The n × n matrix

${\displaystyle \mathbf {Z} (x):=(\mathbf {z} _{1}(x),\ldots ,\mathbf {z} _{n}(x))}$ 

is called fundamental matrix. In general there is no method to explicitly construct a fundamental system, but if one solution is known d'Alembert reduction can be used to reduce the dimension of the differential equation by one.

The set of solutions for a system of inhomogeneous linear differential equations of order 1 and dimension n

${\displaystyle \mathbf {y} ^{'}(x)=\mathbf {A} (x)\mathbf {y} (x)+\mathbf {b} (x)}$ 

can be constructed by finding the fundamental system ${\displaystyle \mathbf {z} _{1}(x),\ldots ,\mathbf {z} _{n}(x)}$  to the corresponding homogeneous equation and one particular solution ${\displaystyle \mathbf {p} (x)}$  to the inhomogeneous equation. Every solution ${\displaystyle \mathbf {s} (x)}$  to nonhomogeneous equation can then be written as

${\displaystyle \mathbf {s} (x)=\sum _{i=1}^{n}c_{i}\mathbf {z} _{i}(x)+\mathbf {p} (x).}$ 

A particular solution to the nonhomogeneous equation can be found by the method of undetermined coefficients or the method of variation of parameters.

If a system of homogeneous linear differential equations has constant coefficients

${\displaystyle \mathbf {y} ^{'}(x)=\mathbf {A} \mathbf {y} (x)}$ 

then we can explicitly construct a fundamental system. The fundamental system can be written as a matrix differential equation

${\displaystyle \mathbf {Y} ^{'}=\mathbf {A} \mathbf {Y} }$ 

with solution as a matrix exponential

${\displaystyle e^{x\mathbf {A} }}$ 

which is a fundamental matrix for the original differential equation. To explicitly calculate this expression we first transform A into Jordan normal form

${\displaystyle e^{x\mathbf {A} }=e^{x\mathbf {C} ^{-1}\mathbf {J} \mathbf {C} ^{1}}=\mathbf {C} ^{-1}e^{x\mathbf {J} }\mathbf {C} ^{1}}$ 

and then evaluate the Jordan blocks

${\displaystyle J_{i}={\begin{bmatrix}\lambda _{i}&1&\;&\;\\\;&\ddots &\ddots &\;\\\;&\;&\ddots &1\\\;&\;&\;&\lambda _{i}\end{bmatrix}}}$ 

of J separately as

${\displaystyle e^{x\mathbf {J_{i}} }=e^{\lambda _{i}x}{\begin{bmatrix}1&x&{\frac {x^{2}}{2}}&\dots &{\frac {x^{n-1}}{(n-1)!}}\\\;&\ddots &\ddots &\ddots &\vdots \\\;&\;&\ddots &\ddots &{\frac {x^{2}}{2}}\\\;&\;&\;&\ddots &x\\\;&\;&\;&\;&1\end{bmatrix}}.}$ 

• A. D. Polyanin and V. F. Zaitsev, Handbook of Exact Solutions for Ordinary Differential Equations (2nd edition), Chapman & Hall/CRC Press, Boca Raton, 2003. ISBN 1-58488-297-2
• A. D. Polyanin, V. F. Zaitsev, and A. Moussiaux, Handbook of First Order Partial Differential Equations, Taylor & Francis, London, 2002. ISBN 0-415-27267-X
• D. Zwillinger, Handbook of Differential Equations (3rd edition), Academic Press, Boston, 1997.
• Hartman, Philip, Ordinary Differential Equations, 2nd Ed., Society for Industrial & Applied Math, 2002. ISBN 0-89871-510-5.
• W. Johnson, A Treatise on Ordinary and Partial Differential Equations, John Wiley and Sons, 1913, in University of Michigan Historical Math Collection
• E.L. Ince, Ordinary Differential Equations, Dover Publications, 1958, ISBN 0486603490
• Witold Hurewicz Lectures on Ordinary Differential Equations, Dover Publications, ISBN 0-486-49510-8