# Finding a general solution of $A_n$

Find the general solution to

$A_{n+1} + 4A_n = n$

I am unsure how to even start the question :S

-
For those who saw the other title: sorry. I believe I misunderstood the question. :o  For OP: Is this a sequence? If so, what values of $n$ is it valid for (e.g. $n\ge0$) and what is the start value? –  anorton Apr 1 '13 at 20:36

Let $B_n = A_n + an+b$. We then have $$B_{n+1} + 4B_n = A_{n+1} + an + a + b + 4A_n + 4an + 4b = (5a+1)n + a+5b$$ Choosing $a = -\dfrac15$ and $b = \dfrac1{25}$, i.e., setting $B_n = A_n - \dfrac{n}5 + \dfrac1{25}$, we get $$B_{n+1} + 4 B_n = 0$$ This gives us $B_n = (-4)^n B_0$. Hence, $$A_n - \dfrac{n}5 + \dfrac1{25} = (-4)^n \left(A_0 + \dfrac1{25}\right) \implies A_n = (-4)^n \left(A_0 + \dfrac1{25}\right) + \dfrac{n}{5} - \dfrac1{25}$$

-
@MarkBennet Yes. Thanks. Corrected. –  user17762 Apr 1 '13 at 20:48

Split the problem into homogeneous and inhomogeoneous solutions $A_n^{(H)}$ and $A_n^{(I)}$, respectively. The homogeneous solution satisfies

$$A_{n+1}^{(H)}+4 A_n^{(H)}=0$$

so that

$$A_n^{(H)} = K \cdot (-4)^n$$

where $K$ is some constant. For the inhomogeneous solution, you guess a form that will make the left side equal to the right side; in this case, a linear form will do:

$$A_n^{(I)} = a n + b$$

where you substitute into the equation and find $a$ and $b$ by equating constant and linear terms. The solution is then

$$A_n = A_n^{(H)} + A_n^{(I)}$$

You then find the constant $K$ by using an initial condition (which you did not specify).

-
Suppose $B_{n+1}+4B_{n}=0$ then you can check by linearity that $C_n=A_n+B_n$ satisfies the original equation. And you can compute $B_n$ in terms of $B_0$ without difficulty.
You are left with needing a particular solution for $A_n$ - and first off the guess for a linear expression in $n$ is a linear expression in $n$: - $A_n=pn+q$ will normally work. Sometimes, in similar problems, you will need to increase the degree so that you have terms in $n^2$. Find $p$ and $q$ and then add the sequence for $B_n$ which gives you the right initial value.