Linear Independence and Differential Equations

They involve more complex functions.

They replace the order of two with the order of n.

They do not require initial conditions.

They are only applicable to non-homogeneous equations.

The product of solutions is a solution.

The sum of solutions is not a solution.

A linear combination of solutions is also a solution.

Only one solution exists for each equation.

Solutions are only possible for homogeneous equations.

Multiple solutions exist for any initial conditions.

No solutions exist without specific initial conditions.

Exactly one solution exists for given initial conditions.

If they solve the same differential equation.

If they cannot be expressed as a multiple of each other.

If they have the same derivative.

If one is a multiple of the other.

To check if functions are linearly independent.

To find the roots of a polynomial.

To determine the order of a differential equation.

To solve differential equations directly.

The functions have no derivatives.

The functions are linearly independent.

The functions are linearly dependent.

The functions solve a non-homogeneous equation.

They do not solve any differential equation.

They have no derivatives.

They are linearly independent.

They are linearly dependent.

The product of y1 and y2.

A single function y2.

A linear combination of y1 and y2.

A single function y1.

It is irrelevant to the solution process.

It is only applicable to non-homogeneous equations.

It forms the basis for the general solution.

It provides a unique solution.

Finding the Wronskian.

Determining the order of the equation.

Finding n solutions.

Checking for linear dependence.