Perfect squares
- Grigorios Kostakos
- Founder
- Posts: 461
- Joined: Mon Nov 09, 2015 1:36 am
- Location: Ioannina, Greece
Perfect squares
Prove that every term of the sequence \begin{align*} &49\,,\quad 4489\,,\quad 444889\,,\quad 44448889\,,\\ &4444488889\,, \quad 444444888889\,,\ldots \end{align*} is a perfect square.
Grigorios Kostakos
- Tolaso J Kos
- Administrator
- Posts: 867
- Joined: Sat Nov 07, 2015 6:12 pm
- Location: Larisa
- Contact:
Re: Perfect squares
Hello Grigoris (Αρχιμήδης 6 greets you),Grigorios Kostakos wrote:Prove that every term of the sequence \begin{align*} &49\,,\quad 4489\,,\quad 444889\,,\quad 44448889\,,\\ &4444488889\,, \quad 444444888889\,,\ldots \end{align*} is a perfect square.
the numbers appearing in the sequence above are of the form:
$$\begin{aligned}
a_k &=4\left ( 10^{2k-1}+10^{2k-2}+\cdots +10^k \right )+ 8\left ( 10^{k-1}+\cdots +10 \right )+9 \\
&=4\left ( 10^k \cdot \frac{10^k-1}{10-1} \right )+ 8 \left ( 10 \cdot \frac{10^{k-1}-1}{10-1}\right )+9 \\
&= \frac{4}{9}\left ( 10^{2k}-10^k \right )+\frac{8}{9} \left ( 10^k-10 \right )+9 \\
&= \left ( \frac{2\cdot 10^k +1}{3} \right )^2
\end{aligned}$$
that are indeed perfect squares. Also note that each term is an integer since $$\displaystyle 10^k \equiv 1 \bmod 3, \; \;\; 2 \cdot 10^k +1 \equiv 0 \bmod 3 $$
Hence \( \dfrac{2\cdot 10^k+1}{3} \in \mathbb{Z} \).
Imagination is much more important than knowledge.
Create an account or sign in to join the discussion
You need to be a member in order to post a reply
Create an account
Not a member? register to join our community
Members can start their own topics & subscribe to topics
It’s free and only takes a minute
Sign in
Who is online
Users browsing this forum: No registered users and 1 guest