Calculus II: Introduction to differential equations

1. Differential equation

1.1. Definition

A differential equation is an equation that contains a derivative.

The general solution of a differential equation is all the functions that satisfy the related equation.

The particular solution of the differential equation dy/dx = f(x) is given by its related initial conditions, that is for x = xo, we have y = y = f(xo) = yo.

1.2. Example

dy/dx + x - 1 = 0
dy/dx = - x + 1
dy = (- x + 1)dx
∫ dy = ∫ (- x + 1) dx
y + cst1 = - (1/2) x² + x + cst2
or
y = - (1/2) x² + x + cst

if for x = 0 , yo = 3, then
cst = 3, and the particular solution is :

y = - (1/2) x² + x + 3

2. Separable differential equations

2.1. Definition

If the differential equation contains variables that we can separate, the equation is called separable differential equations.

It has the form:

g(y) dy = f(x) dx

For this equation, to obtain the general solution, we separate first the variable and calculate the related primitives of the two sides of the equation.

2.2. Example

Let's solve the following differential equation with y = 0 if x = 1.

dy/dx = 3x²y³ .

We separate the variables as follows:

dy/y³ = 3x² dx

The primitives of the two memmbers are:
(-1/2)/y² = x³ + cst.

That is

y² = (-1/2)/(x³ + cst)

Or

y² = - 1/2x³ + cst.

According to the initial conditions y = 0 if x = 1, we have:

0 = - 1/2 + cst, so cst = + 1/2

The general solution of the equation is:

y² = - 1/2x³ + 1/2.

3. Linear first order differential equation

3.1. Definition

A Linear first order differential equation is of the form:

dy/dx + P(x)y = Q(x)

That we cannot separate as before.

- Linear stands for the power of the terms is 1.
- First order stands for the derivative in the equation is a first derivative.

To find the general solution of this equation, we multiply its two sides by a factor called integrating factor I(x) such that the left side of the equation dy/dx + P(x)y becomes

[dy/dx + P(x)y] I(x) = d(I(x) y)/dx .

So

I(x)[dy/dx + P(x)y] = I(x) Q(x)

The first side must be: d(I(x) y)/dx. So
d(I(x) y)/dx = I(x)[dy/dx + P(x)y] , or
y dI(x)/dx + dy/dx . I(x) = I(x). dy/dx + I(x) . P(x) y I(x)
y dI(x)/dx = I(x) . P(x)y
dI(x)/I(x) = P(x) dx
ln(I(x)) = ∫ P(x) dx + cst

We are searching for a particular integrating factor, so we consider I(x) > 0 and no constant .

I(x) = exp {∫ P(x) dx}

I(x) = exp {∫ P(x) dx}

The equation
d(I(x) y)/dx = I(x) Q(x) gives
I(x) y = ∫ I(x) Q(x) dx

Therefore

y = [∫ I(x) Q(x) dx]/I(x)

Differential equation:
dy/dx + P(x)y = Q(x)

Integrating factor:
I(x) = exp {∫ P(x) dx}

General solotion:
y = (1/I(x)) ∫ I(x) Q(x) dx

3.2. Example

Solve the differential equation:

dy/dx + 2 xy = 3 x

P(x) = 2 x
Q(x) = 3 x
∫ P(x) dx = x²
I(x) = exp {∫ P(x) dx} = exp {x²}
∫ I(x) Q(x) dx = ∫ exp {x²} 3 x dx =
3 ∫ exp {x²} x dx = (3/2) exp {x²} + const

Therefore

y = (1/I(x)) ∫ I(x) Q(x) dx =
(3/2) exp {- x²} [exp {x²} + const] =
(3/2) [1 + const . exp {- x²}] =
(3/2) + const . exp {- x²}

4. Exercises

Solve the differential equation

dy/dx - 1/x = 0
with yo = 1 when x = e

chimie labs

Physics and Measurements

Probability & Statistics

Combinatorics - Probability

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Optics

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