find the nth term in the quadratic sequence 3, 8, 15, 24
MathBot Answer:
$$3,8,15,24,...$$This infinite sequence is a quadratic sequence. The nth term rule for the sequence is $a_n=n \left(n + 2\right)$, where $n>0$. The recursive formula is $a_n=a_{n-1} + 2 n + 1$, where $n>1$ and $a_{1}=3$.
$$\begin{matrix}3&&8&&15&&24\\[6pt]&+5&&+7&&+9\\[6pt]&&+2&&+2\\[6pt]\end{matrix}$$
Explicit Formula
Since there are 2 rows of differences, the formula for the sequence can be written as a polynomial with degree 2, where $n$ is the term number and $(x_{0}, x_{1}, x_{2})$ are the coefficients: $$a_n=n^{2} x_{2} + n x_{1} + x_{0}$$
Using the first 3 terms in the sequence, create and solve the system of equations for $(x_{0}, x_{1}, x_{2})$: $$\begin{aligned} 3 &= 1^{2} x_{2} + 1 x_{1} + x_{0} \\ 8 &= 2^{2} x_{2} + 2 x_{1} + x_{0} \\ 15 &= 3^{2} x_{2} + 3 x_{1} + x_{0} \end{aligned} \quad \Rightarrow \quad \begin{aligned} x_{0} + x_{1} + x_{2} = 3\\x_{0} + 2 x_{1} + 4 x_{2} = 8\\x_{0} + 3 x_{1} + 9 x_{2} = 15 \end{aligned}$$ $$ \Rightarrow \quad (x_{0}, x_{1}, x_{2})=\left( 0, \ 2, \ 1\right) $$
The nth term rule is:$$\begin{aligned} a_n&=n^{2} x_{2} + n x_{1} + x_{0} \\ &=n^{2} \left(1\right) + n \left(2\right) + \left(0\right) \\ &=n \left(n + 2\right) \end{aligned}$$
Recursive Formula
Since there are 2 rows of differences, the formula for the sequence can be written as the sum of $a_{n-1}$ and polynomial with degree 1, where $n$ is the term number and $(x_{0}, x_{1})$ are the coefficients: $$a_n=a_{n-1} + n x_{1} + x_{0}$$
Using the first 3 terms in the sequence, create and solve the system of equations for $(x_{0}, x_{1})$: $$\begin{aligned} 8 &= 3 + 2 x_{1} + x_{0} \\ 15 &= 8 + 3 x_{1} + x_{0} \end{aligned} \quad \Rightarrow \quad \begin{aligned} x_{0} + 2 x_{1} = 5\\x_{0} + 3 x_{1} = 7 \end{aligned}$$ $$ \Rightarrow \quad (x_{0}, x_{1})=\left( 1, \ 2\right) $$
The nth term rule is:$$\begin{aligned} a_n&=a_{n-1} + n x_{1} + x_{0} \\ &=a_{n-1} + n \left(2\right) + \left(1\right) \\ &=a_{n-1} + 2 n + 1 \end{aligned}$$