Math 3120 Differential Equations
withBoundary Value
Problems
Chapter 1Introduction to Differential
Equations
Basic Mathematical ModelsMany physical systems describing the real world
are statements or relations involving rate of change. In mathematical terms, statements are equations and rates are derivatives.Definition: An equation containing derivatives is called a differential equation. Differential equation (DE) play a prominent role in physics, engineering, chemistry, biology and other disciplines. For example: Motion of fluids, Flow of current in electrical circuits, Dissipation of heat in solid objects, Seismic waves, Population dynamics etc.Definition: A differential equation that describes a physical process is often called a mathematical model.
Formulate a mathematical model describing motion of an object falling in the atmosphere near sea level.
Variables: time t, velocity v Newton’s 2nd Law: F = ma = net
force
Force of gravity: F = mg downward force
Force of air resistance: F = v upward force
Then
vmgdt
dvm
Basic Mathematical Models
dt
dvm
We can also write Newton’s 2nd Law:
where s(t) is the distance the body falls in time t from its initial point of release
Then,
Basic Mathematical Models
dt
dvs
dt
dsmF re whe
2
2
mgdt
ds
dt
sdm
2
2
(1)
(2)
(3)
(4)
(5)
mgdt
ds
dt
sdm
2
2
Examples of DE
vmgdt
dvm
equation) (wave ),(),(
equation)(heat ),(),(
2
2
2
22
2
2
22
t
txu
x
txua
t
txu
x
txu
)(1
2
2
tEqCdt
dsR
dt
qdL
Classifications of Differential Equation
By Types Ordinary Differential Equation (ODE) Partial Differential Equation (PDE)
Order Systems Linearity
Linear Non-Linear
Ordinary Differential Equations
When the unknown function depends on a single independent variable, only ordinary derivatives appear in the equation. In this case the equation is said to be an ordinary differential equations.
For example:
A DE can contain more than one dependent variable. For example:
05.0,2.08.92
2
ydx
dy
dx
ydv
dt
dv
yxdt
dy
dt
dx
Partial Differential Equations
When the unknown function depends on several independent variables, partial derivatives appear in the equation. In this case the equation is said to be a partial differential equation.
Examples:
equation) (wave ),(),(
equation)(heat ),(),(
2
2
2
22
2
2
22
t
txu
x
txua
t
txu
x
txu
Notation
Leibniz
Prime
Dot
Subscript
)()1()4( ,,,,, nn yyyyyy
n
n
dx
yd
dx
yd
dx
yd
dx
dy,........,,
3
3
2
2
ydx
ydy
dx
dy 2
2
,
yyxxx uuu ,,
Systems of Differential Equations
Another classification of differential equations depends on the number of unknown functions that are involved.
If there is a single unknown function to be found, then one equation is sufficient. If there are two or more unknown functions, then a system of equations is required.
For example, Lotka-Volterra (predator-prey) equations have the form
where u(t) and v(t) are the respective populations of prey and predator species. The constants a, c, , depend on the particular species being studied.
uvcvdtdv
uvuadtdu
/
/
Order of Differential Equations
The order of a differential equation is the order of the highest derivative that appears in the equation.
Examples:
An nth order differential equation can be written as
The normal form of Eq. (6) is
tuuedt
yd
dt
ydyy yyxx
t sin 1 03 22
2
4
4
)7( ,,,,,,)( )1()( nn yyyyytfty
(6) 0,,,,,, )( nyyyyytF
Linear & Nonlinear Differential Equations
An ordinary differential equation
is linear if F is linear in the variables
Thus the general linear ODE has the form
The characteristic of linear ODE is given as
0,,,,,, )( nyyyyytF
)(,,,,, nyyyyy
)()()()( )1(1
)(0 tgytaytayta n
nn
Linear & Nonlinear Differential Equations
Example: Determine whether the equations below are linear or nonlinear.
tuuutyy
tuuutyey
tdt
ydt
dt
ydyy
yyxx
yyxxy
cos)sin()6(023)3(
sin)5(023)2(
1)4(03)1(
2
22
2
4
4
Solutions to Differential Equations
A solution of an ordinary differential equation
on an interval I is a function (t) such that
exists and satisfies the equation:
for every t in I.
Unless stated we shall assume that function f of Eq. (7) is a real valued function and we are interested in obtaining real valued solutions
NOTE: Solutions of ODE are always defined on an interval.
)1()( ,,,,,)( nn tft
)()1( ,,,, nn )7( ,,,,,,)( )1()( nn yyyyytfty
)(ty
Solutions to Differential Equations
Example: Show that is a solution of the ODE on the interval (-∞, ∞).
Verify that is a solutions of the ODE on the interval (-∞, ∞).
tty sin)(
tty cos)( 0 yy
0 yy
Types of Solutions
Trivial solution: is a solution of a differential equation that is identically zero on an interval I.
Explicit solution: is a solution in which the dependent variable is expressed solely in terms of the independent variable and constants. For example,
are two explicit solutions of the ODE
Implicit solution is a solution that is not in explicit form.
ttytty sin)( and ,cos)( 0 yy
Families of Solutions
A solution of a first- order differential equation
usually contains a single arbitrary constant or parameter c.
One-parameter family of solution: is a
solution containing an arbitrary constant represented by a set of solutions.
Particular solution: is a solution of a differential equation that is free of arbitrary parameters.
0,, yyxF
0,, cyxG
Initial Value Problems (IVP)
Initial Conditions (IC) are values of the solution and /or its derivatives at specific points on the given interval I.
A differential equation along with an appropriate number of IC is called an initial value problem. Generally, a first order differential equation is of the type
An nth order IVP is of the form
where are arbitrary constants. Note: The number of IC’s depend on the order of the DE.
10)1(
1000
)1()(
)(,....,)(',)( subject to
),.....,',,(
nn
nn
ytyytyyty
yyytfy
00 )( ),,(' ytyytfy
110 ,....,, nyyy
Solutions to Differential Equations
Three important questions in the study of differential equations: Is there a solution? (Existence)
If there is a solution, is it unique? (Uniqueness)
If there is a solution, how do we find it?
(Qualitative Solution, Analytical Solution, Numerical Approximation)
Theorem 1.2.1: Existence of a Unique Solution
Suppose f and f/y are continuous on some open rectangle R defined by (t, y) (, ) x (, ) containing the point (t0, y0). Then in some interval (t0 - h, t0 + h) (, ) there exists a unique solution y = (t) that satisfies the IVP
It turns out that conditions stated in Theorem 1.2.1 are sufficient but not necessary.
00 )( subject to
),('
yty
ytfy