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Mathematical Physics
Mathematical PhysicsP-334 Dr. Hatim DirarDepartment of Physics, College of Science Imam Mohamad Ibn Saud Islamic University
ScopesDifferential equations lead to:
Definition InterpretationForecasting of any physical system of any dimension
29/29/2013Hatim DirarScopes in PhysicsMechanics Free Fall let us considering free fall system defined by the following equation of motion =-g The above equation is second order DE
Classification of Differential Equations DE is defined as an equation contains derivative of an unknown function, which express the relationship we seek the equation includes total derivative like is called ordinary differential equation (ODE)If the function is of multivariables , the differential equation is known as partial differential equation (PDE)Order of DE indicates the order of the highest derivative appear in the equationDegree of the DE equations indicates the power of the derivative of highest order after the equation has been rationalized e.g.
is of second order and first degree
9/29/2013Hatim Dirar4Classification of DEExample 2
The above equation has said to be of a first order and second degree since it will contains after it is rationalized DE has said to be linear if each term of it is such that the dependant variable or its derivative occur only once and only to the first power e.g.
whereas, the following equation is nonlinear
Classification of DEIf the right hand side of the DE is equal to zero it has said to be homogenous, otherwise it is inhomogeneousIf you know two solutions of any homogenous equation, other solution can be constructed as the linear combination of these solutionsTrivial change of unfamiliar DE might convert it to a recognizable DEMany DEs are too difficult to be solved and few can be solved in closed form
Solution of DE Solution of first-order DE DE of general form
or
is clearly first-order DESuch equation can be solved by separation of variable methodIf are reducible to then we have
Solution of DEThe above equation can be solved easily by integrating directlyExample:Solve the following DE
Solution:Let us rearrange the equation or to separate the variables hence it will be
Now let us integrate as;
Solution of DE the solution will be
Where, C is constantSome times, the variable may not be separable. In such case we need to change these variable so as to be separable, the following is the general form;
Where f is an arbitrary function and a and b are constants. If we let
Solution of DEThen,
then the DE will be
From which we obtained,
such DE became separable
109/29/2013Hatim DirarSolution of DE Example:Solve the following DE
Solution:Let, then and the DE will be
Solution of DEor,
hence the equation is separable can easy be solved by integrating the variables
Solution of DEHomogenous DE, which has the general form may also be reduced to an equation with separable variables
Example:Solve the equation Solution:The right hand side can be written as
Solution of DEhence we get function of single variable, let
and our equation become from which we have
Integration gives
149/29/2013Hatim DirarSolution of DEEx:Solve the following DE:1-
2-
3-
Exact equationExample:Solve the equation
Solution: The above equation has said to be homogenous if we will be able to change the variable, such that to eliminate -5 and -1 from numerator and denominator, respectively. Let,
Exact equationThe above equation has said to be homogenous if we will be able to change the variable, such that to eliminate -5 and -1 from numerator and denominator, respectively.
Where, and are constants, chosen in such away our equation will be homogenous. Substitute for both x and y we get.
Now let,
then.
Hence our equation will be,
herefore, the above equation becomes separable and hence solvable.Example 2.5 Fall of a skydiver. Solution: Assuming the parachute opens at the beginning of the fall, there are two forces acting on the parachute: the downward force of gravity mg, and the
upward force of air resistance. If we choose a coordinate system that has at the earth's surface and increases upward, then the equation of motion of the falling diver, according to Newton's second law, is
where m is the mass, g the gravitational acceleration, and k a positive constant. In general the air resistance is very complicated, but the power-law approximation is useful in many instances in which the velocity does not vary appreciably.
Experiments show that for subsonic velocity up to 300 m/s, the air resistance is approximately proportional to . The equation is separable
To make the equation more simple let
Assume that,
Therefore,
Let us apply the above reduction we get,
Upon integration
Where C is the constant of integration
let,
Fro1m the above solution it is obviously seen that, as; ,
This implies that if the fall is from sufficient high, the fallen particle will fall with constant velocity known as terminal velocity. To determine C we need to know the value of k, which is being 30Kg/m
Exact DE The following equation has said to integrable because it is homogenous
The solution of the above equation is of the form
The above equation has said to be exact if
To check this let us let us consider the above equation, By performing differential we get, which the general properties of partial derivative of any well behave f unction
If our exact DE is of the form,
Then it is easy to identify that,
Then it follows from the above equation that, Hence, it is the same relation we had obtained previously
Examples: Show that the equation, is exact and find its general solution Solution: Let us rearrange the above equation so as to look like the following standard form Since,
Therefore, the given equation is exact and its general solution will be,
This implies that,
Where, are the integration constants, comparing the above solution it is clearly seen that,
Thus the general solution is,
It is very interesting to consider a DE of this type The left hand side is an exact differential equation and on the right hand side is the function of x only. Then the general solution can be written as,
Alternatively we can write the above solution as;
Since the LHS of the above equation is exact, then
Let us test the exactness of the above equation;
Hence, the above equation satisfies the requirement for being exact; we can write the solution as: Where,
Integrating Factor (IF) Inexact DE can be converted to exact by multiplying it by an IF. Different DE have different Ifs, which are rather difficult to find. Let us consider the following DE, Let, be the IF of the above DE. Now multiply the DE by IF, we get
Now the RHS of the above equation has said to be integrable; the condition is that the LHS is exactHence the equation becomes,
Which yield,
Or,
Hence it is possible to write the general solution as;
Where,
Therefore, the solution will be;
Example: Show that the given equation is not exact; then find a suitable IF that could makes the DE exact and look for its general solution Solution: First of all let us write the above equation in the standard form .i.e.
It is obviously seen that, This implies that, the given equation is not exact
Let us divide the equation by x, we get;
From the above equation we found that,
Hence, the required IF is;
Now apply this IF to the given equation we get, Integrating the above equation we get, and
Application in Physics: For the given LCR circuit, shown below, find the current in the circuit as the function of time t
Solution: First of all we need to setup the differential equation for the current flowing in the circuit. R and L represents the constant resistance and inductance, respectively.
and
where,
is the voltage dropped across R
is the voltage dropped across L
Let us apply Kirchhoffs second law
here t represents the independent variable and stand for the dependent. The general solution will be,
E and k are constants, and the evaluation of the above integral gives,
Regardless the value of k, we see that,
At , the solution will be,