Solutions of Differential Equations

A solution of a differential equation is an expression of the dependent variable that satisfies the relation established in the differential equation. For example, the solution of $y'+y-2=4x$ will be some equation y = f(x) such that y and its first derivative, y', satisfy the relation $y'+y-2=4x$ . The general solution of a differential equation will have one or more arbitrary constants, depending on the order of the original differential equation (the solution of a first order diff. eq. will have one arbitrary constant, a second order one will have two, etc.).

Examples:

$y'=2x$ . Through simple integration, we can calculate the general solution of this equation to be $y=x^{2}+C$ , where C is an arbitrary constant.
$y'-y=0$ . The G.S. is $y=Ce^{x}$ . $y'=Ce^{x}$ , so $y'-y=0\to Ce^{x}-Ce^{x}=0$ , so this solution satisfies the relationship for all arbitrary constants C.
$y''+y'-2y=0$ . The G.S. is $y=Ce^{x}+De^{-2x}$ . $y'=Ce^{x}-2De^{-2x}$ and $y''=Ce^{x}+4De^{-2x}$ , so $0=y''+y'-2y$ becomes $0=Ce^{x}+4De^{-2x}+Ce^{x}-2De^{-2x}-2(Ce^{x}+De^{-2x})=Ce^{x}+Ce^{x}-2Ce^{x}+4De^{-2x}-2De^{-2x}-2De^{-2x})=0$ .

The particular solution of a differential equation can be solved if we have enough points to solve for the arbitrary constants.

Examples:

$y'=2x$ , $y(2)=0$ . With this point and the general solution $y=x^{2}+C$ , we can calculate the constant C to be -4. Thus the particular solution is $y=x^{2}-4$ .
$y'-y=0$ , $y(0)=3$ . $3=Ce^{0}=C$ , so the particular solution is $y=3e^{x}$ .
$y''+y'-2y=0$ . The G.S. is $y=Ce^{x}+De^{-2x}$ . $y'=Ce^{x}-2De^{-2x}$ and $y''=Ce^{x}+4De^{-2x}$ , so $0=y''+y'-2y$ becomes $0=Ce^{x}+4De^{-2x}+Ce^{x}-2De^{-2x}-2(Ce^{x}+De^{-2x})=Ce^{x}+Ce^{x}-2Ce^{x}+4De^{-2x}-2De^{-2x}-2De^{-2x})=0$ .